stylegan_models.py

import torch
import torch.nn as nn
import torch.nn.functional as F

import numpy as np
from collections import OrderedDict


class MyLinear(nn.Module):
    """Linear layer with equalized learning rate and custom learning rate multiplier."""
    def __init__(self, input_size, output_size, gain=2**(0.5), use_wscale=False, lrmul=1, bias=True):
        super().__init__()
        he_std = gain * input_size**(-0.5) # He init
        # Equalized learning rate and custom learning rate multiplier.
        if use_wscale:
            init_std = 1.0 / lrmul
            self.w_mul = he_std * lrmul
        else:
            init_std = he_std / lrmul
            self.w_mul = lrmul
        self.weight = torch.nn.Parameter(torch.randn(output_size, input_size) * init_std)
        if bias:
            self.bias = torch.nn.Parameter(torch.zeros(output_size))
            self.b_mul = lrmul
        else:
            self.bias = None

    def forward(self, x):
        bias = self.bias
        if bias is not None:
            bias = bias * self.b_mul
        return F.linear(x, self.weight * self.w_mul, bias)



class MyConv2d(nn.Module):
    """Conv layer with equalized learning rate and custom learning rate multiplier."""
    def __init__(self, input_channels, output_channels, kernel_size, gain=2**(0.5), use_wscale=False, lrmul=1, bias=True,
                intermediate=None, upscale=False):
        super().__init__()
        if upscale:
            self.upscale = Upscale2d()
        else:
            self.upscale = None
        he_std = gain * (input_channels * kernel_size ** 2) ** (-0.5) # He init
        self.kernel_size = kernel_size
        if use_wscale:
            init_std = 1.0 / lrmul
            self.w_mul = he_std * lrmul
        else:
            init_std = he_std / lrmul
            self.w_mul = lrmul
        self.weight = torch.nn.Parameter(torch.randn(output_channels, input_channels, kernel_size, kernel_size) * init_std)
        if bias:
            self.bias = torch.nn.Parameter(torch.zeros(output_channels))
            self.b_mul = lrmul
        else:
            self.bias = None
        self.intermediate = intermediate

    def forward(self, x):
        bias = self.bias
        if bias is not None:
            bias = bias * self.b_mul
        
        have_convolution = False
        if self.upscale is not None and min(x.shape[2:]) * 2 >= 128:
            # this is the fused upscale + conv from StyleGAN, sadly this seems incompatible with the non-fused way
            # this really needs to be cleaned up and go into the conv...
            w = self.weight * self.w_mul
            w = w.permute(1, 0, 2, 3)
            # probably applying a conv on w would be more efficient. also this quadruples the weight (average)?!
            w = F.pad(w, (1,1,1,1))
            w = w[:, :, 1:, 1:]+ w[:, :, :-1, 1:] + w[:, :, 1:, :-1] + w[:, :, :-1, :-1]
            x = F.conv_transpose2d(x, w, stride=2, padding=(w.size(-1)-1)//2)
            have_convolution = True
        elif self.upscale is not None:
            x = self.upscale(x)
    
        if not have_convolution and self.intermediate is None:
            return F.conv2d(x, self.weight * self.w_mul, bias, padding=self.kernel_size//2)
        elif not have_convolution:
            x = F.conv2d(x, self.weight * self.w_mul, None, padding=self.kernel_size//2)
        
        if self.intermediate is not None:
            x = self.intermediate(x)
        if bias is not None:
            x = x + bias.view(1, -1, 1, 1)
        return x


class NoiseLayer(nn.Module):
    """adds noise. noise is per pixel (constant over channels) with per-channel weight"""
    def __init__(self, channels):
        super().__init__()
        self.weight = nn.Parameter(torch.zeros(channels))
        self.noise = None
    
    def forward(self, x, noise=None):
        if noise is None and self.noise is None:
            noise = torch.randn(x.size(0), 1, x.size(2), x.size(3), device=x.device, dtype=x.dtype)
        elif noise is None:
            # here is a little trick: if you get all the noiselayers and set each
            # modules .noise attribute, you can have pre-defined noise.
            # Very useful for analysis
            noise = self.noise
        x = x + self.weight.view(1, -1, 1, 1) * noise
        return x  


class StyleMod(nn.Module):
    def __init__(self, latent_size, channels, use_wscale):
        super(StyleMod, self).__init__()
        self.lin = MyLinear(latent_size,
                            channels * 2,
                            gain=1.0, use_wscale=use_wscale)
        
    def forward(self, x, latent):
        style = self.lin(latent) # style => [batch_size, n_channels*2]
        shape = [-1, 2, x.size(1)] + (x.dim() - 2) * [1]
        style = style.view(shape)  # [batch_size, 2, n_channels, ...]
        x = x * (style[:, 0] + 1.) + style[:, 1]
        return x


class PixelNormLayer(nn.Module):
    """ This layer ensures that the input vector have std = 1:
        - std = 1/N * sqrt(x-mean(x))
        - In this case x comes from a normal centred in 0 so mean(x) = 0
        - Dividing the value of std(x) to x makes the normal of x become 1:
            + If the std == 1 it remains the same
            + If the std > 1 it decrease the values of x which in consequence reduce the std
            + If the std < 1 it increase the values of x which in consequence increase the std
    """
    def __init__(self, epsilon=1e-8):
        super().__init__()
        self.epsilon = epsilon
    def forward(self, x):
        return x * torch.rsqrt(torch.mean(x**2, dim=1, keepdim=True) + self.epsilon)


class BlurLayer(nn.Module):
    def __init__(self, kernel=[1, 2, 1], normalize=True, flip=False, stride=1):
        super(BlurLayer, self).__init__()
        kernel=[1, 2, 1]
        kernel = torch.tensor(kernel, dtype=torch.float32)
        kernel = kernel[:, None] * kernel[None, :]
        kernel = kernel[None, None]
        if normalize:
            kernel = kernel / kernel.sum()
        if flip:
            kernel = kernel[:, :, ::-1, ::-1]
        self.register_buffer('kernel', kernel)
        self.stride = stride
    
    def forward(self, x):
        # expand kernel channels
        kernel = self.kernel.expand(x.size(1), -1, -1, -1)
        x = F.conv2d(
            x,
            kernel,
            stride=self.stride,
            padding=int((self.kernel.size(2)-1)/2),
            groups=x.size(1)
        )
        return x


def upscale2d(x, factor=2, gain=1):
    assert x.dim() == 4
    if gain != 1:
        x = x * gain
    if factor != 1:
        shape = x.shape
        x = x.view(shape[0], shape[1], shape[2], 1, shape[3], 1).expand(-1, -1, -1, factor, -1, factor)
        x = x.contiguous().view(shape[0], shape[1], factor * shape[2], factor * shape[3])
    return x


class Upscale2d(nn.Module):
    def __init__(self, factor=2, gain=1):
        super().__init__()
        assert isinstance(factor, int) and factor >= 1
        self.gain = gain
        self.factor = factor
    def forward(self, x):
        return upscale2d(x, factor=self.factor, gain=self.gain)


class G_mapping(nn.Sequential):
    def __init__(self, nonlinearity='lrelu', use_wscale=True):
        act, gain = {'relu': (torch.relu, np.sqrt(2)),
                     'lrelu': (nn.LeakyReLU(negative_slope=0.2), np.sqrt(2))}[nonlinearity]
        layers = [
            ('pixel_norm', PixelNormLayer()),
            ('dense0', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense0_act', act),
            ('dense1', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense1_act', act),
            ('dense2', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense2_act', act),
            ('dense3', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense3_act', act),
            ('dense4', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense4_act', act),
            ('dense5', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense5_act', act),
            ('dense6', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense6_act', act),
            ('dense7', MyLinear(512, 512, gain=gain, lrmul=0.01, use_wscale=use_wscale)),
            ('dense7_act', act)
        ]
        super().__init__(OrderedDict(layers))
        
    def forward(self, x):
        x = super().forward(x)
        # Broadcast
        x = x.expand(-1, 18, -1)
        return x


class Truncation(nn.Module):
    def __init__(self, avg_latent, max_layer=8, threshold=0.7):
        super().__init__()
        self.max_layer = max_layer
        self.threshold = threshold
        self.register_buffer('avg_latent', avg_latent) # parameter of the module which is not trainable and is not passed to the optimizer when calling parameters() function
    def forward(self, x):
        assert x.dim() == 3
        interp = torch.lerp(self.avg_latent, x, self.threshold)
        do_trunc = (torch.arange(x.size(1)) < self.max_layer).view(1, -1, 1)
        return torch.where(do_trunc, interp, x)


class LayerEpilogue(nn.Module):
    """Things to do at the end of each layer."""
    def __init__(self, channels, dlatent_size, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer):
        super().__init__()
        layers = []
        if use_noise:
            layers.append(('noise', NoiseLayer(channels)))
        layers.append(('activation', activation_layer))
        if use_pixel_norm:
            layers.append(('pixel_norm', PixelNormLayer()))
        if use_instance_norm:
            layers.append(('instance_norm', nn.InstanceNorm2d(channels)))
        self.top_epi = nn.Sequential(OrderedDict(layers))
        if use_styles:
            self.style_mod = StyleMod(dlatent_size, channels, use_wscale=use_wscale)
        else:
            self.style_mod = None
    def forward(self, x, dlatents_in_slice=None):
        x = self.top_epi(x)
        if self.style_mod is not None:
            x = self.style_mod(x, dlatents_in_slice)
        else:
            assert dlatents_in_slice is None
        return x


class InputBlock(nn.Module):
    def __init__(self, nf, dlatent_size, const_input_layer, gain, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer):
        super().__init__()
        self.const_input_layer = const_input_layer
        self.nf = nf
        if self.const_input_layer:
            # called 'const' in tf
            self.const = nn.Parameter(torch.ones(1, nf, 4, 4))
            self.bias = nn.Parameter(torch.ones(nf))
        else:
            self.dense = MyLinear(dlatent_size, nf*16, gain=gain/4, use_wscale=use_wscale) # tweak gain to match the official implementation of Progressing GAN
        self.epi1 = LayerEpilogue(nf, dlatent_size, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer)
        self.conv = MyConv2d(nf, nf, 3, gain=gain, use_wscale=use_wscale)
        self.epi2 = LayerEpilogue(nf, dlatent_size, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer)
        
    def forward(self, dlatents_in_range):
        batch_size = dlatents_in_range.size(0)
        if self.const_input_layer:
            x = self.const.expand(batch_size, -1, -1, -1)
            x = x + self.bias.view(1, -1, 1, 1)
        else:
            x = self.dense(dlatents_in_range[:, 0]).view(batch_size, self.nf, 4, 4)
        x = self.epi1(x, dlatents_in_range[:, 0])
        x = self.conv(x)
        x = self.epi2(x, dlatents_in_range[:, 1])
        return x



class GSynthesisBlock(nn.Module):
    def __init__(self, in_channels, out_channels, blur_filter, dlatent_size, gain, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer):
        # 2**res x 2**res # res = 3..resolution_log2
        super().__init__()
        if blur_filter:
            blur = BlurLayer(blur_filter)
        else:
            blur = None
        self.conv0_up = MyConv2d(in_channels, out_channels, kernel_size=3, gain=gain, use_wscale=use_wscale,
                                 intermediate=blur, upscale=True)
        self.epi1 = LayerEpilogue(out_channels, dlatent_size, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer)
        self.conv1 = MyConv2d(out_channels, out_channels, kernel_size=3, gain=gain, use_wscale=use_wscale)
        self.epi2 = LayerEpilogue(out_channels, dlatent_size, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, activation_layer)
            
    def forward(self, x, dlatents_in_range):
        x = self.conv0_up(x)
        x = self.epi1(x, dlatents_in_range[:, 0])
        x = self.conv1(x)
        x = self.epi2(x, dlatents_in_range[:, 1])
        return x



class G_synthesis(nn.Module):
    def __init__(self,
        dlatent_size        = 512,          # Disentangled latent (W) dimensionality.
        num_channels        = 3,            # Number of output color channels.
        resolution          = 1024,         # Output resolution.
        fmap_base           = 8192,         # Overall multiplier for the number of feature maps.
        fmap_decay          = 1.0,          # log2 feature map reduction when doubling the resolution.
        fmap_max            = 512,          # Maximum number of feature maps in any layer.
        use_styles          = True,         # Enable style inputs?
        const_input_layer   = True,         # First layer is a learned constant?
        use_noise           = True,         # Enable noise inputs?
        randomize_noise     = True,         # True = randomize noise inputs every time (non-deterministic), False = read noise inputs from variables.
        nonlinearity        = 'lrelu',      # Activation function: 'relu', 'lrelu'
        use_wscale          = True,         # Enable equalized learning rate?
        use_pixel_norm      = False,        # Enable pixelwise feature vector normalization?
        use_instance_norm   = True,         # Enable instance normalization?
        dtype               = torch.float32,  # Data type to use for activations and outputs.
        blur_filter         = [1,2,1],      # Low-pass filter to apply when resampling activations. None = no filtering.
        ):
        
        super().__init__()
        def nf(stage):
            return min(int(fmap_base / (2.0 ** (stage * fmap_decay))), fmap_max)
        self.dlatent_size = dlatent_size
        resolution_log2 = int(np.log2(resolution))
        assert resolution == 2**resolution_log2 and resolution >= 4

        act, gain = {'relu': (torch.relu, np.sqrt(2)),
                     'lrelu': (nn.LeakyReLU(negative_slope=0.2), np.sqrt(2))}[nonlinearity]
        num_layers = resolution_log2 * 2 - 2
        num_styles = num_layers if use_styles else 1
        torgbs = []
        blocks = []
        for res in range(2, resolution_log2 + 1):
            channels = nf(res-1)
            name = '{s}x{s}'.format(s=2**res)
            if res == 2:
                blocks.append((name,
                               InputBlock(channels, dlatent_size, const_input_layer, gain, use_wscale,
                                      use_noise, use_pixel_norm, use_instance_norm, use_styles, act)))
                
            else:
                blocks.append((name,
                               GSynthesisBlock(last_channels, channels, blur_filter, dlatent_size, gain, use_wscale, use_noise, use_pixel_norm, use_instance_norm, use_styles, act)))
            last_channels = channels
        self.torgb = MyConv2d(channels, num_channels, 1, gain=1, use_wscale=use_wscale)
        self.blocks = nn.ModuleDict(OrderedDict(blocks))
        
    def forward(self, dlatents_in):
        # Input: Disentangled latents (W) [minibatch, num_layers, dlatent_size].
        # lod_in = tf.cast(tf.get_variable('lod', initializer=np.float32(0), trainable=False), dtype)
        batch_size = dlatents_in.size(0)       
        for i, m in enumerate(self.blocks.values()):
            if i == 0:
                x = m(dlatents_in[:, 2*i:2*i+2])
            else:
                x = m(x, dlatents_in[:, 2*i:2*i+2])
        rgb = self.torgb(x)
        return rgb


avg_latent = torch.zeros(1, 18, 512)

g_all = nn.Sequential(OrderedDict([
    ('g_mapping', G_mapping()),
    # ('truncation', Truncation(avg_latent)),
    ('g_synthesis', G_synthesis())    
]))
g_all.load_state_dict(torch.load('./karras2019stylegan-ffhq-1024x1024.for_g_all.pt'))

g_synthesis = g_all.g_synthesis
g_mapping = g_all.g_mapping