import torch import torch.nn.functional as F import numpy as np from .geom import gather_nd # input: [batch_size, C, H, W] # output: [batch_size, C, H, W], [batch_size, C, H, W] def peakiness_score(inputs, moving_instance_max, ksize=3, dilation=1): inputs = inputs / moving_instance_max batch_size, C, H, W = inputs.shape pad_size = ksize // 2 + (dilation - 1) kernel = torch.ones([C, 1, ksize, ksize], device=inputs.device) / (ksize * ksize) pad_inputs = F.pad(inputs, [pad_size] * 4, mode="reflect") avg_spatial_inputs = F.conv2d( pad_inputs, kernel, stride=1, dilation=dilation, padding=0, groups=C ) avg_channel_inputs = torch.mean( inputs, axis=1, keepdim=True ) # channel dimension is 1 alpha = F.softplus(inputs - avg_spatial_inputs) beta = F.softplus(inputs - avg_channel_inputs) return alpha, beta # input: score_map [batch_size, 1, H, W] # output: indices [2, k, 2], scores [2, k] def extract_kpts(score_map, k=256, score_thld=0, edge_thld=0, nms_size=3, eof_size=5): h = score_map.shape[2] w = score_map.shape[3] mask = score_map > score_thld if nms_size > 0: nms_mask = F.max_pool2d( score_map, kernel_size=nms_size, stride=1, padding=nms_size // 2 ) nms_mask = torch.eq(score_map, nms_mask) mask = torch.logical_and(nms_mask, mask) if eof_size > 0: eof_mask = torch.ones( (1, 1, h - 2 * eof_size, w - 2 * eof_size), dtype=torch.float32, device=score_map.device, ) eof_mask = F.pad(eof_mask, [eof_size] * 4, value=0) eof_mask = eof_mask.bool() mask = torch.logical_and(eof_mask, mask) if edge_thld > 0: non_edge_mask = edge_mask(score_map, 1, dilation=3, edge_thld=edge_thld) mask = torch.logical_and(non_edge_mask, mask) bs = score_map.shape[0] if bs is None: indices = torch.nonzero(mask)[0] scores = gather_nd(score_map, indices)[0] sample = torch.sort(scores, descending=True)[1][0:k] indices = indices[sample].unsqueeze(0) scores = scores[sample].unsqueeze(0) else: indices = [] scores = [] for i in range(bs): tmp_mask = mask[i][0] tmp_score_map = score_map[i][0] tmp_indices = torch.nonzero(tmp_mask) tmp_scores = gather_nd(tmp_score_map, tmp_indices) tmp_sample = torch.sort(tmp_scores, descending=True)[1][0:k] tmp_indices = tmp_indices[tmp_sample] tmp_scores = tmp_scores[tmp_sample] indices.append(tmp_indices) scores.append(tmp_scores) try: indices = torch.stack(indices, dim=0) scores = torch.stack(scores, dim=0) except: min_num = np.min([len(i) for i in indices]) indices = torch.stack([i[:min_num] for i in indices], dim=0) scores = torch.stack([i[:min_num] for i in scores], dim=0) return indices, scores def edge_mask(inputs, n_channel, dilation=1, edge_thld=5): b, c, h, w = inputs.size() device = inputs.device dii_filter = torch.tensor([[0, 1.0, 0], [0, -2.0, 0], [0, 1.0, 0]]).view(1, 1, 3, 3) dij_filter = 0.25 * torch.tensor( [[1.0, 0, -1.0], [0, 0.0, 0], [-1.0, 0, 1.0]] ).view(1, 1, 3, 3) djj_filter = torch.tensor([[0, 0, 0], [1.0, -2.0, 1.0], [0, 0, 0]]).view(1, 1, 3, 3) dii = F.conv2d( inputs.view(-1, 1, h, w), dii_filter.to(device), padding=dilation, dilation=dilation, ).view(b, c, h, w) dij = F.conv2d( inputs.view(-1, 1, h, w), dij_filter.to(device), padding=dilation, dilation=dilation, ).view(b, c, h, w) djj = F.conv2d( inputs.view(-1, 1, h, w), djj_filter.to(device), padding=dilation, dilation=dilation, ).view(b, c, h, w) det = dii * djj - dij * dij tr = dii + djj del dii, dij, djj threshold = (edge_thld + 1) ** 2 / edge_thld is_not_edge = torch.min(tr * tr / det <= threshold, det > 0) return is_not_edge