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Update README to use scikit-learn API
Browse files- README.md +65 -42
- example.py +10 -12
README.md
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@@ -73,71 +73,94 @@ Most common issues at this stage are solved
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by [tweaking the Julia package server](https://github.com/MilesCranmer/PySR/issues/27).
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to use up-to-date packages.
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## Docker
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You can also test out PySR in Docker, without
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installing it locally, by running the following command in
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the root directory of this repo:
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```bash
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docker build --pull --rm -f "Dockerfile" -t pysr "."
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```
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This builds an image called `pysr`. You can then run this with:
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```bash
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docker run -it --rm -v "$PWD:/data" pysr ipython
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```
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which will link the current directory to the container's `/data` directory
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and then launch ipython.
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# Quickstart
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```python
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import numpy as np
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from pysr import pysr, best
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# Dataset
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X = 2 * np.random.randn(100, 5)
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y = 2 * np.cos(X[:, 3]) + X[:, 0] ** 2 -
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niterations=5,
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binary_operators=["+", "*"],
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unary_operators=[
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"cos",
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"exp",
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"sin",
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"inv(x) = 1/x", # Define your own operator! (Julia syntax)
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],
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)
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...# (you can use ctl-c to exit early)
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print(best(equations))
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```
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```python
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```
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and cache functions from the symbolic regression backend.
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or `best_callable` to get a function you can call.
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This uses a score which balances complexity and error;
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however, one can see the full list of equations with:
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```python
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print(
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```
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- `MSE` - the mean square error of the formula
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- `score` - a metric akin to Occam's razor; you should use this to help select the "true" equation.
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- `sympy_format` - sympy equation.
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- `lambda_format` - a lambda function for that equation, that you can pass values through.
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by [tweaking the Julia package server](https://github.com/MilesCranmer/PySR/issues/27).
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to use up-to-date packages.
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# Quickstart
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Let's create a PySR example. First, let's import
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numpy to generate some test data:
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```python
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import numpy as np
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X = 2 * np.random.randn(100, 5)
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y = 2.5382 * np.cos(X[:, 3]) + X[:, 0] ** 2 - 0.5
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```
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We have created a dataset with 100 datapoints, with 5 features each.
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The relation we wish to model is $2.5382 \cos(x_3) + x_0^2 - 0.5$.
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Now, let's create a PySR model and train it.
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PySR's main interface is in the style of scikit-learn:
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```python
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from pysr import PySRRegressor
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model = PySRRegressor(
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niterations=5,
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populations=8,
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binary_operators=["+", "*"],
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unary_operators=[
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"cos",
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"exp",
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"sin",
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],
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model_selection="best",
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)
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```
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This will set up the model for 5 iterations of the search code, which contains hundreds of thousands of mutations and equation evaluations.
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Let's train this model on our dataset:
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```python
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model.fit(X, y)
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```
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Internally, this launches a Julia process which will do a multithreaded search for equations to fit the dataset.
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Equations will be printed during training, and once you are satisfied, you may
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quit early by hitting 'q' and then \<enter\>.
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After the model has been fit, you can run `model.predict(X)`
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to see the predictions on a given dataset.
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You may run:
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```python
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print(model)
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```
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to print the learned equations, which for the above should be close to:
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```python
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PySRRegressor.equations = [
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pick score Equation MSE Complexity
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0 0.000000 3.598587 3.044337e+01 1
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1 1.074135 (x0 * x0) 3.552313e+00 3
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2 0.023611 (-0.40477127 + (x0 * x0)) 3.388464e+00 5
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3 0.855682 ((x0 * x0) + cos(x3)) 1.440074e+00 6
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4 0.876831 ((x0 * x0) + (2.5026207 * cos(x3))) 2.493328e-01 8
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5 >>>> 10.687394 ((-0.5000114 + (x0 * x0)) + (2.5382013 * cos(x... 1.299652e-10 10
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6 2.573098 ((-0.50000024 + (x0 * x0)) + (2.5382 * sin(1.5... 7.565937e-13 12
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]
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```
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This arrow in the `pick` column indicates which equation is currently selected by your
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`model_selection` strategy for prediction.
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(You may change `model_selection` after `.fit(X, y)` as well.)
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`model.equations` is a pandas DataFrame containing all equations, including callable format
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(`lambda_format`),
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SymPy format (`sympy_format`), and even JAX and PyTorch format
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(both of which are differentiable).
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### Notes
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- `score` - a metric akin to Occam's razor; you should use this to help select the "true" equation.
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- `sympy_format` - sympy equation.
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- `lambda_format` - a lambda function for that equation, that you can pass values through.
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# Docker
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You can also test out PySR in Docker, without
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installing it locally, by running the following command in
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the root directory of this repo:
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```bash
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docker build --pull --rm -f "Dockerfile" -t pysr "."
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```
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This builds an image called `pysr`. You can then run this with:
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```bash
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docker run -it --rm -v "$PWD:/data" pysr ipython
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```
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which will link the current directory to the container's `/data` directory
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and then launch ipython.
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example.py
CHANGED
@@ -1,23 +1,21 @@
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import numpy as np
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from pysr import PySRRegressor
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y = 3 * np.cos(X[:, 3]) + X[:, 0] ** 2 - 2
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model = PySRRegressor(
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niterations=
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unary_operators=[
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"cos",
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"exp",
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"sin",
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"inv(x) = 2/x",
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],
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)
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model.fit(X, y)
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print(model)
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import numpy as np
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X = 2 * np.random.randn(100, 5)
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y = 2.5382 * np.cos(X[:, 3]) + X[:, 0] ** 2 - 0.5
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from pysr import PySRRegressor
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model = PySRRegressor(
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niterations=5,
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populations=8,
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binary_operators=["+", "*"],
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unary_operators=[
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"cos",
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"exp",
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"sin",
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],
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model_selection="best",
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)
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model.fit(X, y)
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print(model)
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