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test_gpu_updaters.py
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test_gpu_updaters.py
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import numpy as np
import sys
import gc
import pytest
import xgboost as xgb
from hypothesis import given, strategies, assume, settings, note
sys.path.append("tests/python")
import testing as tm
import test_updaters as test_up
parameter_strategy = strategies.fixed_dictionaries({
'max_depth': strategies.integers(0, 11),
'max_leaves': strategies.integers(0, 256),
'max_bin': strategies.integers(2, 1024),
'grow_policy': strategies.sampled_from(['lossguide', 'depthwise']),
'min_child_weight': strategies.floats(0.5, 2.0),
'seed': strategies.integers(0, 10),
# We cannot enable subsampling as the training loss can increase
# 'subsample': strategies.floats(0.5, 1.0),
'colsample_bytree': strategies.floats(0.5, 1.0),
'colsample_bylevel': strategies.floats(0.5, 1.0),
}).filter(lambda x: (x['max_depth'] > 0 or x['max_leaves'] > 0) and (
x['max_depth'] > 0 or x['grow_policy'] == 'lossguide'))
def train_result(param, dmat: xgb.DMatrix, num_rounds: int) -> dict:
result: xgb.callback.TrainingCallback.EvalsLog = {}
booster = xgb.train(
param,
dmat,
num_rounds,
[(dmat, "train")],
verbose_eval=False,
evals_result=result,
)
assert booster.num_features() == dmat.num_col()
assert booster.num_boosted_rounds() == num_rounds
return result
class TestGPUUpdaters:
cputest = test_up.TestTreeMethod()
@given(parameter_strategy, strategies.integers(1, 20), tm.dataset_strategy)
@settings(deadline=None, print_blob=True)
def test_gpu_hist(self, param, num_rounds, dataset):
param["tree_method"] = "gpu_hist"
param = dataset.set_params(param)
result = train_result(param, dataset.get_dmat(), num_rounds)
note(result)
assert tm.non_increasing(result["train"][dataset.metric])
@given(tm.sparse_datasets_strategy)
@settings(deadline=None, print_blob=True)
def test_sparse(self, dataset):
param = {"tree_method": "hist", "max_bin": 64}
hist_result = train_result(param, dataset.get_dmat(), 16)
note(hist_result)
assert tm.non_increasing(hist_result['train'][dataset.metric])
param = {"tree_method": "gpu_hist", "max_bin": 64}
gpu_hist_result = train_result(param, dataset.get_dmat(), 16)
note(gpu_hist_result)
assert tm.non_increasing(gpu_hist_result['train'][dataset.metric])
np.testing.assert_allclose(
hist_result["train"]["rmse"], gpu_hist_result["train"]["rmse"], rtol=1e-2
)
@given(strategies.integers(10, 400), strategies.integers(3, 8),
strategies.integers(1, 2), strategies.integers(4, 7))
@settings(deadline=None, print_blob=True)
@pytest.mark.skipif(**tm.no_pandas())
def test_categorical_ohe(self, rows, cols, rounds, cats):
self.cputest.run_categorical_ohe(rows, cols, rounds, cats, "gpu_hist")
@given(
strategies.integers(10, 400),
strategies.integers(3, 8),
strategies.integers(4, 7)
)
@settings(deadline=None, print_blob=True)
@pytest.mark.skipif(**tm.no_pandas())
def test_categorical_missing(self, rows, cols, cats):
self.cputest.run_categorical_missing(rows, cols, cats, "gpu_hist")
def test_max_cat(self) -> None:
self.cputest.run_max_cat("gpu_hist")
def test_categorical_32_cat(self):
'''32 hits the bound of integer bitset, so special test'''
rows = 1000
cols = 10
cats = 32
rounds = 4
self.cputest.run_categorical_ohe(rows, cols, rounds, cats, "gpu_hist")
@pytest.mark.skipif(**tm.no_cupy())
def test_invalid_category(self):
self.cputest.run_invalid_category("gpu_hist")
@pytest.mark.skipif(**tm.no_cupy())
@given(parameter_strategy, strategies.integers(1, 20),
tm.dataset_strategy)
@settings(deadline=None, print_blob=True)
def test_gpu_hist_device_dmatrix(self, param, num_rounds, dataset):
# We cannot handle empty dataset yet
assume(len(dataset.y) > 0)
param['tree_method'] = 'gpu_hist'
param = dataset.set_params(param)
result = train_result(param, dataset.get_device_dmat(), num_rounds)
note(result)
assert tm.non_increasing(result['train'][dataset.metric])
@given(parameter_strategy, strategies.integers(1, 20),
tm.dataset_strategy)
@settings(deadline=None, print_blob=True)
def test_external_memory(self, param, num_rounds, dataset):
if dataset.name.endswith("-l1"):
return
# We cannot handle empty dataset yet
assume(len(dataset.y) > 0)
param['tree_method'] = 'gpu_hist'
param = dataset.set_params(param)
m = dataset.get_external_dmat()
external_result = train_result(param, m, num_rounds)
del m
gc.collect()
assert tm.non_increasing(external_result['train'][dataset.metric])
def test_empty_dmatrix_prediction(self):
# FIXME(trivialfis): This should be done with all updaters
kRows = 0
kCols = 100
X = np.empty((kRows, kCols))
y = np.empty((kRows))
dtrain = xgb.DMatrix(X, y)
bst = xgb.train({'verbosity': 2,
'tree_method': 'gpu_hist',
'gpu_id': 0},
dtrain,
verbose_eval=True,
num_boost_round=6,
evals=[(dtrain, 'Train')])
kRows = 100
X = np.random.randn(kRows, kCols)
dtest = xgb.DMatrix(X)
predictions = bst.predict(dtest)
np.testing.assert_allclose(predictions, 0.5, 1e-6)
@pytest.mark.mgpu
@given(tm.dataset_strategy, strategies.integers(0, 10))
@settings(deadline=None, max_examples=10, print_blob=True)
def test_specified_gpu_id_gpu_update(self, dataset, gpu_id):
param = {'tree_method': 'gpu_hist', 'gpu_id': gpu_id}
param = dataset.set_params(param)
result = train_result(param, dataset.get_dmat(), 10)
assert tm.non_increasing(result['train'][dataset.metric])