Seaborn's creator has unfortunately stated that he won't add such a feature. Below are some options. (The last section contains my original suggestion, which was a hack that used private implementation details of `seaborn`

and was not particularly flexible.)

# Simple alternative version of `regplot`

The following function overlays a fit line on a scatter plot and returns the results from `statsmodels`

. This supports the simplest and perhaps most common usage for `sns.regplot`

, but does not implement any of the fancier functionality.

```
import statsmodels.api as sm
def simple_regplot(
x, y, n_std=2, n_pts=100, ax=None, scatter_kws=None, line_kws=None, ci_kws=None
):
""" Draw a regression line with error interval. """
ax = plt.gca() if ax is None else ax
# calculate best-fit line and interval
x_fit = sm.add_constant(x)
fit_results = sm.OLS(y, x_fit).fit()
eval_x = sm.add_constant(np.linspace(np.min(x), np.max(x), n_pts))
pred = fit_results.get_prediction(eval_x)
# draw the fit line and error interval
ci_kws = {} if ci_kws is None else ci_kws
ax.fill_between(
eval_x[:, 1],
pred.predicted_mean - n_std * pred.se_mean,
pred.predicted_mean + n_std * pred.se_mean,
alpha=0.5,
**ci_kws,
)
line_kws = {} if line_kws is None else line_kws
h = ax.plot(eval_x[:, 1], pred.predicted_mean, **line_kws)
# draw the scatterplot
scatter_kws = {} if scatter_kws is None else scatter_kws
ax.scatter(x, y, c=h[0].get_color(), **scatter_kws)
return fit_results
```

The results from `statsmodels`

contain a wealth of information, *e.g.*:

```
>>> print(fit_results.summary())
OLS Regression Results
==============================================================================
Dep. Variable: y R-squared: 0.477
Model: OLS Adj. R-squared: 0.471
Method: Least Squares F-statistic: 89.23
Date: Fri, 08 Jan 2021 Prob (F-statistic): 1.93e-15
Time: 17:56:00 Log-Likelihood: -137.94
No. Observations: 100 AIC: 279.9
Df Residuals: 98 BIC: 285.1
Df Model: 1
Covariance Type: nonrobust
==============================================================================
coef std err t P>|t| [0.025 0.975]
------------------------------------------------------------------------------
const -0.1417 0.193 -0.735 0.464 -0.524 0.241
x1 3.1456 0.333 9.446 0.000 2.485 3.806
==============================================================================
Omnibus: 2.200 Durbin-Watson: 1.777
Prob(Omnibus): 0.333 Jarque-Bera (JB): 1.518
Skew: -0.002 Prob(JB): 0.468
Kurtosis: 2.396 Cond. No. 4.35
==============================================================================
Notes:
[1] Standard Errors assume that the covariance matrix of the errors is correctly specified.
```

# A drop-in replacement (almost) for `sns.regplot`

The advantage of the method above over my original answer below is that it's easy to extend it to more complex fits.

Shameless plug: here is such an extended `regplot`

function that I wrote that implements a large fraction of `sns.regplot`

's functionality: https://github.com/ttesileanu/pydove.

While some features are still missing, the function I wrote

- allows flexibility by separating the plotting from the statistical modeling (and you also get easy access to the fitting results).
- is much faster for large datasets because it lets
`statsmodels`

calculate confidence intervals instead of using bootstrapping.
- allows for slightly more diverse fits (
*e.g.,* polynomials in `log(x)`

).
- allows for slightly more fine-grained plotting options.

# Old answer

Seaborn's creator has unfortunately stated that he won't add such a feature, so here's a workaround.

```
def regplot(
*args,
line_kws=None,
marker=None,
scatter_kws=None,
**kwargs
):
# this is the class that `sns.regplot` uses
plotter = sns.regression._RegressionPlotter(*args, **kwargs)
# this is essentially the code from `sns.regplot`
ax = kwargs.get("ax", None)
if ax is None:
ax = plt.gca()
scatter_kws = {} if scatter_kws is None else copy.copy(scatter_kws)
scatter_kws["marker"] = marker
line_kws = {} if line_kws is None else copy.copy(line_kws)
plotter.plot(ax, scatter_kws, line_kws)
# unfortunately the regression results aren't stored, so we rerun
grid, yhat, err_bands = plotter.fit_regression(plt.gca())
# also unfortunately, this doesn't return the parameters, so we infer them
slope = (yhat[-1] - yhat[0]) / (grid[-1] - grid[0])
intercept = yhat[0] - slope * grid[0]
return slope, intercept
```

Note that this only works for linear regression because it simply infers the slope and intercept from the regression results. The nice thing is that it uses `seaborn`

's own regression class and so the results are guaranteed to be consistent with what's shown. The downside is of course that we're using a private implementation detail in `seaborn`

that can break at any point.