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Talkshow_Demo / evaluation /metrics.py
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 '''
Warning: metrics are for reference only, may have limited significance
'''
import os
import sys
sys.path.append(os.getcwd())
import numpy as np
import torch
from data_utils.lower_body import rearrange, symmetry
import torch.nn.functional as F
def data_driven_baselines(gt_kps):
'''
gt_kps: T, D
'''
gt_velocity = np.abs(gt_kps[1:] - gt_kps[:-1])
mean= np.mean(gt_velocity, axis=0)[np.newaxis] #(1, D)
mean = np.mean(np.abs(gt_velocity-mean))
last_step = gt_kps[1] - gt_kps[0]
last_step = last_step[np.newaxis] #(1, D)
last_step = np.mean(np.abs(gt_velocity-last_step))
return last_step, mean
def Batch_LVD(gt_kps, pr_kps, symmetrical, weight):
if gt_kps.shape[0] > pr_kps.shape[1]:
length = pr_kps.shape[1]
else:
length = gt_kps.shape[0]
gt_kps = gt_kps[:length]
pr_kps = pr_kps[:, :length]
global symmetry
symmetry = torch.tensor(symmetry).bool()
if symmetrical:
# rearrange for compute symmetric. ns means non-symmetrical joints, ys means symmetrical joints.
gt_kps = gt_kps[:, rearrange]
ns_gt_kps = gt_kps[:, ~symmetry]
ys_gt_kps = gt_kps[:, symmetry]
ys_gt_kps = ys_gt_kps.reshape(ys_gt_kps.shape[0], -1, 2, 3)
ns_gt_velocity = (ns_gt_kps[1:] - ns_gt_kps[:-1]).norm(p=2, dim=-1)
ys_gt_velocity = (ys_gt_kps[1:] - ys_gt_kps[:-1]).norm(p=2, dim=-1)
left_gt_vel = ys_gt_velocity[:, :, 0].sum(dim=-1)
right_gt_vel = ys_gt_velocity[:, :, 1].sum(dim=-1)
move_side = torch.where(left_gt_vel>right_gt_vel, torch.ones(left_gt_vel.shape).cuda(), torch.zeros(left_gt_vel.shape).cuda())
ys_gt_velocity = torch.mul(ys_gt_velocity[:, :, 0].transpose(0,1), move_side) + torch.mul(ys_gt_velocity[:, :, 1].transpose(0,1), ~move_side.bool())
ys_gt_velocity = ys_gt_velocity.transpose(0,1)
gt_velocity = torch.cat([ns_gt_velocity, ys_gt_velocity], dim=1)
pr_kps = pr_kps[:, :, rearrange]
ns_pr_kps = pr_kps[:, :, ~symmetry]
ys_pr_kps = pr_kps[:, :, symmetry]
ys_pr_kps = ys_pr_kps.reshape(ys_pr_kps.shape[0], ys_pr_kps.shape[1], -1, 2, 3)
ns_pr_velocity = (ns_pr_kps[:, 1:] - ns_pr_kps[:, :-1]).norm(p=2, dim=-1)
ys_pr_velocity = (ys_pr_kps[:, 1:] - ys_pr_kps[:, :-1]).norm(p=2, dim=-1)
left_pr_vel = ys_pr_velocity[:, :, :, 0].sum(dim=-1)
right_pr_vel = ys_pr_velocity[:, :, :, 1].sum(dim=-1)
move_side = torch.where(left_pr_vel > right_pr_vel, torch.ones(left_pr_vel.shape).cuda(),
torch.zeros(left_pr_vel.shape).cuda())
ys_pr_velocity = torch.mul(ys_pr_velocity[..., 0].permute(2, 0, 1), move_side) + torch.mul(
ys_pr_velocity[..., 1].permute(2, 0, 1), ~move_side.long())
ys_pr_velocity = ys_pr_velocity.permute(1, 2, 0)
pr_velocity = torch.cat([ns_pr_velocity, ys_pr_velocity], dim=2)
else:
gt_velocity = (gt_kps[1:] - gt_kps[:-1]).norm(p=2, dim=-1)
pr_velocity = (pr_kps[:, 1:] - pr_kps[:, :-1]).norm(p=2, dim=-1)
if weight:
w = F.softmax(gt_velocity.sum(dim=1).normal_(), dim=0)
else:
w = 1 / gt_velocity.shape[0]
v_diff = ((pr_velocity - gt_velocity).abs().sum(dim=-1) * w).sum(dim=-1).mean()
return v_diff
def LVD(gt_kps, pr_kps, symmetrical=False, weight=False):
gt_kps = gt_kps.squeeze()
pr_kps = pr_kps.squeeze()
if len(pr_kps.shape) == 4:
return Batch_LVD(gt_kps, pr_kps, symmetrical, weight)
# length = np.minimum(gt_kps.shape[0], pr_kps.shape[0])
length = gt_kps.shape[0]-10
# gt_kps = gt_kps[25:length]
# pr_kps = pr_kps[25:length] #(T, D)
# if pr_kps.shape[0] < gt_kps.shape[0]:
# pr_kps = np.pad(pr_kps, [[0, int(gt_kps.shape[0]-pr_kps.shape[0])], [0, 0]], mode='constant')
gt_velocity = (gt_kps[1:] - gt_kps[:-1]).norm(p=2, dim=-1)
pr_velocity = (pr_kps[1:] - pr_kps[:-1]).norm(p=2, dim=-1)
return (pr_velocity-gt_velocity).abs().sum(dim=-1).mean()
def diversity(kps):
'''
kps: bs, seq, dim
'''
dis_list = []
#the distance between each pair
for i in range(kps.shape[0]):
for j in range(i+1, kps.shape[0]):
seq_i = kps[i]
seq_j = kps[j]
dis = np.mean(np.abs(seq_i - seq_j))
dis_list.append(dis)
return np.mean(dis_list)