import os import sys import numpy as np import pandas as pd import sympy from sympy import sympify, lambdify import subprocess import tempfile import shutil from pathlib import Path from datetime import datetime import warnings from multiprocessing import cpu_count from sklearn.base import BaseEstimator, RegressorMixin is_julia_warning_silenced = False def install(julia_project=None): # pragma: no cover import julia julia.install() julia_project = _get_julia_project(julia_project) init_julia() from julia import Pkg Pkg.activate(f"{_escape_filename(julia_project)}") Pkg.update() Pkg.instantiate() Pkg.precompile() warnings.warn( "It is recommended to restart Python after installing PySR's dependencies," " so that the Julia environment is properly initialized." ) Main = None already_ran = False sympy_mappings = { "div": lambda x, y: x / y, "mult": lambda x, y: x * y, "sqrt_abs": lambda x: sympy.sqrt(abs(x)), "square": lambda x: x ** 2, "cube": lambda x: x ** 3, "plus": lambda x, y: x + y, "sub": lambda x, y: x - y, "neg": lambda x: -x, "pow": lambda x, y: abs(x) ** y, "cos": sympy.cos, "sin": sympy.sin, "tan": sympy.tan, "cosh": sympy.cosh, "sinh": sympy.sinh, "tanh": sympy.tanh, "exp": sympy.exp, "acos": sympy.acos, "asin": sympy.asin, "atan": sympy.atan, "acosh": lambda x: sympy.acosh(abs(x) + 1), "acosh_abs": lambda x: sympy.acosh(abs(x) + 1), "asinh": sympy.asinh, "atanh": lambda x: sympy.atanh(sympy.Mod(x + 1, 2) - 1), "atanh_clip": lambda x: sympy.atanh(sympy.Mod(x + 1, 2) - 1), "abs": abs, "mod": sympy.Mod, "erf": sympy.erf, "erfc": sympy.erfc, "log_abs": lambda x: sympy.log(abs(x)), "log10_abs": lambda x: sympy.log(abs(x), 10), "log2_abs": lambda x: sympy.log(abs(x), 2), "log1p_abs": lambda x: sympy.log(abs(x) + 1), "floor": sympy.floor, "ceil": sympy.ceiling, "sign": sympy.sign, "gamma": sympy.gamma, } def pysr(X, y, weights=None, **kwargs): warnings.warn( "Calling `pysr` is deprecated. Please use `model = PySRRegressor(**params); model.fit(X, y)` going forward.", DeprecationWarning, ) model = PySRRegressor(**kwargs) model.fit(X, y, weights=weights) return model.equations def _handle_constraints(binary_operators, unary_operators, constraints): for op in unary_operators: if op not in constraints: constraints[op] = -1 for op in binary_operators: if op not in constraints: constraints[op] = (-1, -1) if op in ["plus", "sub"]: if constraints[op][0] != constraints[op][1]: raise NotImplementedError( "You need equal constraints on both sides for - and *, due to simplification strategies." ) elif op == "mult": # Make sure the complex expression is in the left side. if constraints[op][0] == -1: continue if constraints[op][1] == -1 or constraints[op][0] < constraints[op][1]: constraints[op][0], constraints[op][1] = ( constraints[op][1], constraints[op][0], ) def _create_inline_operators(binary_operators, unary_operators): global Main for op_list in [binary_operators, unary_operators]: for i, op in enumerate(op_list): is_user_defined_operator = "(" in op if is_user_defined_operator: Main.eval(op) # Cut off from the first non-alphanumeric char: first_non_char = [ j for j, char in enumerate(op) if not (char.isalpha() or char.isdigit()) ][0] function_name = op[:first_non_char] op_list[i] = function_name def _handle_feature_selection(X, select_k_features, y, variable_names): if select_k_features is not None: selection = run_feature_selection(X, y, select_k_features) print(f"Using features {[variable_names[i] for i in selection]}") X = X[:, selection] else: selection = None return X, selection def _check_assertions( X, binary_operators, unary_operators, use_custom_variable_names, variable_names, weights, y, ): # Check for potential errors before they happen assert len(unary_operators) + len(binary_operators) > 0 assert len(X.shape) == 2 assert len(y.shape) in [1, 2] assert X.shape[0] == y.shape[0] if weights is not None: assert weights.shape == y.shape assert X.shape[0] == weights.shape[0] if use_custom_variable_names: assert len(variable_names) == X.shape[1] def run_feature_selection(X, y, select_k_features): """Use a gradient boosting tree regressor as a proxy for finding the k most important features in X, returning indices for those features as output.""" from sklearn.ensemble import RandomForestRegressor from sklearn.feature_selection import SelectFromModel clf = RandomForestRegressor(n_estimators=100, max_depth=3, random_state=0) clf.fit(X, y) selector = SelectFromModel( clf, threshold=-np.inf, max_features=select_k_features, prefit=True ) return selector.get_support(indices=True) def _escape_filename(filename): """Turns a file into a string representation with correctly escaped backslashes""" str_repr = str(filename) str_repr = str_repr.replace("\\", "\\\\") return str_repr def best(*args, **kwargs): raise NotImplementedError( "`best` has been deprecated. Please use the `PySRRegressor` interface. After fitting, you can return `.sympy()` to get the sympy representation of the best equation." ) def best_row(*args, **kwargs): raise NotImplementedError( "`best_row` has been deprecated. Please use the `PySRRegressor` interface. After fitting, you can run `print(model)` to view the best equation." ) def best_tex(*args, **kwargs): raise NotImplementedError( "`best_tex` has been deprecated. Please use the `PySRRegressor` interface. After fitting, you can return `.latex()` to get the sympy representation of the best equation." ) def best_callable(*args, **kwargs): raise NotImplementedError( "`best_callable` has been deprecated. Please use the `PySRRegressor` interface. After fitting, you can use `.predict(X)` to use the best callable." ) def _denoise(X, y, Xresampled=None): """Denoise the dataset using a Gaussian process""" from sklearn.gaussian_process import GaussianProcessRegressor from sklearn.gaussian_process.kernels import RBF, WhiteKernel, ConstantKernel gp_kernel = RBF(np.ones(X.shape[1])) + WhiteKernel(1e-1) + ConstantKernel() gpr = GaussianProcessRegressor(kernel=gp_kernel, n_restarts_optimizer=50) gpr.fit(X, y) if Xresampled is not None: return Xresampled, gpr.predict(Xresampled) return X, gpr.predict(X) class CallableEquation: """Simple wrapper for numpy lambda functions built with sympy""" def __init__(self, sympy_symbols, eqn, selection=None, variable_names=None): self._sympy = eqn self._sympy_symbols = sympy_symbols self._selection = selection self._variable_names = variable_names self._lambda = lambdify(sympy_symbols, eqn) def __repr__(self): return f"PySRFunction(X=>{self._sympy})" def __call__(self, X): if isinstance(X, pd.DataFrame): X = np.array(X[self._variable_names]) if self._selection is not None: return self._lambda(*X[:, self._selection].T) return self._lambda(*X.T) def _get_julia_project(julia_project): if julia_project is None: # Create temp directory: tmp_dir = tempfile.mkdtemp() tmp_dir = Path(tmp_dir) # Create Project.toml in temp dir: _write_project_file(tmp_dir) return tmp_dir else: return Path(julia_project) def silence_julia_warning(): global is_julia_warning_silenced is_julia_warning_silenced = True def init_julia(): """Initialize julia binary, turning off compiled modules if needed.""" global is_julia_warning_silenced from julia.core import JuliaInfo, UnsupportedPythonError info = JuliaInfo.load(julia="julia") if not info.is_pycall_built(): raise ImportError( """ Required dependencies are not installed or built. Run the following code in the Python REPL: >>> import pysr >>> pysr.install()""" ) Main = None try: from julia import Main as _Main Main = _Main except UnsupportedPythonError: if not is_julia_warning_silenced: warnings.warn( """ Your Python version is statically linked to libpython. For example, this could be the python included with conda, or maybe your system's built-in python. This will still work, but the precompilation cache for Julia will be turned off, which may result in slower startup times on the initial pysr() call. To install a Python version that is dynamically linked to libpython, pyenv is recommended (https://github.com/pyenv/pyenv). To silence this warning, you can run pysr.silence_julia_warning() after importing pysr.""" ) from julia.core import Julia jl = Julia(compiled_modules=False) from julia import Main as _Main Main = _Main return Main def _write_project_file(tmp_dir): """This writes a Julia Project.toml to a temporary directory The reason we need this is because sometimes Python will compile a project to binary, and then Julia can't read the Project.toml file. It is more reliable to have Python simply create the Project.toml from scratch. """ project_toml = """ [deps] SymbolicRegression = "8254be44-1295-4e6a-a16d-46603ac705cb" [compat] SymbolicRegression = "0.7.0" julia = "1.5" """ project_toml_path = tmp_dir / "Project.toml" project_toml_path.write_text(project_toml) class PySRRegressor(BaseEstimator, RegressorMixin): def __init__( self, model_selection="best", weights=None, binary_operators=None, unary_operators=None, procs=cpu_count(), loss="L2DistLoss()", populations=20, niterations=100, ncyclesperiteration=300, alpha=0.1, annealing=False, fractionReplaced=0.10, fractionReplacedHof=0.10, npop=1000, parsimony=1e-4, migration=True, hofMigration=True, shouldOptimizeConstants=True, topn=10, weightAddNode=1, weightInsertNode=3, weightDeleteNode=3, weightDoNothing=1, weightMutateConstant=10, weightMutateOperator=1, weightRandomize=1, weightSimplify=0.002, perturbationFactor=1.0, extra_sympy_mappings=None, extra_torch_mappings=None, extra_jax_mappings=None, equation_file=None, verbosity=1e9, progress=None, maxsize=20, fast_cycle=False, maxdepth=None, variable_names=None, batching=False, batchSize=50, select_k_features=None, warmupMaxsizeBy=0.0, constraints=None, useFrequency=True, tempdir=None, delete_tempfiles=True, julia_project=None, update=True, temp_equation_file=False, output_jax_format=False, output_torch_format=False, optimizer_algorithm="BFGS", optimizer_nrestarts=3, optimize_probability=1.0, optimizer_iterations=10, tournament_selection_n=10, tournament_selection_p=1.0, denoise=False, Xresampled=None, precision=32, multithreading=None, **kwargs, ): """Initialize settings for an equation search in PySR. Note: most default parameters have been tuned over several example equations, but you should adjust `niterations`, `binary_operators`, `unary_operators` to your requirements. You can view more detailed explanations of the options on the [options page](https://pysr.readthedocs.io/en/latest/docs/options/) of the documentation. :param model_selection: How to select a model. Can be 'accuracy' or 'best'. The default, 'best', will optimize a combination of complexity and accuracy. :type model_selection: str :param binary_operators: List of strings giving the binary operators in Julia's Base. Default is ["+", "-", "*", "/",]. :type binary_operators: list :param unary_operators: Same but for operators taking a single scalar. Default is []. :type unary_operators: list :param procs: Number of processes (=number of populations running). :type procs: int :param loss: String of Julia code specifying the loss function. Can either be a loss from LossFunctions.jl, or your own loss written as a function. Examples of custom written losses include: `myloss(x, y) = abs(x-y)` for non-weighted, or `myloss(x, y, w) = w*abs(x-y)` for weighted. Among the included losses, these are as follows. Regression: `LPDistLoss{P}()`, `L1DistLoss()`, `L2DistLoss()` (mean square), `LogitDistLoss()`, `HuberLoss(d)`, `L1EpsilonInsLoss(ϵ)`, `L2EpsilonInsLoss(ϵ)`, `PeriodicLoss(c)`, `QuantileLoss(τ)`. Classification: `ZeroOneLoss()`, `PerceptronLoss()`, `L1HingeLoss()`, `SmoothedL1HingeLoss(γ)`, `ModifiedHuberLoss()`, `L2MarginLoss()`, `ExpLoss()`, `SigmoidLoss()`, `DWDMarginLoss(q)`. :type loss: str :param populations: Number of populations running. :type populations: int :param niterations: Number of iterations of the algorithm to run. The best equations are printed, and migrate between populations, at the end of each. :type niterations: int :param ncyclesperiteration: Number of total mutations to run, per 10 samples of the population, per iteration. :type ncyclesperiteration: int :param alpha: Initial temperature. :type alpha: float :param annealing: Whether to use annealing. You should (and it is default). :type annealing: bool :param fractionReplaced: How much of population to replace with migrating equations from other populations. :type fractionReplaced: float :param fractionReplacedHof: How much of population to replace with migrating equations from hall of fame. :type fractionReplacedHof: float :param npop: Number of individuals in each population :type npop: int :param parsimony: Multiplicative factor for how much to punish complexity. :type parsimony: float :param migration: Whether to migrate. :type migration: bool :param hofMigration: Whether to have the hall of fame migrate. :type hofMigration: bool :param shouldOptimizeConstants: Whether to numerically optimize constants (Nelder-Mead/Newton) at the end of each iteration. :type shouldOptimizeConstants: bool :param topn: How many top individuals migrate from each population. :type topn: int :param perturbationFactor: Constants are perturbed by a max factor of (perturbationFactor*T + 1). Either multiplied by this or divided by this. :type perturbationFactor: float :param weightAddNode: Relative likelihood for mutation to add a node :type weightAddNode: float :param weightInsertNode: Relative likelihood for mutation to insert a node :type weightInsertNode: float :param weightDeleteNode: Relative likelihood for mutation to delete a node :type weightDeleteNode: float :param weightDoNothing: Relative likelihood for mutation to leave the individual :type weightDoNothing: float :param weightMutateConstant: Relative likelihood for mutation to change the constant slightly in a random direction. :type weightMutateConstant: float :param weightMutateOperator: Relative likelihood for mutation to swap an operator. :type weightMutateOperator: float :param weightRandomize: Relative likelihood for mutation to completely delete and then randomly generate the equation :type weightRandomize: float :param weightSimplify: Relative likelihood for mutation to simplify constant parts by evaluation :type weightSimplify: float :param equation_file: Where to save the files (.csv separated by |) :type equation_file: str :param verbosity: What verbosity level to use. 0 means minimal print statements. :type verbosity: int :param progress: Whether to use a progress bar instead of printing to stdout. :type progress: bool :param maxsize: Max size of an equation. :type maxsize: int :param maxdepth: Max depth of an equation. You can use both maxsize and maxdepth. maxdepth is by default set to = maxsize, which means that it is redundant. :type maxdepth: int :param fast_cycle: (experimental) - batch over population subsamples. This is a slightly different algorithm than regularized evolution, but does cycles 15% faster. May be algorithmically less efficient. :type fast_cycle: bool :param variable_names: a list of names for the variables, other than "x0", "x1", etc. :type variable_names: list :param batching: whether to compare population members on small batches during evolution. Still uses full dataset for comparing against hall of fame. :type batching: bool :param batchSize: the amount of data to use if doing batching. :type batchSize: int :param select_k_features: whether to run feature selection in Python using random forests, before passing to the symbolic regression code. None means no feature selection; an int means select that many features. :type select_k_features: None/int :param warmupMaxsizeBy: whether to slowly increase max size from a small number up to the maxsize (if greater than 0). If greater than 0, says the fraction of training time at which the current maxsize will reach the user-passed maxsize. :type warmupMaxsizeBy: float :param constraints: dictionary of int (unary) or 2-tuples (binary), this enforces maxsize constraints on the individual arguments of operators. E.g., `'pow': (-1, 1)` says that power laws can have any complexity left argument, but only 1 complexity exponent. Use this to force more interpretable solutions. :type constraints: dict :param useFrequency: whether to measure the frequency of complexities, and use that instead of parsimony to explore equation space. Will naturally find equations of all complexities. :type useFrequency: bool :param tempdir: directory for the temporary files :type tempdir: str/None :param delete_tempfiles: whether to delete the temporary files after finishing :type delete_tempfiles: bool :param julia_project: a Julia environment location containing a Project.toml (and potentially the source code for SymbolicRegression.jl). Default gives the Python package directory, where a Project.toml file should be present from the install. :type julia_project: str/None :param update: Whether to automatically update Julia packages. :type update: bool :param temp_equation_file: Whether to put the hall of fame file in the temp directory. Deletion is then controlled with the delete_tempfiles argument. :type temp_equation_file: bool :param output_jax_format: Whether to create a 'jax_format' column in the output, containing jax-callable functions and the default parameters in a jax array. :type output_jax_format: bool :param output_torch_format: Whether to create a 'torch_format' column in the output, containing a torch module with trainable parameters. :type output_torch_format: bool :param tournament_selection_n: Number of expressions to consider in each tournament. :type tournament_selection_n: int :param tournament_selection_p: Probability of selecting the best expression in each tournament. The probability will decay as p*(1-p)^n for other expressions, sorted by loss. :type tournament_selection_p: float :param denoise: Whether to use a Gaussian Process to denoise the data before inputting to PySR. Can help PySR fit noisy data. :type denoise: bool :param precision: What precision to use for the data. By default this is 32 (float32), but you can select 64 or 16 as well. :type precision: int :param multithreading: Use multithreading instead of distributed backend. Default is yes. Using procs=0 will turn off both. :type multithreading: bool :param **kwargs: Other options passed to SymbolicRegression.Options, for example, if you modify SymbolicRegression.jl to include additional arguments. :type **kwargs: dict :returns: Results dataframe, giving complexity, MSE, and equations (as strings), as well as functional forms. If list, each element corresponds to a dataframe of equations for each output. :type: pd.DataFrame/list """ super().__init__() self.model_selection = model_selection if binary_operators is None: binary_operators = "+ * - /".split(" ") if unary_operators is None: unary_operators = [] if extra_sympy_mappings is None: extra_sympy_mappings = {} if variable_names is None: variable_names = [] if constraints is None: constraints = {} if multithreading is None: # Default is multithreading=True, unless explicitly set, # or procs is set to 0 (serial mode). multithreading = procs != 0 buffer_available = "buffer" in sys.stdout.__dir__() if progress is not None: if progress and not buffer_available: warnings.warn( "Note: it looks like you are running in Jupyter. The progress bar will be turned off." ) progress = False else: progress = buffer_available assert optimizer_algorithm in ["NelderMead", "BFGS"] assert tournament_selection_n < npop if extra_jax_mappings is not None: for value in extra_jax_mappings.values(): if not isinstance(value, str): raise NotImplementedError( "extra_jax_mappings must have keys that are strings! e.g., {sympy.sqrt: 'jnp.sqrt'}." ) if extra_torch_mappings is not None: for value in extra_jax_mappings.values(): if not callable(value): raise NotImplementedError( "extra_torch_mappings must be callable functions! e.g., {sympy.sqrt: torch.sqrt}." ) if maxsize > 40: warnings.warn( "Note: Using a large maxsize for the equation search will be exponentially slower and use significant memory. You should consider turning `useFrequency` to False, and perhaps use `warmupMaxsizeBy`." ) elif maxsize < 7: raise NotImplementedError("PySR requires a maxsize of at least 7") if maxdepth is None: maxdepth = maxsize if isinstance(binary_operators, str): binary_operators = [binary_operators] if isinstance(unary_operators, str): unary_operators = [unary_operators] self.params = { **dict( weights=weights, binary_operators=binary_operators, unary_operators=unary_operators, procs=procs, loss=loss, populations=populations, niterations=niterations, ncyclesperiteration=ncyclesperiteration, alpha=alpha, annealing=annealing, fractionReplaced=fractionReplaced, fractionReplacedHof=fractionReplacedHof, npop=npop, parsimony=float(parsimony), migration=migration, hofMigration=hofMigration, shouldOptimizeConstants=shouldOptimizeConstants, topn=topn, weightAddNode=weightAddNode, weightInsertNode=weightInsertNode, weightDeleteNode=weightDeleteNode, weightDoNothing=weightDoNothing, weightMutateConstant=weightMutateConstant, weightMutateOperator=weightMutateOperator, weightRandomize=weightRandomize, weightSimplify=weightSimplify, perturbationFactor=perturbationFactor, verbosity=verbosity, progress=progress, maxsize=maxsize, fast_cycle=fast_cycle, maxdepth=maxdepth, batching=batching, batchSize=batchSize, select_k_features=select_k_features, warmupMaxsizeBy=warmupMaxsizeBy, constraints=constraints, useFrequency=useFrequency, tempdir=tempdir, delete_tempfiles=delete_tempfiles, update=update, temp_equation_file=temp_equation_file, optimizer_algorithm=optimizer_algorithm, optimizer_nrestarts=optimizer_nrestarts, optimize_probability=optimize_probability, optimizer_iterations=optimizer_iterations, tournament_selection_n=tournament_selection_n, tournament_selection_p=tournament_selection_p, denoise=denoise, Xresampled=Xresampled, precision=precision, multithreading=multithreading, ), **kwargs, } # Stored equations: self.equations = None self.multioutput = None self.raw_julia_output = None self.equation_file = equation_file self.n_features = None self.extra_sympy_mappings = extra_sympy_mappings self.extra_torch_mappings = extra_torch_mappings self.extra_jax_mappings = extra_jax_mappings self.output_jax_format = output_jax_format self.output_torch_format = output_torch_format self.nout = 1 self.selection = None self.variable_names = variable_names self.julia_project = julia_project self.surface_parameters = [ "model_selection", "multioutput", "raw_julia_output", "equation_file", "n_features", "extra_sympy_mappings", "extra_torch_mappings", "extra_jax_mappings", "output_jax_format", "output_torch_format", "nout", "selection", "variable_names", "julia_project", ] def __repr__(self): if self.equations is None: return "PySRRegressor.equations = None" equations = self.equations selected = ["" for _ in range(len(equations))] if self.model_selection == "accuracy": chosen_row = -1 elif self.model_selection == "best": chosen_row = equations["score"].idxmax() else: raise NotImplementedError selected[chosen_row] = ">>>>" output = "PySRRegressor.equations = [\n" repr_equations = pd.DataFrame( dict( pick=selected, score=equations["score"], equation=equations["equation"], loss=equations["loss"], complexity=equations["complexity"], ) ) output += repr_equations.__repr__() output += "\n]" return output def set_params(self, **params): """Set parameters for pysr.pysr call or model_selection strategy.""" for key, value in params.items(): if key in self.surface_parameters: self.__setattr__(key, value) else: self.params[key] = value self.refresh() return self def get_params(self, deep=True): del deep return { **self.params, **{p: self.__getattribute__(key) for key in self.surface_parameters}, } def get_best(self): if self.equations is None: return 0.0 if self.model_selection == "accuracy": return self.equations.iloc[-1] elif self.model_selection == "best": return best_row(self.equations) else: raise NotImplementedError def fit(self, X, y, weights=None, variable_names=None): """Search for equations to fit the dataset. :param X: 2D array. Rows are examples, columns are features. If pandas DataFrame, the columns are used for variable names (so make sure they don't contain spaces). :type X: np.ndarray/pandas.DataFrame :param y: 1D array (rows are examples) or 2D array (rows are examples, columns are outputs). Putting in a 2D array will trigger a search for equations for each feature of y. :type y: np.ndarray :param weights: Optional. Same shape as y. Each element is how to weight the mean-square-error loss for that particular element of y. :type weights: np.ndarray :param variable_names: a list of names for the variables, other than "x0", "x1", etc. :type variable_names: list """ if variable_names is None: variable_names = self.variable_names self._run( X=X, y=y, weights=weights, variable_names=variable_names, ) return self def refresh(self): # Updates self.equations with any new options passed, # such as extra_sympy_mappings. self.equations = self.get_hof() def predict(self, X): self.refresh() np_format = self.get_best()["lambda_format"] return np_format(X) def sympy(self): self.refresh() return self.get_best()["sympy_format"] def latex(self): self.refresh() return self.sympy().simplify() def jax(self): self.set_params(output_jax_format=True) self.refresh() return self.get_best()["jax_format"] def pytorch(self): self.set_params(output_torch_format=True) self.refresh() return self.get_best()["torch_format"] def _run(self, X, y, weights, variable_names): global already_ran global Main for key in self.surface_parameters: if key in self.params: raise ValueError( f"{key} is a surface parameter, and cannot be in self.params" ) multithreading = self.params["multithreading"] procs = self.params["procs"] binary_operators = self.params["binary_operators"] unary_operators = self.params["unary_operators"] batching = self.params["batching"] maxsize = self.params["maxsize"] select_k_features = self.params["select_k_features"] Xresampled = self.params["Xresampled"] denoise = self.params["denoise"] constraints = self.params["constraints"] update = self.params["update"] loss = self.params["loss"] weightMutateConstant = self.params["weightMutateConstant"] weightMutateOperator = self.params["weightMutateOperator"] weightAddNode = self.params["weightAddNode"] weightInsertNode = self.params["weightInsertNode"] weightDeleteNode = self.params["weightDeleteNode"] weightSimplify = self.params["weightSimplify"] weightRandomize = self.params["weightRandomize"] weightDoNothing = self.params["weightDoNothing"] if Main is None: if multithreading: os.environ["JULIA_NUM_THREADS"] = str(procs) Main = init_julia() if isinstance(X, pd.DataFrame): if variable_names is not None: warnings.warn("Resetting variable_names from X.columns") variable_names = list(X.columns) X = np.array(X) if len(X.shape) == 1: X = X[:, None] assert not isinstance(y, pd.DataFrame) if len(variable_names) == 0: variable_names = [f"x{i}" for i in range(X.shape[1])] use_custom_variable_names = len(variable_names) != 0 # TODO: this is always true. _check_assertions( X, binary_operators, unary_operators, use_custom_variable_names, variable_names, weights, y, ) self.n_features = X.shape[1] if len(X) > 10000 and not batching: warnings.warn( "Note: you are running with more than 10,000 datapoints. You should consider turning on batching (https://pysr.readthedocs.io/en/latest/docs/options/#batching). You should also reconsider if you need that many datapoints. Unless you have a large amount of noise (in which case you should smooth your dataset first), generally < 10,000 datapoints is enough to find a functional form with symbolic regression. More datapoints will lower the search speed." ) X, selection = _handle_feature_selection( X, select_k_features, y, variable_names ) if len(y.shape) == 1 or (len(y.shape) == 2 and y.shape[1] == 1): self.multioutput = False nout = 1 y = y.reshape(-1) elif len(y.shape) == 2: self.multioutput = True nout = y.shape[1] else: raise NotImplementedError("y shape not supported!") if denoise: if weights is not None: raise NotImplementedError( "No weights for denoising - the weights are learned." ) if Xresampled is not None: # Select among only the selected features: if isinstance(Xresampled, pd.DataFrame): # Handle Xresampled is pandas dataframe if selection is not None: Xresampled = Xresampled[[variable_names[i] for i in selection]] else: Xresampled = Xresampled[variable_names] Xresampled = np.array(Xresampled) else: if selection is not None: Xresampled = Xresampled[:, selection] if self.multioutput: y = np.stack( [ _denoise(X, y[:, i], Xresampled=Xresampled)[1] for i in range(nout) ], axis=1, ) if Xresampled is not None: X = Xresampled else: X, y = _denoise(X, y, Xresampled=Xresampled) self.julia_project = _get_julia_project(self.julia_project) tmpdir = Path(tempfile.mkdtemp(dir=self.params["tempdir"])) if self.params["temp_equation_file"]: self.equation_file = tmpdir / "hall_of_fame.csv" elif self.equation_file is None: date_time = datetime.now().strftime("%Y-%m-%d_%H%M%S.%f")[:-3] self.equation_file = "hall_of_fame_" + date_time + ".csv" _create_inline_operators( binary_operators=binary_operators, unary_operators=unary_operators ) _handle_constraints( binary_operators=binary_operators, unary_operators=unary_operators, constraints=constraints, ) una_constraints = [constraints[op] for op in unary_operators] bin_constraints = [constraints[op] for op in binary_operators] try: # TODO: is this needed since Julia now prints directly to stdout? term_width = shutil.get_terminal_size().columns except: _, term_width = subprocess.check_output(["stty", "size"]).split() if not already_ran: from julia import Pkg Pkg.activate(f"{_escape_filename(self.julia_project)}") try: if update: Pkg.resolve() Pkg.instantiate() else: Pkg.instantiate() except RuntimeError as e: raise ImportError( f""" Required dependencies are not installed or built. Run the following code in the Python REPL: >>> import pysr >>> pysr.install() Tried to activate project {self.julia_project} but failed.""" ) from e Main.eval("using SymbolicRegression") Main.plus = Main.eval("(+)") Main.sub = Main.eval("(-)") Main.mult = Main.eval("(*)") Main.pow = Main.eval("(^)") Main.div = Main.eval("(/)") Main.custom_loss = Main.eval(loss) mutationWeights = [ float(weightMutateConstant), float(weightMutateOperator), float(weightAddNode), float(weightInsertNode), float(weightDeleteNode), float(weightSimplify), float(weightRandomize), float(weightDoNothing), ] options = Main.Options( binary_operators=Main.eval(str(tuple(binary_operators)).replace("'", "")), unary_operators=Main.eval(str(tuple(unary_operators)).replace("'", "")), bin_constraints=bin_constraints, una_constraints=una_constraints, loss=Main.custom_loss, maxsize=int(maxsize), hofFile=_escape_filename(self.equation_file), npopulations=int(self.params["populations"]), batching=batching, batchSize=int( min([self.params["batchSize"], len(X)]) if batching else len(X) ), mutationWeights=mutationWeights, terminal_width=int(term_width), probPickFirst=self.params["tournament_selection_p"], ns=self.params["tournament_selection_n"], # These have the same name: parsimony=self.params["parsimony"], alpha=self.params["alpha"], maxdepth=self.params["maxdepth"], fast_cycle=self.params["fast_cycle"], migration=self.params["migration"], hofMigration=self.params["hofMigration"], fractionReplacedHof=self.params["fractionReplacedHof"], shouldOptimizeConstants=self.params["shouldOptimizeConstants"], warmupMaxsizeBy=self.params["warmupMaxsizeBy"], useFrequency=self.params["useFrequency"], npop=self.params["npop"], ncyclesperiteration=self.params["ncyclesperiteration"], fractionReplaced=self.params["fractionReplaced"], topn=self.params["topn"], verbosity=self.params["verbosity"], optimizer_algorithm=self.params["optimizer_algorithm"], optimizer_nrestarts=self.params["optimizer_nrestarts"], optimize_probability=self.params["optimize_probability"], optimizer_iterations=self.params["optimizer_iterations"], perturbationFactor=self.params["perturbationFactor"], annealing=self.params["annealing"], ) np_dtype = {16: np.float16, 32: np.float32, 64: np.float64}[ self.params["precision"] ] Main.X = np.array(X, dtype=np_dtype).T if len(y.shape) == 1: Main.y = np.array(y, dtype=np_dtype) else: Main.y = np.array(y, dtype=np_dtype).T if weights is not None: if len(weights.shape) == 1: Main.weights = np.array(weights, dtype=np_dtype) else: Main.weights = np.array(weights, dtype=np_dtype).T else: Main.weights = None cprocs = 0 if multithreading else procs self.raw_julia_output = Main.EquationSearch( Main.X, Main.y, weights=Main.weights, niterations=int(self.params["niterations"]), varMap=( variable_names if selection is None else [variable_names[i] for i in selection] ), options=options, numprocs=int(cprocs), multithreading=bool(multithreading), ) self.variable_names = variable_names self.selection = selection # Not in params: # selection, variable_names, multioutput self.equations = self.get_hof() if self.params["delete_tempfiles"]: shutil.rmtree(tmpdir) already_ran = True def get_hof(self): """Get the equations from a hall of fame file. If no arguments entered, the ones used previously from a call to PySR will be used.""" try: if self.multioutput: all_outputs = [] for i in range(1, self.nout + 1): df = pd.read_csv( str(self.equation_file) + f".out{i}" + ".bkup", sep="|", ) # Rename Complexity column to complexity: df.rename( columns={ "Complexity": "complexity", "MSE": "loss", "Equation": "equation", }, inplace=True, ) all_outputs.append(df) else: all_outputs = [pd.read_csv(str(self.equation_file) + ".bkup", sep="|")] all_outputs[-1].rename( columns={ "Complexity": "complexity", "MSE": "loss", "Equation": "equation", }, inplace=True, ) except FileNotFoundError: raise RuntimeError( "Couldn't find equation file! The equation search likely exited before a single iteration completed." ) ret_outputs = [] for output in all_outputs: scores = [] lastMSE = None lastComplexity = 0 sympy_format = [] lambda_format = [] if self.output_jax_format: jax_format = [] if self.output_torch_format: torch_format = [] use_custom_variable_names = len(self.variable_names) != 0 local_sympy_mappings = { **self.extra_sympy_mappings, **sympy_mappings, } if use_custom_variable_names: sympy_symbols = [ sympy.Symbol(self.variable_names[i]) for i in range(self.n_features) ] else: sympy_symbols = [ sympy.Symbol("x%d" % i) for i in range(self.n_features) ] for _, eqn_row in output.iterrows(): eqn = sympify(eqn_row["equation"], locals=local_sympy_mappings) sympy_format.append(eqn) # Numpy: lambda_format.append( CallableEquation( sympy_symbols, eqn, self.selection, self.variable_names ) ) # JAX: if self.output_jax_format: from .export_jax import sympy2jax func, params = sympy2jax( eqn, sympy_symbols, selection=self.selection, extra_jax_mappings=self.extra_jax_mappings, ) jax_format.append({"callable": func, "parameters": params}) # Torch: if self.output_torch_format: from .export_torch import sympy2torch module = sympy2torch( eqn, sympy_symbols, selection=self.selection, extra_torch_mappings=self.extra_torch_mappings, ) torch_format.append(module) curMSE = eqn_row["loss"] curComplexity = eqn_row["complexity"] if lastMSE is None: cur_score = 0.0 else: if curMSE > 0.0: cur_score = -np.log(curMSE / lastMSE) / ( curComplexity - lastComplexity ) else: cur_score = np.inf scores.append(cur_score) lastMSE = curMSE lastComplexity = curComplexity output["score"] = np.array(scores) output["sympy_format"] = sympy_format output["lambda_format"] = lambda_format output_cols = [ "complexity", "loss", "score", "equation", "sympy_format", "lambda_format", ] if self.output_jax_format: output_cols += ["jax_format"] output["jax_format"] = jax_format if self.output_torch_format: output_cols += ["torch_format"] output["torch_format"] = torch_format ret_outputs.append(output[output_cols]) if self.multioutput: return ret_outputs return ret_outputs[0]