## Instructions for PaddleFL-MPC UCI Housing Demo ([简体中文](./README_CN.md)|English) This document introduces how to run UCI Housing demo based on Paddle-MPC, which has two ways of running, i.e., single machine and multi machines. ### 1. Running on Single Machine #### (1). Prepare Data Generate encrypted data utilizing `generate_encrypted_data()` in `process_data.py` script. For example, users can write the following code into a python script named `prepare.py`, and then run the script with command `python prepare.py`. ```python import process_data process_data.generate_encrypted_data() ``` Encrypted data files of feature and label would be generated and saved in `/tmp` directory. Different suffix names are used for these files to indicate the ownership of different computation parties. For instance, a file named `house_feature.part0` means it is a feature file of party 0. #### (2). Launch Demo with A Shell Script Launch demo with the `run_standalone.sh` script. The concrete command is: ```bash bash run_standalone.sh uci_housing_demo.py ``` The loss with cypher text format will be displayed on screen while training. At the same time, the loss data would be also save in `/tmp` directory, and the format of file name is similar to what is described in Step 1. Besides, predictions would be made in this demo once training is finished. The predictions with cypher text format would also be save in `/tmp` directory. Finally, using `load_decrypt_data()` in `process_data.py` script, this demo would decrypt and print the loss and predictions, which can be compared with related results of Paddle plain text model. **Note** that remember to delete the loss and prediction files in `/tmp` directory generated in last running, in case of any influence on the decrypted results of current running. For simplifying users operations, we provide the following commands in `run_standalone.sh`, which can delete the files mentioned above when running this script. ```bash # remove temp data generated in last time LOSS_FILE="/tmp/uci_loss.*" PRED_FILE="/tmp/uci_prediction.*" if [ "$LOSS_FILE" ]; then rm -rf $LOSS_FILE fi if [ "$PRED_FILE" ]; then rm -rf $PRED_FILE fi ``` ### 2. Running on Multi Machines #### (1). Prepare Data Data owner encrypts data. Concrete operations are consistent with “Prepare Data” in “Running on Single Machine”. #### (2). Distribute Encrypted Data According to the suffix of file name, distribute encrypted data files to `/tmp ` directories of all 3 computation parties. For example, send `house_feature.part0` and `house_label.part0` to `/tmp` of party 0 with `scp` command. #### (3). Modify uci_housing_demo.py Each computation party makes the following modifications on `uci_housing_demo.py` according to the environment of machine. * Modify IP Information Modify `localhost` in the following code as the IP address of the machine. ```python pfl_mpc.init("aby3", int(role), "localhost", server, int(port)) ``` * Comment Out Codes for Single Machine Running Comment out the following codes which are used when running on single machine. ```python import process_data print("uci_loss:") process_data.load_decrypt_data("/tmp/uci_loss", (1,)) print("prediction:") process_data.load_decrypt_data("/tmp/uci_prediction", (BATCH_SIZE,)) ``` #### (4). Launch Demo on Each Party **Note** that Redis service is necessary for demo running. Remember to clear the cache of Redis server before launching demo on each computation party, in order to avoid any negative influences caused by the cached records in Redis. The following command can be used for clear Redis, where REDIS_BIN is the executable binary of redis-cli, SERVER and PORT represent the IP and port of Redis server respectively. ``` $REDIS_BIN -h $SERVER -p $PORT flushall ``` Launch demo on each computation party with the following command, ``` $PYTHON_EXECUTABLE uci_housing_demo.py $PARTY_ID $SERVER $PORT ``` where PYTHON_EXECUTABLE is the python which installs PaddleFL, PARTY_ID is the ID of computation party, which is 0, 1, or 2, SERVER and PORT represent the IP and port of Redis server respectively. Similarly, training loss with cypher text format would be printed on the screen of each computation party. And at the same time, the loss and predictions would be saved in `/tmp` directory. **Note** that remember to delete the loss and prediction files in `/tmp` directory generated in last running, in case of any influence on the decrypted results of current running. #### (5). Decrypt Loss and Prediction Data Each computation party sends `uci_loss.part` and `uci_prediction.part` files in `/tmp` directory to the `/tmp` directory of data owner. Data owner decrypts and gets the plain text of loss and predictions with ` load_decrypt_data()` in `process_data.py`. For example, the following code can be written into a python script to decrypt and print training loss. ```python import process_data print("uci_loss:") process_data.load_decrypt_data("/tmp/uci_loss", (1,)) ``` And the following code can be written into a python script to decrypt and print predictions. ```python import process_data print("prediction:") process_data.load_decrypt_data("/tmp/uci_prediction", (BATCH_SIZE,)) ``` ### 3. Convergence of paddle_fl.mpc vs paddle Below, is the result of our experiment to test the convergence of paddle_fl.mpc on single machine. #### (1). Training Parameters - Dataset: Boston house price dataset - Number of Epoch: 20 - Batch Size: 10 #### (2). Experiment Results | Epoch/Step | paddle_fl.mpc | Paddle | | ---------- | ------------- | ------ | | Epoch=0, Step=0 | 738.39491 | 738.46204 | | Epoch=1, Step=0 | 630.68834 | 629.9071 | | Epoch=2, Step=0 | 539.54683 | 538.1757 | | Epoch=3, Step=0 | 462.41159 | 460.64722 | | Epoch=4, Step=0 | 397.11516 | 395.11017 | | Epoch=5, Step=0 | 341.83102 | 339.69815 | | Epoch=6, Step=0 | 295.01114 | 292.83597 | | Epoch=7, Step=0 | 255.35141 | 253.19429 | | Epoch=8, Step=0 | 221.74739 | 219.65132 | | Epoch=9, Step=0 | 193.26459 | 191.25981 | | Epoch=10, Step=0 | 169.11423 | 167.2204 | | Epoch=11, Step=0 | 148.63138 | 146.85835 | | Epoch=12, Step=0 | 131.25081 | 129.60391 | | Epoch=13, Step=0 | 116.49708 | 114.97599 | | Epoch=14, Step=0 | 103.96669 | 102.56854 | | Epoch=15, Step=0 | 93.31706 | 92.03858 | | Epoch=16, Step=0 | 84.26219 | 83.09653 | | Epoch=17, Step=0 | 76.55664 | 75.49785 | | Epoch=18, Step=0 | 69.99673 | 69.03561 | | Epoch=19, Step=0 | 64.40562 | 63.53539 |