DL-Art-School/codes/models/archs/srflow_orig/FlowUpsamplerNet.py

import numpy as np
import torch
from torch import nn as nn

import models.modules.Split
from models.modules import flow, thops
from models.modules.Split import Split2d
from models.modules.glow_arch import f_conv2d_bias
from models.modules.FlowStep import FlowStep
from utils.util import opt_get


class FlowUpsamplerNet(nn.Module):
    def __init__(self, image_shape, hidden_channels, K, L=None,
                 actnorm_scale=1.0,
                 flow_permutation=None,
                 flow_coupling="affine",
                 LU_decomposed=False, opt=None):

        super().__init__()

        self.layers = nn.ModuleList()
        self.output_shapes = []
        self.L = opt_get(opt, ['network_G', 'flow', 'L'])
        self.K = opt_get(opt, ['network_G', 'flow', 'K'])
        if isinstance(self.K, int):
            self.K = [K for K in [K, ] * (self.L + 1)]

        self.opt = opt
        H, W, self.C = image_shape
        self.check_image_shape()

        if opt['scale'] == 16:
            self.levelToName = {
                0: 'fea_up16',
                1: 'fea_up8',
                2: 'fea_up4',
                3: 'fea_up2',
                4: 'fea_up1',
            }

        if opt['scale'] == 8:
            self.levelToName = {
                0: 'fea_up8',
                1: 'fea_up4',
                2: 'fea_up2',
                3: 'fea_up1',
                4: 'fea_up0'
            }

        elif opt['scale'] == 4:
            self.levelToName = {
                0: 'fea_up4',
                1: 'fea_up2',
                2: 'fea_up1',
                3: 'fea_up0',
                4: 'fea_up-1'
            }

        affineInCh = self.get_affineInCh(opt_get)
        flow_permutation = self.get_flow_permutation(flow_permutation, opt)

        normOpt = opt_get(opt, ['network_G', 'flow', 'norm'])

        conditional_channels = {}
        n_rrdb = self.get_n_rrdb_channels(opt, opt_get)
        n_bypass_channels = opt_get(opt, ['network_G', 'flow', 'levelConditional', 'n_channels'])
        conditional_channels[0] = n_rrdb
        for level in range(1, self.L + 1):
            # Level 1 gets conditionals from 2, 3, 4 => L - level
            # Level 2 gets conditionals from 3, 4
            # Level 3 gets conditionals from 4
            # Level 4 gets conditionals from None
            n_bypass = 0 if n_bypass_channels is None else (self.L - level) * n_bypass_channels
            conditional_channels[level] = n_rrdb + n_bypass

        # Upsampler
        for level in range(1, self.L + 1):
            # 1. Squeeze
            H, W = self.arch_squeeze(H, W)

            # 2. K FlowStep
            self.arch_additionalFlowAffine(H, LU_decomposed, W, actnorm_scale, hidden_channels, opt)
            self.arch_FlowStep(H, self.K[level], LU_decomposed, W, actnorm_scale, affineInCh, flow_coupling,
                               flow_permutation,
                               hidden_channels, normOpt, opt, opt_get,
                               n_conditinal_channels=conditional_channels[level])
            # Split
            self.arch_split(H, W, level, self.L, opt, opt_get)

        if opt_get(opt, ['network_G', 'flow', 'split', 'enable']):
            self.f = f_conv2d_bias(affineInCh, 2 * 3 * 64 // 2 // 2)
        else:
            self.f = f_conv2d_bias(affineInCh, 2 * 3 * 64)

        self.H = H
        self.W = W
        self.scaleH = 160 / H
        self.scaleW = 160 / W

    def get_n_rrdb_channels(self, opt, opt_get):
        blocks = opt_get(opt, ['network_G', 'flow', 'stackRRDB', 'blocks'])
        n_rrdb = 64 if blocks is None else (len(blocks) + 1) * 64
        return n_rrdb

    def arch_FlowStep(self, H, K, LU_decomposed, W, actnorm_scale, affineInCh, flow_coupling, flow_permutation,
                      hidden_channels, normOpt, opt, opt_get, n_conditinal_channels=None):
        condAff = self.get_condAffSetting(opt, opt_get)
        if condAff is not None:
            condAff['in_channels_rrdb'] = n_conditinal_channels

        for k in range(K):
            position_name = get_position_name(H, self.opt['scale'])
            if normOpt: normOpt['position'] = position_name

            self.layers.append(
                FlowStep(in_channels=self.C,
                         hidden_channels=hidden_channels,
                         actnorm_scale=actnorm_scale,
                         flow_permutation=flow_permutation,
                         flow_coupling=flow_coupling,
                         acOpt=condAff,
                         position=position_name,
                         LU_decomposed=LU_decomposed, opt=opt, idx=k, normOpt=normOpt))
            self.output_shapes.append(
                [-1, self.C, H, W])

    def get_condAffSetting(self, opt, opt_get):
        condAff = opt_get(opt, ['network_G', 'flow', 'condAff']) or None
        condAff = opt_get(opt, ['network_G', 'flow', 'condFtAffine']) or condAff
        return condAff

    def arch_split(self, H, W, L, levels, opt, opt_get):
        correct_splits = opt_get(opt, ['network_G', 'flow', 'split', 'correct_splits'], False)
        correction = 0 if correct_splits else 1
        if opt_get(opt, ['network_G', 'flow', 'split', 'enable']) and L < levels - correction:
            logs_eps = opt_get(opt, ['network_G', 'flow', 'split', 'logs_eps']) or 0
            consume_ratio = opt_get(opt, ['network_G', 'flow', 'split', 'consume_ratio']) or 0.5
            position_name = get_position_name(H, self.opt['scale'])
            position = position_name if opt_get(opt, ['network_G', 'flow', 'split', 'conditional']) else None
            cond_channels = opt_get(opt, ['network_G', 'flow', 'split', 'cond_channels'])
            cond_channels = 0 if cond_channels is None else cond_channels

            t = opt_get(opt, ['network_G', 'flow', 'split', 'type'], 'Split2d')

            if t == 'Split2d':
                split = models.modules.Split.Split2d(num_channels=self.C, logs_eps=logs_eps, position=position,
                                                     cond_channels=cond_channels, consume_ratio=consume_ratio, opt=opt)
            self.layers.append(split)
            self.output_shapes.append([-1, split.num_channels_pass, H, W])
            self.C = split.num_channels_pass

    def arch_additionalFlowAffine(self, H, LU_decomposed, W, actnorm_scale, hidden_channels, opt):
        if 'additionalFlowNoAffine' in opt['network_G']['flow']:
            n_additionalFlowNoAffine = int(opt['network_G']['flow']['additionalFlowNoAffine'])
            for _ in range(n_additionalFlowNoAffine):
                self.layers.append(
                    FlowStep(in_channels=self.C,
                             hidden_channels=hidden_channels,
                             actnorm_scale=actnorm_scale,
                             flow_permutation='invconv',
                             flow_coupling='noCoupling',
                             LU_decomposed=LU_decomposed, opt=opt))
                self.output_shapes.append(
                    [-1, self.C, H, W])

    def arch_squeeze(self, H, W):
        self.C, H, W = self.C * 4, H // 2, W // 2
        self.layers.append(flow.SqueezeLayer(factor=2))
        self.output_shapes.append([-1, self.C, H, W])
        return H, W

    def get_flow_permutation(self, flow_permutation, opt):
        flow_permutation = opt['network_G']['flow'].get('flow_permutation', 'invconv')
        return flow_permutation

    def get_affineInCh(self, opt_get):
        affineInCh = opt_get(self.opt, ['network_G', 'flow', 'stackRRDB', 'blocks']) or []
        affineInCh = (len(affineInCh) + 1) * 64
        return affineInCh

    def check_image_shape(self):
        assert self.C == 1 or self.C == 3, ("image_shape should be HWC, like (64, 64, 3)"
                                            "self.C == 1 or self.C == 3")

    def forward(self, gt=None, rrdbResults=None, z=None, epses=None, logdet=0., reverse=False, eps_std=None,
                y_onehot=None):

        if reverse:
            epses_copy = [eps for eps in epses] if isinstance(epses, list) else epses

            sr, logdet = self.decode(rrdbResults, z, eps_std, epses=epses_copy, logdet=logdet, y_onehot=y_onehot)
            return sr, logdet
        else:
            assert gt is not None
            assert rrdbResults is not None
            z, logdet = self.encode(gt, rrdbResults, logdet=logdet, epses=epses, y_onehot=y_onehot)

            return z, logdet

    def encode(self, gt, rrdbResults, logdet=0.0, epses=None, y_onehot=None):
        fl_fea = gt
        reverse = False
        level_conditionals = {}
        bypasses = {}

        L = opt_get(self.opt, ['network_G', 'flow', 'L'])

        for level in range(1, L + 1):
            bypasses[level] = torch.nn.functional.interpolate(gt, scale_factor=2 ** -level, mode='bilinear', align_corners=False)

        for layer, shape in zip(self.layers, self.output_shapes):
            size = shape[2]
            level = int(np.log(160 / size) / np.log(2))

            if level > 0 and level not in level_conditionals.keys():
                level_conditionals[level] = rrdbResults[self.levelToName[level]]

            level_conditionals[level] = rrdbResults[self.levelToName[level]]

            if isinstance(layer, FlowStep):
                fl_fea, logdet = layer(fl_fea, logdet, reverse=reverse, rrdbResults=level_conditionals[level])
            elif isinstance(layer, Split2d):
                fl_fea, logdet = self.forward_split2d(epses, fl_fea, layer, logdet, reverse, level_conditionals[level],
                                                      y_onehot=y_onehot)
            else:
                fl_fea, logdet = layer(fl_fea, logdet, reverse=reverse)

        z = fl_fea

        if not isinstance(epses, list):
            return z, logdet

        epses.append(z)
        return epses, logdet

    def forward_preFlow(self, fl_fea, logdet, reverse):
        if hasattr(self, 'preFlow'):
            for l in self.preFlow:
                fl_fea, logdet = l(fl_fea, logdet, reverse=reverse)
        return fl_fea, logdet

    def forward_split2d(self, epses, fl_fea, layer, logdet, reverse, rrdbResults, y_onehot=None):
        ft = None if layer.position is None else rrdbResults[layer.position]
        fl_fea, logdet, eps = layer(fl_fea, logdet, reverse=reverse, eps=epses, ft=ft, y_onehot=y_onehot)

        if isinstance(epses, list):
            epses.append(eps)
        return fl_fea, logdet

    def decode(self, rrdbResults, z, eps_std=None, epses=None, logdet=0.0, y_onehot=None):
        z = epses.pop() if isinstance(epses, list) else z

        fl_fea = z
        # debug.imwrite("fl_fea", fl_fea)
        bypasses = {}
        level_conditionals = {}
        if not opt_get(self.opt, ['network_G', 'flow', 'levelConditional', 'conditional']) == True:
            for level in range(self.L + 1):
                level_conditionals[level] = rrdbResults[self.levelToName[level]]

        for layer, shape in zip(reversed(self.layers), reversed(self.output_shapes)):
            size = shape[2]
            level = int(np.log(160 / size) / np.log(2))
            # size = fl_fea.shape[2]
            # level = int(np.log(160 / size) / np.log(2))

            if isinstance(layer, Split2d):
                fl_fea, logdet = self.forward_split2d_reverse(eps_std, epses, fl_fea, layer,
                                                              rrdbResults[self.levelToName[level]], logdet=logdet,
                                                              y_onehot=y_onehot)
            elif isinstance(layer, FlowStep):
                fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True, rrdbResults=level_conditionals[level])
            else:
                fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True)

        sr = fl_fea

        assert sr.shape[1] == 3
        return sr, logdet

    def forward_split2d_reverse(self, eps_std, epses, fl_fea, layer, rrdbResults, logdet, y_onehot=None):
        ft = None if layer.position is None else rrdbResults[layer.position]
        fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True,
                               eps=epses.pop() if isinstance(epses, list) else None,
                               eps_std=eps_std, ft=ft, y_onehot=y_onehot)
        return fl_fea, logdet


def get_position_name(H, scale):
    downscale_factor = 160 // H
    position_name = 'fea_up{}'.format(scale / downscale_factor)
    return position_name
Bring in an original SRFlow implementation for reference 2020-11-20 04:42:39 +00:00			`import numpy as np`
			`import torch`
			`from torch import nn as nn`

			`import models.modules.Split`
			`from models.modules import flow, thops`
			`from models.modules.Split import Split2d`
			`from models.modules.glow_arch import f_conv2d_bias`
			`from models.modules.FlowStep import FlowStep`
			`from utils.util import opt_get`


			`class FlowUpsamplerNet(nn.Module):`
			`def __init__(self, image_shape, hidden_channels, K, L=None,`
			`actnorm_scale=1.0,`
			`flow_permutation=None,`
			`flow_coupling="affine",`
			`LU_decomposed=False, opt=None):`

			`super().__init__()`

			`self.layers = nn.ModuleList()`
			`self.output_shapes = []`
			`self.L = opt_get(opt, ['network_G', 'flow', 'L'])`
			`self.K = opt_get(opt, ['network_G', 'flow', 'K'])`
			`if isinstance(self.K, int):`
			`self.K = [K for K in [K, ] * (self.L + 1)]`

			`self.opt = opt`
			`H, W, self.C = image_shape`
			`self.check_image_shape()`

			`if opt['scale'] == 16:`
			`self.levelToName = {`
			`0: 'fea_up16',`
			`1: 'fea_up8',`
			`2: 'fea_up4',`
			`3: 'fea_up2',`
			`4: 'fea_up1',`
			`}`

			`if opt['scale'] == 8:`
			`self.levelToName = {`
			`0: 'fea_up8',`
			`1: 'fea_up4',`
			`2: 'fea_up2',`
			`3: 'fea_up1',`
			`4: 'fea_up0'`
			`}`

			`elif opt['scale'] == 4:`
			`self.levelToName = {`
			`0: 'fea_up4',`
			`1: 'fea_up2',`
			`2: 'fea_up1',`
			`3: 'fea_up0',`
			`4: 'fea_up-1'`
			`}`

			`affineInCh = self.get_affineInCh(opt_get)`
			`flow_permutation = self.get_flow_permutation(flow_permutation, opt)`

			`normOpt = opt_get(opt, ['network_G', 'flow', 'norm'])`

			`conditional_channels = {}`
			`n_rrdb = self.get_n_rrdb_channels(opt, opt_get)`
			`n_bypass_channels = opt_get(opt, ['network_G', 'flow', 'levelConditional', 'n_channels'])`
			`conditional_channels[0] = n_rrdb`
			`for level in range(1, self.L + 1):`
			`# Level 1 gets conditionals from 2, 3, 4 => L - level`
			`# Level 2 gets conditionals from 3, 4`
			`# Level 3 gets conditionals from 4`
			`# Level 4 gets conditionals from None`
			`n_bypass = 0 if n_bypass_channels is None else (self.L - level) * n_bypass_channels`
			`conditional_channels[level] = n_rrdb + n_bypass`

			`# Upsampler`
			`for level in range(1, self.L + 1):`
			`# 1. Squeeze`
			`H, W = self.arch_squeeze(H, W)`

			`# 2. K FlowStep`
			`self.arch_additionalFlowAffine(H, LU_decomposed, W, actnorm_scale, hidden_channels, opt)`
			`self.arch_FlowStep(H, self.K[level], LU_decomposed, W, actnorm_scale, affineInCh, flow_coupling,`
			`flow_permutation,`
			`hidden_channels, normOpt, opt, opt_get,`
			`n_conditinal_channels=conditional_channels[level])`
			`# Split`
			`self.arch_split(H, W, level, self.L, opt, opt_get)`

			`if opt_get(opt, ['network_G', 'flow', 'split', 'enable']):`
			`self.f = f_conv2d_bias(affineInCh, 2 * 3 * 64 // 2 // 2)`
			`else:`
			`self.f = f_conv2d_bias(affineInCh, 2 * 3 * 64)`

			`self.H = H`
			`self.W = W`
			`self.scaleH = 160 / H`
			`self.scaleW = 160 / W`

			`def get_n_rrdb_channels(self, opt, opt_get):`
			`blocks = opt_get(opt, ['network_G', 'flow', 'stackRRDB', 'blocks'])`
			`n_rrdb = 64 if blocks is None else (len(blocks) + 1) * 64`
			`return n_rrdb`

			`def arch_FlowStep(self, H, K, LU_decomposed, W, actnorm_scale, affineInCh, flow_coupling, flow_permutation,`
			`hidden_channels, normOpt, opt, opt_get, n_conditinal_channels=None):`
			`condAff = self.get_condAffSetting(opt, opt_get)`
			`if condAff is not None:`
			`condAff['in_channels_rrdb'] = n_conditinal_channels`

			`for k in range(K):`
			`position_name = get_position_name(H, self.opt['scale'])`
			`if normOpt: normOpt['position'] = position_name`

			`self.layers.append(`
			`FlowStep(in_channels=self.C,`
			`hidden_channels=hidden_channels,`
			`actnorm_scale=actnorm_scale,`
			`flow_permutation=flow_permutation,`
			`flow_coupling=flow_coupling,`
			`acOpt=condAff,`
			`position=position_name,`
			`LU_decomposed=LU_decomposed, opt=opt, idx=k, normOpt=normOpt))`
			`self.output_shapes.append(`
			`[-1, self.C, H, W])`

			`def get_condAffSetting(self, opt, opt_get):`
			`condAff = opt_get(opt, ['network_G', 'flow', 'condAff']) or None`
			`condAff = opt_get(opt, ['network_G', 'flow', 'condFtAffine']) or condAff`
			`return condAff`

			`def arch_split(self, H, W, L, levels, opt, opt_get):`
			`correct_splits = opt_get(opt, ['network_G', 'flow', 'split', 'correct_splits'], False)`
			`correction = 0 if correct_splits else 1`
			`if opt_get(opt, ['network_G', 'flow', 'split', 'enable']) and L < levels - correction:`
			`logs_eps = opt_get(opt, ['network_G', 'flow', 'split', 'logs_eps']) or 0`
			`consume_ratio = opt_get(opt, ['network_G', 'flow', 'split', 'consume_ratio']) or 0.5`
			`position_name = get_position_name(H, self.opt['scale'])`
			`position = position_name if opt_get(opt, ['network_G', 'flow', 'split', 'conditional']) else None`
			`cond_channels = opt_get(opt, ['network_G', 'flow', 'split', 'cond_channels'])`
			`cond_channels = 0 if cond_channels is None else cond_channels`

			`t = opt_get(opt, ['network_G', 'flow', 'split', 'type'], 'Split2d')`

			`if t == 'Split2d':`
			`split = models.modules.Split.Split2d(num_channels=self.C, logs_eps=logs_eps, position=position,`
			`cond_channels=cond_channels, consume_ratio=consume_ratio, opt=opt)`
			`self.layers.append(split)`
			`self.output_shapes.append([-1, split.num_channels_pass, H, W])`
			`self.C = split.num_channels_pass`

			`def arch_additionalFlowAffine(self, H, LU_decomposed, W, actnorm_scale, hidden_channels, opt):`
			`if 'additionalFlowNoAffine' in opt['network_G']['flow']:`
			`n_additionalFlowNoAffine = int(opt['network_G']['flow']['additionalFlowNoAffine'])`
			`for _ in range(n_additionalFlowNoAffine):`
			`self.layers.append(`
			`FlowStep(in_channels=self.C,`
			`hidden_channels=hidden_channels,`
			`actnorm_scale=actnorm_scale,`
			`flow_permutation='invconv',`
			`flow_coupling='noCoupling',`
			`LU_decomposed=LU_decomposed, opt=opt))`
			`self.output_shapes.append(`
			`[-1, self.C, H, W])`

			`def arch_squeeze(self, H, W):`
			`self.C, H, W = self.C * 4, H // 2, W // 2`
			`self.layers.append(flow.SqueezeLayer(factor=2))`
			`self.output_shapes.append([-1, self.C, H, W])`
			`return H, W`

			`def get_flow_permutation(self, flow_permutation, opt):`
			`flow_permutation = opt['network_G']['flow'].get('flow_permutation', 'invconv')`
			`return flow_permutation`

			`def get_affineInCh(self, opt_get):`
			`affineInCh = opt_get(self.opt, ['network_G', 'flow', 'stackRRDB', 'blocks']) or []`
			`affineInCh = (len(affineInCh) + 1) * 64`
			`return affineInCh`

			`def check_image_shape(self):`
			`assert self.C == 1 or self.C == 3, ("image_shape should be HWC, like (64, 64, 3)"`
			`"self.C == 1 or self.C == 3")`

			`def forward(self, gt=None, rrdbResults=None, z=None, epses=None, logdet=0., reverse=False, eps_std=None,`
			`y_onehot=None):`

			`if reverse:`
			`epses_copy = [eps for eps in epses] if isinstance(epses, list) else epses`

			`sr, logdet = self.decode(rrdbResults, z, eps_std, epses=epses_copy, logdet=logdet, y_onehot=y_onehot)`
			`return sr, logdet`
			`else:`
			`assert gt is not None`
			`assert rrdbResults is not None`
			`z, logdet = self.encode(gt, rrdbResults, logdet=logdet, epses=epses, y_onehot=y_onehot)`

			`return z, logdet`

			`def encode(self, gt, rrdbResults, logdet=0.0, epses=None, y_onehot=None):`
			`fl_fea = gt`
			`reverse = False`
			`level_conditionals = {}`
			`bypasses = {}`

			`L = opt_get(self.opt, ['network_G', 'flow', 'L'])`

			`for level in range(1, L + 1):`
			`bypasses[level] = torch.nn.functional.interpolate(gt, scale_factor=2 ** -level, mode='bilinear', align_corners=False)`

			`for layer, shape in zip(self.layers, self.output_shapes):`
			`size = shape[2]`
			`level = int(np.log(160 / size) / np.log(2))`

			`if level > 0 and level not in level_conditionals.keys():`
			`level_conditionals[level] = rrdbResults[self.levelToName[level]]`

			`level_conditionals[level] = rrdbResults[self.levelToName[level]]`

			`if isinstance(layer, FlowStep):`
			`fl_fea, logdet = layer(fl_fea, logdet, reverse=reverse, rrdbResults=level_conditionals[level])`
			`elif isinstance(layer, Split2d):`
			`fl_fea, logdet = self.forward_split2d(epses, fl_fea, layer, logdet, reverse, level_conditionals[level],`
			`y_onehot=y_onehot)`
			`else:`
			`fl_fea, logdet = layer(fl_fea, logdet, reverse=reverse)`

			`z = fl_fea`

			`if not isinstance(epses, list):`
			`return z, logdet`

			`epses.append(z)`
			`return epses, logdet`

			`def forward_preFlow(self, fl_fea, logdet, reverse):`
			`if hasattr(self, 'preFlow'):`
			`for l in self.preFlow:`
			`fl_fea, logdet = l(fl_fea, logdet, reverse=reverse)`
			`return fl_fea, logdet`

			`def forward_split2d(self, epses, fl_fea, layer, logdet, reverse, rrdbResults, y_onehot=None):`
			`ft = None if layer.position is None else rrdbResults[layer.position]`
			`fl_fea, logdet, eps = layer(fl_fea, logdet, reverse=reverse, eps=epses, ft=ft, y_onehot=y_onehot)`

			`if isinstance(epses, list):`
			`epses.append(eps)`
			`return fl_fea, logdet`

			`def decode(self, rrdbResults, z, eps_std=None, epses=None, logdet=0.0, y_onehot=None):`
			`z = epses.pop() if isinstance(epses, list) else z`

			`fl_fea = z`
			`# debug.imwrite("fl_fea", fl_fea)`
			`bypasses = {}`
			`level_conditionals = {}`
			`if not opt_get(self.opt, ['network_G', 'flow', 'levelConditional', 'conditional']) == True:`
			`for level in range(self.L + 1):`
			`level_conditionals[level] = rrdbResults[self.levelToName[level]]`

			`for layer, shape in zip(reversed(self.layers), reversed(self.output_shapes)):`
			`size = shape[2]`
			`level = int(np.log(160 / size) / np.log(2))`
			`# size = fl_fea.shape[2]`
			`# level = int(np.log(160 / size) / np.log(2))`

			`if isinstance(layer, Split2d):`
			`fl_fea, logdet = self.forward_split2d_reverse(eps_std, epses, fl_fea, layer,`
			`rrdbResults[self.levelToName[level]], logdet=logdet,`
			`y_onehot=y_onehot)`
			`elif isinstance(layer, FlowStep):`
			`fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True, rrdbResults=level_conditionals[level])`
			`else:`
			`fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True)`

			`sr = fl_fea`

			`assert sr.shape[1] == 3`
			`return sr, logdet`

			`def forward_split2d_reverse(self, eps_std, epses, fl_fea, layer, rrdbResults, logdet, y_onehot=None):`
			`ft = None if layer.position is None else rrdbResults[layer.position]`
			`fl_fea, logdet = layer(fl_fea, logdet=logdet, reverse=True,`
			`eps=epses.pop() if isinstance(epses, list) else None,`
			`eps_std=eps_std, ft=ft, y_onehot=y_onehot)`
			`return fl_fea, logdet`


			`def get_position_name(H, scale):`
			`downscale_factor = 160 // H`
			`position_name = 'fea_up{}'.format(scale / downscale_factor)`
			`return position_name`