import math
import numpy as np
import matplotlib
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d.art3d import Poly3DCollection
import mpl_toolkits.mplot3d.axes3d as p3
from textwrap import wrap
from tqdm import tqdm

def list_cut_average(ll, intervals):
    if intervals == 1:
        return ll

    bins = math.ceil(len(ll) * 1.0 / intervals)
    ll_new = []
    for i in range(bins):
        l_low = intervals * i
        l_high = l_low + intervals
        l_high = l_high if l_high < len(ll) else len(ll)
        ll_new.append(np.mean(ll[l_low:l_high]))
    return ll_new


def plot_3d_motion(kinematic_tree, joints, title, dataset="humanml", figsize=(10.24, 10.24), radius=3,
                   vis_mode='default', gt_frames=[]):
    matplotlib.use('Agg')
    title = '\n'.join(wrap(title, 40))

    def init():
        ax.set_xlim3d([-radius / 2, radius / 2])
        ax.set_ylim3d([0, radius])
        ax.set_zlim3d([-radius / 3., radius * 2 / 3.])
        # print(title)
        fig.suptitle(title, fontsize=20)
        ax.grid(b=False)

    def plot_xzPlane(minx, maxx, miny, minz, maxz):
        ## Plot a plane XZ
        verts = [
            [minx, miny, minz],
            [minx, miny, maxz],
            [maxx, miny, maxz],
            [maxx, miny, minz]
        ]
        xz_plane = Poly3DCollection([verts])
        xz_plane.set_facecolor((0.5, 0.5, 0.5, 0.5))
        ax.add_collection3d(xz_plane)

    #         return ax

    # (seq_len, joints_num, 3)
    data = joints.copy().reshape(len(joints), -1, 3)

    # preparation related to specific datasets
    if dataset == 'kit':
        data *= 0.003  # scale for visualization
    elif dataset == 'humanml':
        data *= 1.3  # scale for visualization
    elif dataset in ['humanact12', 'uestc']:
        data *= -1.5 # reverse axes, scale for visualization

    fig = plt.figure(figsize=figsize)
    plt.tight_layout()
    ax = p3.Axes3D(fig)
    init()
    MINS = data.min(axis=0).min(axis=0)
    MAXS = data.max(axis=0).max(axis=0)
    colors_blue = ["#4D84AA", "#5B9965", "#61CEB9", "#34C1E2", "#80B79A"]  # GT color
    colors_orange = ["#DD5A37", "#D69E00", "#B75A39", "#FF6D00", "#DDB50E"]  # Generation color
    colors = colors_orange
    if vis_mode == 'upper_body':  # lower body taken fixed to input motion
        colors[0] = colors_blue[0]
        colors[1] = colors_blue[1]
    elif vis_mode == 'gt':
        colors = colors_blue

    frame_number = data.shape[0]
    #     print(dataset.shape)

    height_offset = MINS[1]
    data[:, :, 1] -= height_offset
    trajec = data[:, 0, [0, 2]]

    data[..., 0] -= data[:, 0:1, 0]
    data[..., 2] -= data[:, 0:1, 2]

    #     print(trajec.shape)

    def update(index):
        #         print(index)
        ax.lines = []
        ax.collections = []
        ax.view_init(elev=120, azim=-90)
        ax.dist = 7.5
        #         ax =
        plot_xzPlane(MINS[0] - trajec[index, 0], MAXS[0] - trajec[index, 0], 0, MINS[2] - trajec[index, 1],
                     MAXS[2] - trajec[index, 1])

        used_colors = colors_blue if index in gt_frames else colors
        for i, (chain, color) in enumerate(zip(kinematic_tree, used_colors)):
            if i < 5:
                linewidth = 4.0
            else:
                linewidth = 2.0
            ax.plot3D(data[index, chain, 0], data[index, chain, 1], data[index, chain, 2], linewidth=linewidth,
                      color=color)
        #         print(trajec[:index, 0].shape)

        plt.axis('off')
        ax.set_xticklabels([])
        ax.set_yticklabels([])
        ax.set_zticklabels([])
    
    for i in tqdm(range(frame_number)):
        update(i)
        plt.savefig("temp/%06d.png"%(i))

    plt.close()