"""Plots for aperiodic fits and parameters."""

from itertools import cycle

import numpy as np

from fooof.sim.gen import gen_freqs, gen_aperiodic

from fooof.core.modutils import safe_import, check_dependency

from fooof.plts.settings import PLT_FIGSIZES

from fooof.plts.style import check_n_style, style_param_plot

from fooof.plts.utils import check_ax, recursive_plot, check_plot_kwargs

plt = safe_import('.pyplot', 'matplotlib')

###################################################################################################

###################################################################################################

@check_dependency(plt, 'matplotlib')

def plot_aperiodic_params(aps, colors=None, labels=None,

ax=None, plot_style=style_param_plot, **plot_kwargs):

"""Plot aperiodic parameters as dots representing offset and exponent value.

Parameters

----------

aps : 2d array or list of 2d array

Aperiodic parameters. Each row is a parameter set, as [Off, Exp] or [Off, Knee, Exp].

colors : str or list of str, optional

Color(s) to plot data.

labels : list of str, optional

Label(s) for plotted data, to be added in a legend.

ax : matplotlib.Axes, optional

Figure axes upon which to plot.

plot_style : callable, optional, default: style_param_plot

A function to call to apply styling & aesthetics to the plot.

**plot_kwargs

Keyword arguments to pass into the plot call.

"""

ax = check_ax(ax, plot_kwargs.pop('figsize', PLT_FIGSIZES['params']))

if isinstance(aps, list):

recursive_plot(aps, plot_aperiodic_params, ax, colors=colors, labels=labels,

plot_style=plot_style, **plot_kwargs)

else:

# Unpack data: offset as x; exponent as y

xs, ys = aps[:, 0], aps[:, -1]

sizes = plot_kwargs.pop('s', 150)

plot_kwargs = check_plot_kwargs(plot_kwargs, {'alpha' : 0.7})

ax.scatter(xs, ys, sizes, c=colors, label=labels, **plot_kwargs)

# Add axis labels

ax.set_xlabel('Offset')

ax.set_ylabel('Exponent')

check_n_style(plot_style, ax)

@check_dependency(plt, 'matplotlib')

def plot_aperiodic_fits(aps, freq_range, control_offset=False,

log_freqs=False, colors=None, labels=None,

ax=None, plot_style=style_param_plot, **plot_kwargs):

"""Plot reconstructions of model aperiodic fits.

Parameters

----------

aps : 2d array

Aperiodic parameters. Each row is a parameter set, as [Off, Exp] or [Off, Knee, Exp].

freq_range : list of [float, float]

The frequency range to plot the peak fits across, as [f_min, f_max].

control_offset : boolean, optional, default: False

Whether to control for the offset, by setting it to zero.

log_freqs : boolean, optional, default: False

Whether to plot the x-axis in log space.

colors : str or list of str, optional

Color(s) to plot data.

labels : list of str, optional

Label(s) for plotted data, to be added in a legend.

ax : matplotlib.Axes, optional

Figure axes upon which to plot.

plot_style : callable, optional, default: style_param_plot

A function to call to apply styling & aesthetics to the plot.

**plot_kwargs

Keyword arguments to pass into the plot call.

"""

ax = check_ax(ax, plot_kwargs.pop('figsize', PLT_FIGSIZES['params']))

if isinstance(aps, list):

if not colors:

colors = cycle(plt.rcParams['axes.prop_cycle'].by_key()['color'])

recursive_plot(aps, plot_function=plot_aperiodic_fits, ax=ax,

freq_range=tuple(freq_range),

control_offset=control_offset,

log_freqs=log_freqs, colors=colors, labels=labels,

plot_style=plot_style, **plot_kwargs)

else:

freqs = gen_freqs(freq_range, 0.1)

plt_freqs = np.log10(freqs) if log_freqs else freqs

colors = colors[0] if isinstance(colors, list) else colors

avg_vals = np.zeros(shape=[len(freqs)])

for ap_params in aps:

if control_offset:

# Copy the object to not overwrite any data

ap_params = ap_params.copy()

ap_params[0] = 0

# Recreate & plot the aperiodic component from parameters

ap_vals = gen_aperiodic(freqs, ap_params)

plot_kwargs = check_plot_kwargs(plot_kwargs, {'alpha' : 0.35, 'linewidth' : 1.25})

ax.plot(plt_freqs, ap_vals, color=colors, **plot_kwargs)

# Collect a running average across components

avg_vals = np.nansum(np.vstack([avg_vals, ap_vals]), axis=0)

# Plot the average component

avg = avg_vals / aps.shape[0]

avg_color = 'black' if not colors else colors

ax.plot(plt_freqs, avg, linewidth=plot_kwargs.get('linewidth')*3,

color=avg_color, label=labels)

# Add axis labels

ax.set_xlabel('log(Frequency)' if log_freqs else 'Frequency')

ax.set_ylabel('log(Power)')

# Set plot limit

ax.set_xlim(np.log10(freq_range) if log_freqs else freq_range)

# Apply plot style

check_n_style(plot_style, ax)