[MAIN] init git repo , implement fitter class, organize workdir of repo

clutter_chuva/__init__.py

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+from .fitting import Fitter, DistributionSummary
+
+__all__ = ["Fitter", "DistributionSummary"]

clutter_chuva/fitting/__init__.py

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+from .fitter import Fitter, DistributionSummary
+
+__all__ = ["Fitter", "DistributionSummary"]

clutter_chuva/fitting/fitter.py

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+from dataclasses import dataclass, field
+
+import numpy as np
+import plotly.graph_objects as go
+import matplotlib.pyplot as plt
+import seaborn as sns
+from scipy.stats import rv_continuous, goodness_of_fit
+
+
+@dataclass
+class DistributionSummary:
+    """
+    Summary of a single distribution fit against a dataset.
+
+    Attributes
+    ----------
+    distribution_object : rv_continuous
+        The scipy distribution object used for fitting.
+    distribution_name : str
+        Human-readable name of the distribution.
+    args_fit_params : tuple
+        Initial guess positional parameters passed to fit() (empty tuple if none).
+    kwds_fit_params : dict
+        Keyword arguments that were passed to fit() (fixed params, etc.).
+    fit_result_params : tuple
+        The actual fitted parameters returned by fit() (empty tuple until fit() is called).
+    statistic_method : str
+        GoF statistic identifier used in validate() (e.g. 'ad', 'ks').
+    test_result : object
+        Result object from scipy.stats.goodness_of_fit; None until
+        validate() is called. Exposes .statistic and .pvalue.
+
+    Computed properties
+    -------------------
+    pvalue      : float | None    – p-value from the GoF test
+    gof_statistic : float | None  – test statistic from the GoF test
+    mean        : float           – mean of the fitted distribution
+    std         : float           – standard deviation of the fitted distribution
+    var         : float           – variance of the fitted distribution
+    """
+
+    distribution_object: rv_continuous
+    distribution_name: str
+    args_fit_params: tuple = field(default_factory=tuple)
+    kwds_fit_params: dict = field(default_factory=dict)
+    fit_result_params: tuple = field(default_factory=tuple)
+    statistic_method: str = 'ad'
+    test_result: object = None
+
+    # ── properties ────────────────────────────────────────────────
+
+    @property
+    def pvalue(self) -> float | None:
+        """p-value from the goodness-of-fit test, or None if not yet run."""
+        return self.test_result.pvalue if self.test_result is not None else None
+
+    @property
+    def gof_statistic(self) -> float | None:
+        """Test statistic from the goodness-of-fit test, or None if not yet run."""
+        return self.test_result.statistic if self.test_result is not None else None
+
+    @property
+    def mean(self) -> float:
+        """Mean of the fitted distribution."""
+        return self.distribution_object.mean(*self.fit_result_params)
+
+    @property
+    def std(self) -> float:
+        """Standard deviation of the fitted distribution."""
+        return self.distribution_object.std(*self.fit_result_params)
+
+    @property
+    def var(self) -> float:
+        """Variance of the fitted distribution."""
+        return self.distribution_object.var(*self.fit_result_params)
+
+    def __repr__(self) -> str:
+        pval_str = f"{self.pvalue:.4f}" if self.pvalue is not None else "N/A"
+        stat_str = f"{self.gof_statistic:.4f}" if self.gof_statistic is not None else "N/A"
+        return (
+            f"DistributionSummary({self.distribution_name})"
+            f"  params={self.fit_result_params}"
+            f"  mean={self.mean:.4f}  std={self.std:.4f}"
+            f"  GoF[{self.statistic_method}]={stat_str}  p={pval_str}"
+        )
+
+    def __str__(self) -> str:
+        return self.__repr__()
+
+
+class Fitter:
+    """
+    Fits and evaluates multiple distributions against a dataset.
+
+    Parameters
+    ----------
+    dist_list : list[rv_continuous]
+        Distributions to fit.
+    statistic_method : str
+        Goodness-of-fit statistic passed to goodness_of_fit (default 'ad').
+    **kwargs :
+        Per-distribution initial guesses and fixed parameters, keyed as:
+          - ``<dist.name>_args``   : tuple of positional initial guesses
+          - ``<dist.name>_params`` : dict of keyword fixed parameters
+        Example:
+            Fitter(
+                [gamma, weibull_min],
+                gamma_args=(2.0,),
+                gamma_params={'floc': 0},
+                weibull_min_args=(1.5, 0.0, 1.0),
+            )
+
+    Access fitted distributions
+    ---------------------------
+    Distributions can be accessed by name (str) or by the rv_continuous object:
+
+        fitter = Fitter([gamma, weibull_min])
+        fitter.fit(data)
+
+        # Access by name
+        summary = fitter['gamma']
+
+        # Access by rv_continuous object
+        summary = fitter[gamma]
+
+        # Check if a distribution is present
+        gamma in fitter       # True
+        'weibull_min' in fitter  # True
+
+        # Override a DistributionSummary
+        fitter['gamma'] = new_summary
+    """
+
+    def __init__(self, dist_list: list[rv_continuous], statistic_method: str = 'ad', **kwargs):
+        self._dist: dict[str, DistributionSummary] = {}
+        self.dist_list = list(dist_list)
+        for dist in dist_list:
+            self._dist[dist.name] = DistributionSummary(
+                distribution_object=dist,
+                distribution_name=dist.name,
+                args_fit_params=kwargs.get(f'{dist.name}_args', ()),
+                kwds_fit_params=kwargs.get(f'{dist.name}_params', {}),
+                statistic_method=statistic_method,
+                test_result=None,
+            )
+
+    #── Getter and setter with flexible keys (str or rv_continuous) ────────────────────────────────
+    def _resolve_key(self, key: str | rv_continuous) -> str:
+        """Resolve a distribution name or rv_continuous object to its string key."""
+        name = key.name if isinstance(key, rv_continuous) else key
+        if name not in self._dist:
+            available = ', '.join(self._dist)
+            raise KeyError(f"Distribution '{name}' not found. Available: {available}")
+        return name
+
+    def __contains__(self, key: str | rv_continuous) -> bool:
+        name = key.name if isinstance(key, rv_continuous) else key
+        return name in self._dist
+
+    def __getitem__(self, key: str | rv_continuous) -> DistributionSummary:
+        return self._dist[self._resolve_key(key)]
+
+    def __setitem__(self, key: str | rv_continuous, summary: DistributionSummary) -> None:
+        if not isinstance(summary, DistributionSummary):
+            raise TypeError(f"Expected DistributionSummary, got {type(summary).__name__}.")
+        self._dist[self._resolve_key(key)] = summary
+
+
+
+    def fit(self, data: np.ndarray) -> None:
+        """
+        Fit every distribution to *data* via MLE.
+
+        Parameters
+        ----------
+        data : array-like
+            Input data. Only the absolute value is used.
+        """
+        data_flat = np.abs(data).flatten()
+        self._last_data_flat = data_flat
+
+        for dist in self.dist_list:
+            _summary = self._dist[dist.name]
+            fit_params = dist.fit(data_flat, *_summary.args_fit_params, **_summary.kwds_fit_params)
+            _summary.fit_result_params = fit_params
+            self._dist[dist.name] = _summary
+
+    def validate(self, **kwargs) -> None:
+        """
+        Run the goodness-of-fit test on every previously fitted distribution.
+
+        Parameters
+        ----------
+        **kwargs :
+            Extra keyword arguments forwarded to goodness_of_fit()
+            (e.g. n_mc_samples=100).
+        """
+        if not hasattr(self, '_last_data_flat'):
+            raise RuntimeError("No data available. Call fit() first.")
+
+        data_flat = self._last_data_flat
+        for dist in self.dist_list:
+            _summary = self._dist[dist.name]
+            test_result = goodness_of_fit(
+                dist,
+                data_flat,
+                statistic=_summary.statistic_method,
+                **kwargs
+            )
+            _summary.test_result = test_result
+            self._dist[dist.name] = _summary
+
+    def summary(self) -> None:
+        """Print a summary of all fitted distributions."""
+        for dist_name, summary in self._dist.items():
+            print(summary)
+
+    def plot_qq_plots(self) -> None:
+        """
+        Generate QQ plots for each fitted distribution against the data.
+        Requires fit() and validate() to have been called.
+        """
+        if not hasattr(self, '_last_data_flat'):
+            raise RuntimeError("No data available. Call fit() first.")
+
+        data_flat = self._last_data_flat
+        for dist_name, summary in self._dist.items():
+            if summary.test_result is None:
+                print(f"Distribution '{dist_name}' has not been validated yet. Skipping QQ plot.")
+                continue
+
+            sorted_data = np.sort(data_flat)
+            theoretical_quantiles = summary.distribution_object.ppf(
+                (np.arange(1, len(sorted_data) + 1) - 0.5) / len(sorted_data),
+                *summary.fit_result_params
+            )
+
+            fig = go.Figure()
+            fig.add_trace(go.Scatter(x=theoretical_quantiles, y=sorted_data, mode='markers', name='Data vs. Fit'))
+            fig.add_trace(go.Scatter(x=theoretical_quantiles, y=theoretical_quantiles, mode='lines', name='Ideal Fit', line=dict(dash='dash')))
+            fig.update_layout(
+                title=f'QQ Plot for {summary.distribution_name}',
+                xaxis_title='Theoretical Quantiles',
+                yaxis_title='Empirical Quantiles',
+                autosize=True,
+            )
+            fig.show()
+
+    def histogram_with_fits(self) -> go.Figure:
+        """
+        Histogram of the data with overlaid PDFs (Plotly).
+        Requires fit() to have been called.
+        """
+        if not hasattr(self, '_last_data_flat'):
+            raise RuntimeError("No data available. Call fit() first.")
+
+        data_flat = self._last_data_flat
+        x = np.linspace(0, data_flat.max(), 1000)
+
+        fig = go.Figure(layout=go.Layout(hovermode='x unified'))
+        fig.add_trace(go.Histogram(
+            x=data_flat, name='Data', opacity=0.3,
+            histnorm='probability density', hoverinfo='skip', marker_color='blue',
+        ))
+        for dist_name, summary in self._dist.items():
+            if not summary.fit_result_params:
+                print(f"Distribution '{dist_name}' has not been fitted yet. Skipping PDF overlay.")
+                continue
+
+            pdf_values = summary.distribution_object.pdf(x, *summary.fit_result_params)
+            fig.add_trace(go.Scatter(x=x, y=pdf_values, mode='lines', name=f'{summary.distribution_name} Fit'))
+            hover_text = [
+                f"<b>{summary.distribution_name}</b>  p-value: {summary.pvalue:.4f}  GoF: {summary.gof_statistic:.4f}"
+                for _ in x
+            ]
+            fig.data[-1].update(hovertext=hover_text, hoverinfo="text")
+
+        fig.update_layout(
+            xaxis=dict(showgrid=True),
+            yaxis=dict(showgrid=True),
+            title=dict(
+                text='Histogram of Data with Fitted Distributions',
+                x=0.02, y=0.95, xanchor='left', yanchor='top',
+                font=dict(size=20, color='darkgray', family='sans-serif'),
+            ),
+            xaxis_title='Value',
+            yaxis_title='Density',
+            autosize=True,
+        )
+        return fig
+
+    def histogram_with_fits_seaborn(self) -> plt.Figure:
+        """
+        Histogram of the data with overlaid PDFs (Matplotlib/Seaborn).
+        Requires fit() to have been called.
+        """
+        if not hasattr(self, '_last_data_flat'):
+            raise RuntimeError("No data available. Call fit() first.")
+
+        data_flat = self._last_data_flat
+        x = np.linspace(0, data_flat.max(), 1000)
+
+        fig, ax = plt.subplots(figsize=(10, 6))
+        sns.histplot(data_flat, bins=int(np.sqrt(len(data_flat))), kde=False, stat='density', color='blue', alpha=0.2, ax=ax)
+
+        for dist_name, summary in self._dist.items():
+            if not summary.fit_result_params:
+                print(f"Distribution '{dist_name}' has not been fitted yet. Skipping PDF overlay.")
+                continue
+
+            pdf_values = summary.distribution_object.pdf(x, *summary.fit_result_params)
+            ax.plot(x, pdf_values, label=f'{summary.distribution_name} --- p={summary.pvalue:.4f}')
+
+        ax.set_title('Histogram of Data with Fitted Distributions', fontsize=8, loc='left', color='darkgray', fontfamily='sans-serif')
+        ax.set_xlabel('Value')
+        ax.set_ylabel('Density')
+        ax.legend()
+        ax.grid(True)
+        return fig