def __init__(

self,

*,

ch,

ch_mult=(1, 2, 4, 8),

num_res_blocks,

attn_resolutions,

dropout=0.0,

resamp_with_conv=True,

in_channels,

resolution,

z_channels,

double_z=True,

**ignore_kwargs,

):

super().__init__()

self.ch = ch

self.temb_ch = 0

self.num_resolutions = len(ch_mult)

self.num_res_blocks = num_res_blocks

self.resolution = resolution

self.in_channels = in_channels

# downsampling

self.conv_in = torch.nn.Conv2d(in_channels, self.ch, kernel_size=3, stride=1, padding=1)

curr_res = resolution

in_ch_mult = (1,) + tuple(ch_mult)

self.down = nn.ModuleList()

for i_level in range(self.num_resolutions):

block = nn.ModuleList()

attn = nn.ModuleList()

block_in = ch * in_ch_mult[i_level]

block_out = ch * ch_mult[i_level]

for i_block in range(self.num_res_blocks):

block.append(

ResnetBlock2D(

in_channels=block_in, out_channels=block_out, temb_channels=self.temb_ch, dropout=dropout

)

)

block_in = block_out

if curr_res in attn_resolutions:

attn.append(AttentionBlock(block_in, overwrite_qkv=True))

down = nn.Module()

down.block = block

down.attn = attn

if i_level != self.num_resolutions - 1:

down.downsample = Downsample2D(block_in, use_conv=resamp_with_conv, padding=0)

curr_res = curr_res // 2

self.down.append(down)

# middle

self.mid = nn.Module()

self.mid.block_1 = ResnetBlock2D(

in_channels=block_in, out_channels=block_in, temb_channels=self.temb_ch, dropout=dropout

)

self.mid.attn_1 = AttentionBlock(block_in, overwrite_qkv=True)

self.mid.block_2 = ResnetBlock2D(

in_channels=block_in, out_channels=block_in, temb_channels=self.temb_ch, dropout=dropout

)

# end

self.norm_out = Normalize(block_in)

self.conv_out = torch.nn.Conv2d(

block_in, 2 * z_channels if double_z else z_channels, kernel_size=3, stride=1, padding=1

)

def forward(self, x):

# assert x.shape[2] == x.shape[3] == self.resolution, "{}, {}, {}".format(x.shape[2], x.shape[3], self.resolution)

# timestep embedding

temb = None

# downsampling

hs = [self.conv_in(x)]

for i_level in range(self.num_resolutions):

for i_block in range(self.num_res_blocks):

h = self.down[i_level].block[i_block](hs[-1], temb)

if len(self.down[i_level].attn) > 0:

h = self.down[i_level].attn[i_block](h)

hs.append(h)

if i_level != self.num_resolutions - 1:

hs.append(self.down[i_level].downsample(hs[-1]))

# middle

h = hs[-1]

h = self.mid.block_1(h, temb)

h = self.mid.attn_1(h)

h = self.mid.block_2(h, temb)

# end

h = self.norm_out(h)

h = nonlinearity(h)

h = self.conv_out(h)

def __init__(

self,

*,

ch,

out_ch,

ch_mult=(1, 2, 4, 8),

num_res_blocks,

attn_resolutions,

dropout=0.0,

resamp_with_conv=True,

in_channels,

resolution,

z_channels,

give_pre_end=False,

**ignorekwargs,

):

super().__init__()

self.ch = ch

self.temb_ch = 0

self.num_resolutions = len(ch_mult)

self.num_res_blocks = num_res_blocks

self.resolution = resolution

self.in_channels = in_channels

self.give_pre_end = give_pre_end

# compute in_ch_mult, block_in and curr_res at lowest res

block_in = ch * ch_mult[self.num_resolutions - 1]

curr_res = resolution // 2 ** (self.num_resolutions - 1)

self.z_shape = (1, z_channels, curr_res, curr_res)

# print("Working with z of shape {} = {} dimensions.".format(self.z_shape, np.prod(self.z_shape)))

# z to block_in

self.conv_in = torch.nn.Conv2d(z_channels, block_in, kernel_size=3, stride=1, padding=1)

# middle

self.mid = nn.Module()

self.mid.block_1 = ResnetBlock2D(

in_channels=block_in, out_channels=block_in, temb_channels=self.temb_ch, dropout=dropout

)

self.mid.attn_1 = AttentionBlock(block_in, overwrite_qkv=True)

self.mid.block_2 = ResnetBlock2D(

in_channels=block_in, out_channels=block_in, temb_channels=self.temb_ch, dropout=dropout

)

# upsampling

self.up = nn.ModuleList()

for i_level in reversed(range(self.num_resolutions)):

block = nn.ModuleList()

attn = nn.ModuleList()

block_out = ch * ch_mult[i_level]

for i_block in range(self.num_res_blocks + 1):

block.append(

ResnetBlock2D(

in_channels=block_in, out_channels=block_out, temb_channels=self.temb_ch, dropout=dropout

)

)

block_in = block_out

if curr_res in attn_resolutions:

attn.append(AttentionBlock(block_in, overwrite_qkv=True))

up = nn.Module()

up.block = block

up.attn = attn

if i_level != 0:

up.upsample = Upsample2D(block_in, use_conv=resamp_with_conv)

curr_res = curr_res * 2

self.up.insert(0, up) # prepend to get consistent order

# end

self.norm_out = Normalize(block_in)

self.conv_out = torch.nn.Conv2d(block_in, out_ch, kernel_size=3, stride=1, padding=1)

def forward(self, z):

# assert z.shape[1:] == self.z_shape[1:]

self.last_z_shape = z.shape

# timestep embedding

temb = None

# z to block_in

h = self.conv_in(z)

# middle

h = self.mid.block_1(h, temb)

h = self.mid.attn_1(h)

h = self.mid.block_2(h, temb)

# upsampling

for i_level in reversed(range(self.num_resolutions)):

for i_block in range(self.num_res_blocks + 1):

h = self.up[i_level].block[i_block](h, temb)

if len(self.up[i_level].attn) > 0:

h = self.up[i_level].attn[i_block](h)

if i_level != 0:

h = self.up[i_level].upsample(h)

# end

if self.give_pre_end:

return h

h = self.norm_out(h)

h = nonlinearity(h)

h = self.conv_out(h)

"""

# NOTE: due to a bug the beta term was applied to the wrong term. for

# backwards compatibility we use the buggy version by default, but you can

# specify legacy=False to fix it.

def __init__(self, n_e, e_dim, beta, remap=None, unknown_index="random", sane_index_shape=False, legacy=True):

super().__init__()

self.n_e = n_e

self.e_dim = e_dim

self.beta = beta

self.legacy = legacy

self.embedding = nn.Embedding(self.n_e, self.e_dim)

self.embedding.weight.data.uniform_(-1.0 / self.n_e, 1.0 / self.n_e)

self.remap = remap

if self.remap is not None:

self.register_buffer("used", torch.tensor(np.load(self.remap)))

self.re_embed = self.used.shape[0]

self.unknown_index = unknown_index # "random" or "extra" or integer

if self.unknown_index == "extra":

self.unknown_index = self.re_embed

self.re_embed = self.re_embed + 1

print(

f"Remapping {self.n_e} indices to {self.re_embed} indices. "

f"Using {self.unknown_index} for unknown indices."

)

else:

self.re_embed = n_e

self.sane_index_shape = sane_index_shape

def remap_to_used(self, inds):

ishape = inds.shape

assert len(ishape) > 1

inds = inds.reshape(ishape[0], -1)

used = self.used.to(inds)

match = (inds[:, :, None] == used[None, None, ...]).long()

new = match.argmax(-1)

unknown = match.sum(2) < 1

if self.unknown_index == "random":

new[unknown] = torch.randint(0, self.re_embed, size=new[unknown].shape).to(device=new.device)

else:

new[unknown] = self.unknown_index

return new.reshape(ishape)

def unmap_to_all(self, inds):

ishape = inds.shape

assert len(ishape) > 1

inds = inds.reshape(ishape[0], -1)

used = self.used.to(inds)

if self.re_embed > self.used.shape[0]: # extra token

inds[inds >= self.used.shape[0]] = 0 # simply set to zero

back = torch.gather(used[None, :][inds.shape[0] * [0], :], 1, inds)

return back.reshape(ishape)

def forward(self, z):

# reshape z -> (batch, height, width, channel) and flatten

z = z.permute(0, 2, 3, 1).contiguous()

z_flattened = z.view(-1, self.e_dim)

# distances from z to embeddings e_j (z - e)^2 = z^2 + e^2 - 2 e * z

d = (

torch.sum(z_flattened**2, dim=1, keepdim=True)

+ torch.sum(self.embedding.weight**2, dim=1)

- 2 * torch.einsum("bd,dn->bn", z_flattened, self.embedding.weight.t())

)

min_encoding_indices = torch.argmin(d, dim=1)

z_q = self.embedding(min_encoding_indices).view(z.shape)

perplexity = None

min_encodings = None

# compute loss for embedding

if not self.legacy:

loss = self.beta * torch.mean((z_q.detach() - z) ** 2) + torch.mean((z_q - z.detach()) ** 2)

else:

loss = torch.mean((z_q.detach() - z) ** 2) + self.beta * torch.mean((z_q - z.detach()) ** 2)

# preserve gradients

z_q = z + (z_q - z).detach()

# reshape back to match original input shape

z_q = z_q.permute(0, 3, 1, 2).contiguous()

if self.remap is not None:

min_encoding_indices = min_encoding_indices.reshape(z.shape[0], -1) # add batch axis

min_encoding_indices = self.remap_to_used(min_encoding_indices)

min_encoding_indices = min_encoding_indices.reshape(-1, 1) # flatten

if self.sane_index_shape:

min_encoding_indices = min_encoding_indices.reshape(z_q.shape[0], z_q.shape[2], z_q.shape[3])

return z_q, loss, (perplexity, min_encodings, min_encoding_indices)

def get_codebook_entry(self, indices, shape):

# shape specifying (batch, height, width, channel)

if self.remap is not None:

indices = indices.reshape(shape[0], -1) # add batch axis

indices = self.unmap_to_all(indices)

indices = indices.reshape(-1) # flatten again

# get quantized latent vectors

z_q = self.embedding(indices)

if shape is not None:

z_q = z_q.view(shape)

# reshape back to match original input shape

z_q = z_q.permute(0, 3, 1, 2).contiguous()

def __init__(self, parameters, deterministic=False):

self.parameters = parameters

self.mean, self.logvar = torch.chunk(parameters, 2, dim=1)

self.logvar = torch.clamp(self.logvar, -30.0, 20.0)

self.deterministic = deterministic

self.std = torch.exp(0.5 * self.logvar)

self.var = torch.exp(self.logvar)

if self.deterministic:

self.var = self.std = torch.zeros_like(self.mean).to(device=self.parameters.device)

def sample(self):

x = self.mean + self.std * torch.randn(self.mean.shape).to(device=self.parameters.device)

return x

def kl(self, other=None):

if self.deterministic:

return torch.Tensor([0.0])

else:

if other is None:

return 0.5 * torch.sum(torch.pow(self.mean, 2) + self.var - 1.0 - self.logvar, dim=[1, 2, 3])

else:

return 0.5 * torch.sum(

torch.pow(self.mean - other.mean, 2) / other.var

+ self.var / other.var

- 1.0

- self.logvar

+ other.logvar,

dim=[1, 2, 3],

)

def nll(self, sample, dims=[1, 2, 3]):

if self.deterministic:

return torch.Tensor([0.0])

logtwopi = np.log(2.0 * np.pi)

return 0.5 * torch.sum(logtwopi + self.logvar + torch.pow(sample - self.mean, 2) / self.var, dim=dims)

def mode(self):

@register_to_config

def __init__(

self,

ch,

out_ch,

num_res_blocks,

attn_resolutions,

in_channels,

resolution,

z_channels,

n_embed,

embed_dim,

remap=None,

sane_index_shape=False, # tell vector quantizer to return indices as bhw

ch_mult=(1, 2, 4, 8),

dropout=0.0,

double_z=True,

resamp_with_conv=True,

give_pre_end=False,

):

super().__init__()

# pass init params to Encoder

self.encoder = Encoder(

ch=ch,

num_res_blocks=num_res_blocks,

attn_resolutions=attn_resolutions,

in_channels=in_channels,

resolution=resolution,

z_channels=z_channels,

ch_mult=ch_mult,

dropout=dropout,

resamp_with_conv=resamp_with_conv,

double_z=double_z,

give_pre_end=give_pre_end,

)

self.quant_conv = torch.nn.Conv2d(z_channels, embed_dim, 1)

self.quantize = VectorQuantizer(n_embed, embed_dim, beta=0.25, remap=remap, sane_index_shape=sane_index_shape)

self.post_quant_conv = torch.nn.Conv2d(embed_dim, z_channels, 1)

# pass init params to Decoder

self.decoder = Decoder(

ch=ch,

out_ch=out_ch,

num_res_blocks=num_res_blocks,

attn_resolutions=attn_resolutions,

in_channels=in_channels,

resolution=resolution,

z_channels=z_channels,

ch_mult=ch_mult,

dropout=dropout,

resamp_with_conv=resamp_with_conv,

give_pre_end=give_pre_end,

)

def encode(self, x):

h = self.encoder(x)

h = self.quant_conv(h)

return h

def decode(self, h, force_not_quantize=False):

# also go through quantization layer

if not force_not_quantize:

quant, emb_loss, info = self.quantize(h)

else:

quant = h

quant = self.post_quant_conv(quant)

dec = self.decoder(quant)

return dec

def forward(self, sample):

x = sample

h = self.encode(x)

dec = self.decode(h)

@register_to_config

def __init__(

self,

ch,

out_ch,

num_res_blocks,

attn_resolutions,

in_channels,

resolution,

z_channels,

embed_dim,

remap=None,

sane_index_shape=False, # tell vector quantizer to return indices as bhw

ch_mult=(1, 2, 4, 8),

dropout=0.0,

double_z=True,

resamp_with_conv=True,

give_pre_end=False,

):

super().__init__()

# pass init params to Encoder

self.encoder = Encoder(

ch=ch,

out_ch=out_ch,

num_res_blocks=num_res_blocks,

attn_resolutions=attn_resolutions,

in_channels=in_channels,

resolution=resolution,

z_channels=z_channels,

ch_mult=ch_mult,

dropout=dropout,

resamp_with_conv=resamp_with_conv,

double_z=double_z,

give_pre_end=give_pre_end,

)

# pass init params to Decoder

self.decoder = Decoder(

ch=ch,

out_ch=out_ch,

num_res_blocks=num_res_blocks,

attn_resolutions=attn_resolutions,

in_channels=in_channels,

resolution=resolution,

z_channels=z_channels,

ch_mult=ch_mult,

dropout=dropout,

resamp_with_conv=resamp_with_conv,

give_pre_end=give_pre_end,

)

self.quant_conv = torch.nn.Conv2d(2 * z_channels, 2 * embed_dim, 1)

self.post_quant_conv = torch.nn.Conv2d(embed_dim, z_channels, 1)

def encode(self, x):

h = self.encoder(x)

moments = self.quant_conv(h)

posterior = DiagonalGaussianDistribution(moments)

return posterior

def decode(self, z):

z = self.post_quant_conv(z)

dec = self.decoder(z)

return dec

def forward(self, sample, sample_posterior=False):

x = sample

posterior = self.encode(x)

if sample_posterior:

z = posterior.sample()

else:

z = posterior.mode()

dec = self.decode(z)