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import cv2 |
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import torch |
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import torch.nn as nn |
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import torch.nn.functional as F |
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import numpy as np |
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from PIL import Image |
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from iopaint.helper import load_model |
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from iopaint.plugins.base_plugin import BasePlugin |
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from iopaint.schema import RunPluginRequest |
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class REBNCONV(nn.Module): |
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def __init__(self, in_ch=3, out_ch=3, dirate=1, stride=1): |
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super(REBNCONV, self).__init__() |
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self.conv_s1 = nn.Conv2d( |
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in_ch, out_ch, 3, padding=1 * dirate, dilation=1 * dirate, stride=stride |
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) |
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self.bn_s1 = nn.BatchNorm2d(out_ch) |
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self.relu_s1 = nn.ReLU(inplace=True) |
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def forward(self, x): |
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hx = x |
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xout = self.relu_s1(self.bn_s1(self.conv_s1(hx))) |
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return xout |
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def _upsample_like(src, tar): |
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src = F.interpolate(src, size=tar.shape[2:], mode="bilinear", align_corners=False) |
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return src |
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class RSU7(nn.Module): |
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def __init__(self, in_ch=3, mid_ch=12, out_ch=3, img_size=512): |
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super(RSU7, self).__init__() |
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self.in_ch = in_ch |
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self.mid_ch = mid_ch |
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self.out_ch = out_ch |
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self.rebnconvin = REBNCONV(in_ch, out_ch, dirate=1) |
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self.rebnconv1 = REBNCONV(out_ch, mid_ch, dirate=1) |
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self.pool1 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv2 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool2 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv3 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool3 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv4 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool4 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv5 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool5 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv6 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.rebnconv7 = REBNCONV(mid_ch, mid_ch, dirate=2) |
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self.rebnconv6d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv5d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv4d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv3d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv2d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv1d = REBNCONV(mid_ch * 2, out_ch, dirate=1) |
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def forward(self, x): |
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b, c, h, w = x.shape |
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hx = x |
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hxin = self.rebnconvin(hx) |
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hx1 = self.rebnconv1(hxin) |
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hx = self.pool1(hx1) |
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hx2 = self.rebnconv2(hx) |
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hx = self.pool2(hx2) |
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hx3 = self.rebnconv3(hx) |
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hx = self.pool3(hx3) |
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hx4 = self.rebnconv4(hx) |
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hx = self.pool4(hx4) |
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hx5 = self.rebnconv5(hx) |
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hx = self.pool5(hx5) |
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hx6 = self.rebnconv6(hx) |
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hx7 = self.rebnconv7(hx6) |
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hx6d = self.rebnconv6d(torch.cat((hx7, hx6), 1)) |
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hx6dup = _upsample_like(hx6d, hx5) |
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hx5d = self.rebnconv5d(torch.cat((hx6dup, hx5), 1)) |
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hx5dup = _upsample_like(hx5d, hx4) |
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hx4d = self.rebnconv4d(torch.cat((hx5dup, hx4), 1)) |
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hx4dup = _upsample_like(hx4d, hx3) |
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hx3d = self.rebnconv3d(torch.cat((hx4dup, hx3), 1)) |
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hx3dup = _upsample_like(hx3d, hx2) |
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hx2d = self.rebnconv2d(torch.cat((hx3dup, hx2), 1)) |
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hx2dup = _upsample_like(hx2d, hx1) |
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hx1d = self.rebnconv1d(torch.cat((hx2dup, hx1), 1)) |
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return hx1d + hxin |
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class RSU6(nn.Module): |
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def __init__(self, in_ch=3, mid_ch=12, out_ch=3): |
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super(RSU6, self).__init__() |
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self.rebnconvin = REBNCONV(in_ch, out_ch, dirate=1) |
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self.rebnconv1 = REBNCONV(out_ch, mid_ch, dirate=1) |
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self.pool1 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv2 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool2 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv3 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool3 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv4 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool4 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv5 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.rebnconv6 = REBNCONV(mid_ch, mid_ch, dirate=2) |
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self.rebnconv5d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv4d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv3d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv2d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv1d = REBNCONV(mid_ch * 2, out_ch, dirate=1) |
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def forward(self, x): |
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hx = x |
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hxin = self.rebnconvin(hx) |
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hx1 = self.rebnconv1(hxin) |
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hx = self.pool1(hx1) |
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hx2 = self.rebnconv2(hx) |
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hx = self.pool2(hx2) |
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hx3 = self.rebnconv3(hx) |
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hx = self.pool3(hx3) |
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hx4 = self.rebnconv4(hx) |
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hx = self.pool4(hx4) |
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hx5 = self.rebnconv5(hx) |
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hx6 = self.rebnconv6(hx5) |
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hx5d = self.rebnconv5d(torch.cat((hx6, hx5), 1)) |
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hx5dup = _upsample_like(hx5d, hx4) |
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hx4d = self.rebnconv4d(torch.cat((hx5dup, hx4), 1)) |
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hx4dup = _upsample_like(hx4d, hx3) |
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hx3d = self.rebnconv3d(torch.cat((hx4dup, hx3), 1)) |
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hx3dup = _upsample_like(hx3d, hx2) |
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hx2d = self.rebnconv2d(torch.cat((hx3dup, hx2), 1)) |
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hx2dup = _upsample_like(hx2d, hx1) |
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hx1d = self.rebnconv1d(torch.cat((hx2dup, hx1), 1)) |
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return hx1d + hxin |
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class RSU5(nn.Module): |
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def __init__(self, in_ch=3, mid_ch=12, out_ch=3): |
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super(RSU5, self).__init__() |
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self.rebnconvin = REBNCONV(in_ch, out_ch, dirate=1) |
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self.rebnconv1 = REBNCONV(out_ch, mid_ch, dirate=1) |
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self.pool1 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv2 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool2 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv3 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool3 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv4 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.rebnconv5 = REBNCONV(mid_ch, mid_ch, dirate=2) |
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self.rebnconv4d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv3d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv2d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv1d = REBNCONV(mid_ch * 2, out_ch, dirate=1) |
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def forward(self, x): |
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hx = x |
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hxin = self.rebnconvin(hx) |
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hx1 = self.rebnconv1(hxin) |
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hx = self.pool1(hx1) |
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hx2 = self.rebnconv2(hx) |
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hx = self.pool2(hx2) |
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hx3 = self.rebnconv3(hx) |
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hx = self.pool3(hx3) |
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hx4 = self.rebnconv4(hx) |
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hx5 = self.rebnconv5(hx4) |
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hx4d = self.rebnconv4d(torch.cat((hx5, hx4), 1)) |
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hx4dup = _upsample_like(hx4d, hx3) |
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hx3d = self.rebnconv3d(torch.cat((hx4dup, hx3), 1)) |
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hx3dup = _upsample_like(hx3d, hx2) |
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hx2d = self.rebnconv2d(torch.cat((hx3dup, hx2), 1)) |
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hx2dup = _upsample_like(hx2d, hx1) |
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hx1d = self.rebnconv1d(torch.cat((hx2dup, hx1), 1)) |
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return hx1d + hxin |
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class RSU4(nn.Module): |
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def __init__(self, in_ch=3, mid_ch=12, out_ch=3): |
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super(RSU4, self).__init__() |
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self.rebnconvin = REBNCONV(in_ch, out_ch, dirate=1) |
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self.rebnconv1 = REBNCONV(out_ch, mid_ch, dirate=1) |
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self.pool1 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv2 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.pool2 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.rebnconv3 = REBNCONV(mid_ch, mid_ch, dirate=1) |
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self.rebnconv4 = REBNCONV(mid_ch, mid_ch, dirate=2) |
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self.rebnconv3d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv2d = REBNCONV(mid_ch * 2, mid_ch, dirate=1) |
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self.rebnconv1d = REBNCONV(mid_ch * 2, out_ch, dirate=1) |
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def forward(self, x): |
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hx = x |
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hxin = self.rebnconvin(hx) |
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hx1 = self.rebnconv1(hxin) |
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hx = self.pool1(hx1) |
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hx2 = self.rebnconv2(hx) |
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hx = self.pool2(hx2) |
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hx3 = self.rebnconv3(hx) |
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hx4 = self.rebnconv4(hx3) |
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hx3d = self.rebnconv3d(torch.cat((hx4, hx3), 1)) |
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hx3dup = _upsample_like(hx3d, hx2) |
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hx2d = self.rebnconv2d(torch.cat((hx3dup, hx2), 1)) |
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hx2dup = _upsample_like(hx2d, hx1) |
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hx1d = self.rebnconv1d(torch.cat((hx2dup, hx1), 1)) |
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return hx1d + hxin |
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class RSU4F(nn.Module): |
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def __init__(self, in_ch=3, mid_ch=12, out_ch=3): |
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super(RSU4F, self).__init__() |
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self.rebnconvin = REBNCONV(in_ch, out_ch, dirate=1) |
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self.rebnconv1 = REBNCONV(out_ch, mid_ch, dirate=1) |
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self.rebnconv2 = REBNCONV(mid_ch, mid_ch, dirate=2) |
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self.rebnconv3 = REBNCONV(mid_ch, mid_ch, dirate=4) |
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self.rebnconv4 = REBNCONV(mid_ch, mid_ch, dirate=8) |
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self.rebnconv3d = REBNCONV(mid_ch * 2, mid_ch, dirate=4) |
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self.rebnconv2d = REBNCONV(mid_ch * 2, mid_ch, dirate=2) |
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self.rebnconv1d = REBNCONV(mid_ch * 2, out_ch, dirate=1) |
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def forward(self, x): |
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hx = x |
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hxin = self.rebnconvin(hx) |
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hx1 = self.rebnconv1(hxin) |
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hx2 = self.rebnconv2(hx1) |
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hx3 = self.rebnconv3(hx2) |
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hx4 = self.rebnconv4(hx3) |
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hx3d = self.rebnconv3d(torch.cat((hx4, hx3), 1)) |
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hx2d = self.rebnconv2d(torch.cat((hx3d, hx2), 1)) |
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hx1d = self.rebnconv1d(torch.cat((hx2d, hx1), 1)) |
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return hx1d + hxin |
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class ISNetDIS(nn.Module): |
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def __init__(self, in_ch=3, out_ch=1): |
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super(ISNetDIS, self).__init__() |
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self.conv_in = nn.Conv2d(in_ch, 64, 3, stride=2, padding=1) |
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self.pool_in = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage1 = RSU7(64, 32, 64) |
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self.pool12 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage2 = RSU6(64, 32, 128) |
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self.pool23 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage3 = RSU5(128, 64, 256) |
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self.pool34 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage4 = RSU4(256, 128, 512) |
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self.pool45 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage5 = RSU4F(512, 256, 512) |
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self.pool56 = nn.MaxPool2d(2, stride=2, ceil_mode=True) |
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self.stage6 = RSU4F(512, 256, 512) |
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self.stage5d = RSU4F(1024, 256, 512) |
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self.stage4d = RSU4(1024, 128, 256) |
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self.stage3d = RSU5(512, 64, 128) |
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self.stage2d = RSU6(256, 32, 64) |
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self.stage1d = RSU7(128, 16, 64) |
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self.side1 = nn.Conv2d(64, out_ch, 3, padding=1) |
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def forward(self, x): |
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hx = x |
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hxin = self.conv_in(hx) |
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hx = self.pool_in(hxin) |
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hx1 = self.stage1(hxin) |
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hx = self.pool12(hx1) |
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hx2 = self.stage2(hx) |
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hx = self.pool23(hx2) |
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hx3 = self.stage3(hx) |
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hx = self.pool34(hx3) |
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hx4 = self.stage4(hx) |
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hx = self.pool45(hx4) |
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hx5 = self.stage5(hx) |
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hx = self.pool56(hx5) |
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hx6 = self.stage6(hx) |
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hx6up = _upsample_like(hx6, hx5) |
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hx5d = self.stage5d(torch.cat((hx6up, hx5), 1)) |
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hx5dup = _upsample_like(hx5d, hx4) |
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hx4d = self.stage4d(torch.cat((hx5dup, hx4), 1)) |
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hx4dup = _upsample_like(hx4d, hx3) |
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hx3d = self.stage3d(torch.cat((hx4dup, hx3), 1)) |
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hx3dup = _upsample_like(hx3d, hx2) |
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hx2d = self.stage2d(torch.cat((hx3dup, hx2), 1)) |
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hx2dup = _upsample_like(hx2d, hx1) |
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hx1d = self.stage1d(torch.cat((hx2dup, hx1), 1)) |
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d1 = self.side1(hx1d) |
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d1 = _upsample_like(d1, x) |
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return d1.sigmoid() |
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ANIME_SEG_MODELS = { |
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"url": "https://github.com/Sanster/models/releases/download/isnetis/isnetis.pth", |
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"md5": "5f25479076b73074730ab8de9e8f2051", |
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} |
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class AnimeSeg(BasePlugin): |
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name = "AnimeSeg" |
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support_gen_image = True |
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support_gen_mask = True |
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def __init__(self): |
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super().__init__() |
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self.model = load_model( |
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ISNetDIS(), |
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ANIME_SEG_MODELS["url"], |
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"cpu", |
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ANIME_SEG_MODELS["md5"], |
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) |
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def gen_image(self, rgb_np_img, req: RunPluginRequest) -> np.ndarray: |
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mask = self.forward(rgb_np_img) |
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mask = Image.fromarray(mask, mode="L") |
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h0, w0 = rgb_np_img.shape[0], rgb_np_img.shape[1] |
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empty = Image.new("RGBA", (w0, h0), 0) |
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img = Image.fromarray(rgb_np_img) |
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cutout = Image.composite(img, empty, mask) |
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return np.asarray(cutout) |
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def gen_mask(self, rgb_np_img, req: RunPluginRequest) -> np.ndarray: |
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return self.forward(rgb_np_img) |
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@torch.inference_mode() |
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def forward(self, rgb_np_img): |
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s = 1024 |
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h0, w0 = h, w = rgb_np_img.shape[0], rgb_np_img.shape[1] |
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if h > w: |
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h, w = s, int(s * w / h) |
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else: |
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h, w = int(s * h / w), s |
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ph, pw = s - h, s - w |
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tmpImg = np.zeros([s, s, 3], dtype=np.float32) |
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tmpImg[ph // 2 : ph // 2 + h, pw // 2 : pw // 2 + w] = ( |
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cv2.resize(rgb_np_img, (w, h)) / 255 |
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) |
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tmpImg = tmpImg.transpose((2, 0, 1)) |
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tmpImg = torch.from_numpy(tmpImg).unsqueeze(0).type(torch.FloatTensor) |
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mask = self.model(tmpImg) |
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mask = mask[0, :, ph // 2 : ph // 2 + h, pw // 2 : pw // 2 + w] |
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mask = cv2.resize(mask.cpu().numpy().transpose((1, 2, 0)), (w0, h0)) |
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return (mask * 255).astype("uint8") |
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