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conftest.py
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"""PyTest configuration file."""
import hashlib
import json
import os
import random
import re
from pathlib import Path
from typing import Any, Callable, Optional, Union
import numpy
import pytest
import torch
from concrete.fhe import Graph as CPGraph
from concrete.fhe.compilation import Circuit, Configuration
from concrete.fhe.mlir.utils import MAXIMUM_TLU_BIT_WIDTH
from sklearn.datasets import make_classification, make_regression
from sklearn.metrics import accuracy_score
from concrete.ml.common.utils import (
SUPPORTED_FLOAT_TYPES,
all_values_are_floats,
array_allclose_and_same_shape,
is_brevitas_model,
is_classifier_or_partial_classifier,
is_model_class_in_a_list,
is_regressor_or_partial_regressor,
to_tuple,
)
from concrete.ml.quantization.quantized_module import QuantizedModule
from concrete.ml.sklearn import (
GammaRegressor,
PoissonRegressor,
TweedieRegressor,
_get_sklearn_neural_net_models,
)
from concrete.ml.sklearn.base import (
BaseTreeEstimatorMixin,
QuantizedTorchEstimatorMixin,
SklearnKNeighborsMixin,
SklearnLinearModelMixin,
)
def pytest_addoption(parser):
"""Options for pytest."""
parser.addoption(
"--global-coverage-infos-json",
action="store",
default=None,
type=str,
help="To dump pytest-cov term report to a text file.",
)
parser.addoption(
"--weekly",
action="store_true",
help="To do longer tests.",
)
parser.addoption(
"--use_gpu",
action="store_true",
help="Force GPU compilation and execution in tests.",
)
parser.addoption(
"--no-flaky", action="store_true", default=False, help="Don't run known flaky tests."
)
def pytest_configure(config):
"""Update pytest configuration."""
config.addinivalue_line("markers", "flaky: mark test or module as flaky")
def pytest_collection_modifyitems(config, items):
"""Run pytest custom options."""
if config.getoption("--no-flaky"):
skip_flaky = pytest.mark.skip(
reason="This test is a known flaky and --no-flaky was called."
)
for item in items:
if "flaky" in item.keywords:
item.add_marker(skip_flaky)
# This is only for doctests where we currently cannot make use of fixtures
original_compilation_config_init = Configuration.__init__
def monkeypatched_compilation_configuration_init_for_codeblocks(
self: Configuration, *args, **kwargs
):
"""Monkeypatched compilation configuration init for codeblocks tests."""
# Parameter `enable_unsafe_features` and `use_insecure_key_cache` are needed in order to be
# able to cache generated keys through `insecure_key_cache_location`. As the name suggests,
# these parameters are unsafe and should only be used for debugging in development
original_compilation_config_init(self, *args, **kwargs)
self.dump_artifacts_on_unexpected_failures = False
self.enable_unsafe_features = True
self.treat_warnings_as_errors = True
self.use_insecure_key_cache = True
self.insecure_key_cache_location = "ConcretePythonKeyCache"
def pytest_sessionstart(session: pytest.Session):
"""Handle codeblocks Configuration if needed."""
if session.config.getoption("--codeblocks", default=False):
# setattr to avoid mypy complaining
# Disable the flake8 bug bear warning for the mypy fix
setattr( # noqa: B010
Configuration,
"__init__",
monkeypatched_compilation_configuration_init_for_codeblocks,
)
def pytest_sessionfinish(session: pytest.Session, exitstatus): # pylint: disable=unused-argument
"""Pytest callback when testing ends."""
# Hacked together from the source code, they don't have an option to export to file and it is
# too much work to get a PR in for such a little thing
# https://github.com/pytest-dev/pytest-cov/blob/
# ec344d8adf2d78238d8f07cb20ed2463d7536970/src/pytest_cov/plugin.py#L329
if session.config.pluginmanager.hasplugin("_cov"):
global_coverage_file = session.config.getoption(
"--global-coverage-infos-json", default=None
)
if global_coverage_file is not None:
cov_plugin = session.config.pluginmanager.getplugin("_cov")
coverage_txt = cov_plugin.cov_report.getvalue()
coverage_status = 0
if (
cov_plugin.options.cov_fail_under is not None
and cov_plugin.options.cov_fail_under > 0
):
failed = cov_plugin.cov_total < cov_plugin.options.cov_fail_under
# If failed is False coverage_status is 0, if True it is 1
coverage_status = int(failed)
global_coverage_file_path = Path(global_coverage_file).resolve()
with open(global_coverage_file_path, "w", encoding="utf-8") as f:
json.dump({"exit_code": coverage_status, "content": coverage_txt}, f)
@pytest.fixture
def default_configuration():
"""Return the compilation configuration for tests that can execute in FHE."""
# Parameter `enable_unsafe_features` and `use_insecure_key_cache` are needed in order to be
# able to cache generated keys through `insecure_key_cache_location`. As the name suggests,
# these parameters are unsafe and should only be used for debugging in development
# Simulation compilation is done lazily when calling circuit.simulate, so we do not need to
# set it by default
return Configuration(
dump_artifacts_on_unexpected_failures=False,
enable_unsafe_features=True,
use_insecure_key_cache=True,
insecure_key_cache_location="ConcretePythonKeyCache",
fhe_simulation=False,
fhe_execution=True,
compress_input_ciphertexts=os.environ.get("USE_INPUT_COMPRESSION", "1") == "1",
)
@pytest.fixture
def simulation_configuration():
"""Return the compilation configuration for tests that only simulate."""
# Parameter `enable_unsafe_features` and `use_insecure_key_cache` are needed in order to be
# able to cache generated keys through `insecure_key_cache_location`. As the name suggests,
# these parameters are unsafe and should only be used for debugging in development
return Configuration(
dump_artifacts_on_unexpected_failures=False,
enable_unsafe_features=True,
use_insecure_key_cache=True,
insecure_key_cache_location="ConcretePythonKeyCache",
fhe_simulation=True,
fhe_execution=False,
compress_input_ciphertexts=os.environ.get("USE_INPUT_COMPRESSION", "1") == "1",
)
REMOVE_COLOR_CODES_RE = re.compile(r"\x1b[^m]*m")
@pytest.fixture
def remove_color_codes():
"""Return the re object to remove color codes."""
return lambda x: REMOVE_COLOR_CODES_RE.sub("", x)
def function_to_seed_torch(seed):
"""Seed torch, for determinism."""
# Seed torch with something which is seed by pytest-randomly
torch.manual_seed(seed)
torch.use_deterministic_algorithms(True)
@pytest.fixture(autouse=True)
def autoseeding_of_everything(request):
"""Seed everything we can, for determinism."""
# Explanations on the seeding system:
#
# The used seed (called sub_seed below) for a test of a function f_i (e.g.,
# test_compute_bits_precision) on a configuration c_j (e.g., x0-8) of a test file t_k (e.g.,
# tests/common/test_utils.py) is computed as some hash(f_i, c_j, t_k, randomly-seed)
#
# It allows to reproduce bugs we would have had on a full pytest execution on a configuration
# (f_i, c_j, t_k) by calling pytest on this single configuration with the --randomly-seed
# parameter and no other arguments.
#
# In particular, it is resistant to crashes which would prevent the few prints below in this
# function, which details some seeding information
randomly_seed = request.config.getoption("--randomly-seed", default=None)
if randomly_seed is None:
raise ValueError("--randomly-seed has not been properly configured internally")
# Get the absolute path of the test file
absolute_path = str(request.fspath)
# Find the tests directory by searching for '/tests/' in the path
test_dir_index = absolute_path.find("/tests/")
if test_dir_index == -1:
raise ValueError(
"Unable to find '/tests/' directory in the path. "
"Make sure the test file is within a '/tests/' directory."
)
# Extract the relative path from the point of the '/tests/' directory
relative_file_path = absolute_path[test_dir_index + 1 :]
# Derive the sub_seed from the randomly_seed and the test name
derivation_string = f"{relative_file_path} # {str(request.node.name)} # {randomly_seed}"
hash_object = hashlib.sha256()
hash_object.update(derivation_string.encode("utf-8"))
hash_value = hash_object.hexdigest()
# The hash is a SHA256, so 256b. And random.seed wants a 64b seed and numpy.random.seed wants a
# 32b seed. So we reduce a bit
sub_seed = int(hash_value, 16) % 2**64
print(f"\nUsing {randomly_seed=}\nUsing {derivation_string=}\nUsing {sub_seed=}")
# And then, do everything per this sub_seed
seed = sub_seed
print(
f"\nRelaunch the tests with --randomly-seed {randomly_seed} "
+ "--randomly-dont-reset-seed to reproduce."
)
print(
"Remark that potentially, any option used in the pytest call may have an impact so in "
+ "case of problem to reproduce, you may want to have a look to `make pytest` options"
)
# Python
random.seed(seed)
# Numpy
seed += 1
numpy.random.seed(seed % 2**32)
# Seed torch
seed += 1
function_to_seed_torch(seed)
return {"randomly seed": randomly_seed}
@pytest.fixture
def is_weekly_option(request):
"""Say if we are in --weekly configuration."""
is_weekly = request.config.getoption("--weekly")
return is_weekly
@pytest.fixture
def get_device_for_compilation(request):
"""Get the hardware device to compile circuits in tests."""
def get_device_for_compilation_impl(fhe_mode):
use_gpu = request.config.getoption("--use_gpu")
device_for_tests = "cuda" if use_gpu else "cpu"
if fhe_mode == "execute":
return device_for_tests
return "cpu"
return get_device_for_compilation_impl
# Method is not ideal as some MLIR can contain TLUs but not the associated graph
# FIXME: https://github.com/zama-ai/concrete-ml-internal/issues/2381
def check_graph_input_has_no_tlu_impl(graph: CPGraph):
"""Check that the graph's input node does not contain a TLU."""
succ = list(graph.graph.successors(graph.input_nodes[0]))
if any(s.converted_to_table_lookup for s in succ):
raise AssertionError(f"Graph contains a TLU on an input node: {str(graph.format())}")
# Method is not ideal as some MLIR can contain TLUs but not the associated graph
# FIXME: https://github.com/zama-ai/concrete-ml-internal/issues/2381
def check_graph_output_has_no_tlu_impl(graph: CPGraph):
"""Check that the graph's output node does not contain a TLU."""
if graph.output_nodes[0].converted_to_table_lookup:
raise AssertionError(f"Graph output is produced by a TLU: {str(graph.format())}")
# Method is not ideal as some MLIR can contain TLUs but not the associated graph
# FIXME: https://github.com/zama-ai/concrete-ml-internal/issues/2381
def check_graph_has_no_input_output_tlu_impl(graph: CPGraph):
"""Check that the graph's input and output nodes do not contain a TLU."""
check_graph_input_has_no_tlu_impl(graph)
check_graph_output_has_no_tlu_impl(graph)
# To update when the feature becomes available Concrete
# FIXME: https://github.com/zama-ai/concrete-numpy-internal/issues/1714
def check_circuit_has_no_tlu_impl(circuit: Circuit):
"""Check a circuit has no TLU."""
if "apply_" in circuit.mlir and "_lookup_table" in circuit.mlir:
raise AssertionError("The circuit contains at least one TLU")
def check_circuit_precision_impl(circuit: Circuit):
"""Check a circuit doesn't need too much precision."""
circuit_precision = circuit.graph.maximum_integer_bit_width()
if circuit_precision > MAXIMUM_TLU_BIT_WIDTH:
raise AssertionError(
f"The circuit is precision is expected to be less than {MAXIMUM_TLU_BIT_WIDTH}. "
f"Got {circuit_precision}."
)
@pytest.fixture
def check_graph_input_has_no_tlu():
"""Check a circuit has no TLU on input."""
return check_graph_input_has_no_tlu_impl
@pytest.fixture
def check_graph_output_has_no_tlu():
"""Check a circuit has no TLU on output."""
return check_graph_output_has_no_tlu_impl
@pytest.fixture
def check_graph_has_no_input_output_tlu():
"""Check a circuit has no TLU on input or output."""
return check_graph_has_no_input_output_tlu_impl
@pytest.fixture
def check_circuit_has_no_tlu():
"""Check a circuit has no TLU."""
return check_circuit_has_no_tlu_impl
@pytest.fixture
def check_circuit_precision():
"""Check that the circuit is valid."""
return check_circuit_precision_impl
@pytest.fixture
def check_array_equal():
"""Fixture to check array equality."""
def check_array_equal_impl(actual: Any, expected: Any, verbose: bool = True):
"""Assert that `actual` is equal to `expected`."""
assert numpy.array_equal(actual, expected), (
""
if not verbose
else f"""
Expected Output
===============
{expected}
Actual Output
=============
{actual}
"""
)
return check_array_equal_impl
@pytest.fixture
def check_float_array_equal():
"""Fixture to check if two float arrays are equal with epsilon precision tolerance."""
def check_float_array_equal_impl(
a, b, rtol=0, atol=0.001, error_information: Optional[str] = ""
):
error_message = (
f"Not equal to tolerance rtol={rtol}, atol={atol}\na: {a}\nb: {b}\n"
f"{error_information}"
)
assert array_allclose_and_same_shape(a, b, rtol, atol), error_message
return check_float_array_equal_impl
@pytest.fixture
def check_r2_score():
"""Fixture to check r2 score."""
def check_r2_score_impl(expected, actual, acceptance_score=0.99):
expected = expected.ravel()
actual = actual.ravel()
mean_expected = numpy.mean(expected)
deltas_expected = expected - mean_expected
deltas_actual = actual - expected
r2_den = numpy.sum(deltas_expected**2)
r2_num = numpy.sum(deltas_actual**2)
# If the values are really close, we consider the test passes
if array_allclose_and_same_shape(expected, actual, atol=1e-4, rtol=0):
return
# If the variance of the target values is very low, fix the max allowed for residuals
# to a known value
r2_den = max(r2_den, 1e-5)
r_square = 1 - r2_num / r2_den
assert (
r_square >= acceptance_score
), f"r2 score of {numpy.round(r_square, 4)} is not high enough."
return check_r2_score_impl
@pytest.fixture
def check_accuracy():
"""Fixture to check the accuracy."""
def check_accuracy_impl(expected, actual, threshold=0.9):
accuracy = accuracy_score(expected, actual)
assert accuracy >= threshold, f"Accuracy of {accuracy} is not high enough ({threshold})."
return check_accuracy_impl
@pytest.fixture
def load_data():
"""Fixture for generating random regression or classification problem."""
def load_data_impl(
model_class: Callable,
*args,
random_state: Optional[int] = None,
**kwargs,
):
"""Generate a random regression or classification problem.
scikit-learn's make_regression() method generates a random regression problem without any
domain restrictions. However, some models can only handle non negative or (strictly)
positive target values. This function therefore adapts it in order to make it work for any
tested regressors.
For classifier, scikit-learn's make_classification() method is directly called.
Args:
model_class (Callable): The Concrete ML model class to generate the data for.
*args: Positional arguments to consider for generating the data.
random_state (int): Determines random number generation for data-set creation.
**kwargs: Keyword arguments to consider for generating the data.
"""
# Create a random_state value in order to seed the data generation functions. This enables
# all tests that use this fixture to be deterministic and thus reproducible.
random_state = numpy.random.randint(0, 2**15) if random_state is None else random_state
# If the data-set should be generated for a classification problem.
if is_classifier_or_partial_classifier(model_class) or is_brevitas_model(model_class):
generated_classifier = list(
make_classification(*args, **kwargs, random_state=random_state)
)
# Cast inputs to float32 as skorch QNNs don't handle float64 values
if is_model_class_in_a_list(model_class, _get_sklearn_neural_net_models()):
generated_classifier[0] = generated_classifier[0].astype(numpy.float32)
return tuple(generated_classifier)
# If the data-set should be generated for a regression problem.
if is_regressor_or_partial_regressor(model_class):
generated_regression = list(make_regression(*args, **kwargs, random_state=random_state))
# Generalized Linear Models can only handle positive target values,
# often strictly positive.
if is_model_class_in_a_list(
model_class, [GammaRegressor, PoissonRegressor, TweedieRegressor]
):
generated_regression[1] = numpy.abs(generated_regression[1]) + 1
# If the model is a neural network and if the data-set only contains a single target
# (e.g., of shape (n,)), reshape the target array (e.g., to shape (n,1))
if is_model_class_in_a_list(model_class, _get_sklearn_neural_net_models()):
if len(generated_regression[1].shape) == 1:
generated_regression[1] = generated_regression[1].reshape(-1, 1)
# Cast inputs and targets to float32 as skorch QNNs don't handle float64 values
generated_regression[0] = generated_regression[0].astype(numpy.float32)
generated_regression[1] = generated_regression[1].astype(numpy.float32)
return tuple(generated_regression)
raise ValueError(
"Model class type is unsupported. Expected a Concrete ML regressor or classifier, or "
f"a functool.partial version of it, but got {model_class}."
)
return load_data_impl
@pytest.fixture
def check_is_good_execution_for_cml_vs_circuit():
"""Compare quantized module or built-in inference vs Concrete circuit."""
def check_is_good_execution_for_cml_vs_circuit_impl(
inputs: Union[tuple, numpy.ndarray],
model: Union[Callable, QuantizedModule, QuantizedTorchEstimatorMixin],
simulate: bool,
n_allowed_runs: int = 5,
):
"""Check that a model or a quantized module give the same output as the circuit.
Args:
inputs (tuple, numpy.ndarray): inputs for the model.
model (Callable, QuantizedModule, QuantizedTorchEstimatorMixin): either the
Concrete ML sklearn built-in model or a quantized module.
simulate (bool): whether to run the execution in FHE or in simulated mode.
n_allowed_runs (int): in case of FHE execution randomness can make the output slightly
different this allows to run the evaluation multiple times
"""
inputs = to_tuple(inputs)
# Make sure that the inputs are floating points
assert all_values_are_floats(*inputs), (
f"Input values are expected to be floating points of dtype {SUPPORTED_FLOAT_TYPES}. "
"Do not quantize the inputs manually as it is handled within this method."
)
fhe_mode = "simulate" if simulate else "execute"
for _ in range(n_allowed_runs):
# Check if model is QuantizedModule
if isinstance(model, QuantizedModule):
y_pred_fhe = model.forward(*inputs, fhe=fhe_mode)
y_pred_quantized = model.forward(*inputs, fhe="disable")
else:
assert isinstance(
model,
(
QuantizedTorchEstimatorMixin,
BaseTreeEstimatorMixin,
SklearnLinearModelMixin,
SklearnKNeighborsMixin,
),
)
if model._is_a_public_cml_model: # pylint: disable=protected-access
# Only check probabilities for classifiers as we only want to check that the
# circuit is outputs (after de-quantization) are correct. We thus want to avoid
# as much post-processing steps in the clear (that could lead to more flaky
# tests), especially since these results are tested in other tests such as the
# `check_subfunctions_in_fhe`
# For KNN `predict_proba` is not supported for now
# FIXME: https://github.com/zama-ai/concrete-ml-internal/issues/3962
if is_classifier_or_partial_classifier(model) and not isinstance(
model, SklearnKNeighborsMixin
):
y_pred_fhe = model.predict_proba(*inputs, fhe=fhe_mode)
y_pred_quantized = model.predict_proba(*inputs, fhe="disable")
else:
y_pred_fhe = model.predict(*inputs, fhe=fhe_mode)
y_pred_quantized = model.predict(*inputs, fhe="disable")
else:
raise ValueError(
"numpy_function should be a built-in concrete sklearn model or "
"a QuantizedModule object."
)
if array_allclose_and_same_shape(y_pred_fhe, y_pred_quantized):
return
raise RuntimeError(
f"Mismatch between circuit results:\n{y_pred_fhe}\n"
f"and model function results:\n{y_pred_quantized}"
)
return check_is_good_execution_for_cml_vs_circuit_impl