Concrete ML provides several of the most popular classification
and regression
tree models that can be found in scikit-learn:
Concrete ML | scikit-learn |
---|---|
Concrete ML also supports XGBoost's XGBClassifier
and XGBRegressor
:
Concrete ML | XGboost |
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For a formal explanation of the mechanisms that enable FHE-compatible decision trees, please see the following paper: Privacy-Preserving Tree-Based Inference with Fully Homomorphic Encryption, arXiv:2303.01254
As the maximum depth parameter of decision trees and tree-ensemble models strongly increases the number of nodes in the trees, we recommend using the XGBoost models which achieve better performance with lower depth.
Here's an example of how to use this model in FHE on a popular data-set using some of scikit-learn's pre-processing tools. A more complete example can be found in the XGBClassifier notebook.
Similarly, the decision boundaries of the Concrete ML model can be plotted and compared to the results of the classical XGBoost model executed in the clear. A 6-bit model is shown in order to illustrate the impact of quantization on classification. Similar plots can be found in the Classifier Comparison notebook.
This graph above shows that, when using a sufficiently high bit-width, quantization has little impact on the decision boundaries of the Concrete ML FHE decision tree models. As quantization is done individually on each input feature, the impact of quantization is strongly reduced. This means that FHE tree-based models reach a similar level of accuracy as their floating point equivalents. Using 6 bits for quantization means that the Concrete ML model reaches, or exceeds, the floating point accuracy. The number of bits for quantization can be adjusted through the n_bits
parameter.
When n_bits
is set to a low value, the quantization process may sometimes create some artifacts that could lead to a decrease in accuracy. At the same time, the execution speed in FHE could improve. In this way, it is possible to adjust the accuracy/speed trade-off, and some accuracy can be recovered by increasing the n_estimators
parameter.
The following graph shows that using 5-6 bits of quantization is usually sufficient to reach the performance of a non-quantized XGBoost model on floating point data. The metrics plotted are accuracy and F1-score on the spambase
data-set.
The inference time in FHE is strongly dependant on the maximum circuit bit-width. For trees, in most cases, the quantization bit-width will be the same as the circuit bit-width. Therefore, reducing the quantization bit-width to 4 or less will result in fast inference times. Adding more bits will increase FHE inference time exponentially.
In some rare cases, the bit-width of the circuit can be higher than the quantization bit-width. This could happen when the quantization bit-width is low but the tree-depth is high. In such cases, the circuit bit-width is upper bounded by ceil(log2(max_depth + 1) + 1)
.
For more information on the inference time of FHE decision trees and tree-ensemble models please see Privacy-Preserving Tree-Based Inference with Fully Homomorphic Encryption, arXiv:2303.01254.