diffusers-sdxl-controlnet / tests /models /unets /test_models_unet_2d_condition.py
svjack's picture
Upload 1392 files
43b7e92 verified
raw
history blame
58.1 kB
# coding=utf-8
# Copyright 2024 HuggingFace Inc.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import copy
import gc
import os
import tempfile
import unittest
from collections import OrderedDict
import torch
from huggingface_hub import snapshot_download
from parameterized import parameterized
from pytest import mark
from diffusers import UNet2DConditionModel
from diffusers.models.attention_processor import (
CustomDiffusionAttnProcessor,
IPAdapterAttnProcessor,
IPAdapterAttnProcessor2_0,
)
from diffusers.models.embeddings import ImageProjection, IPAdapterFaceIDImageProjection, IPAdapterPlusImageProjection
from diffusers.utils import logging
from diffusers.utils.import_utils import is_xformers_available
from diffusers.utils.testing_utils import (
backend_empty_cache,
enable_full_determinism,
floats_tensor,
is_peft_available,
load_hf_numpy,
require_peft_backend,
require_torch_accelerator,
require_torch_accelerator_with_fp16,
require_torch_accelerator_with_training,
require_torch_gpu,
skip_mps,
slow,
torch_all_close,
torch_device,
)
from ..test_modeling_common import ModelTesterMixin, UNetTesterMixin
if is_peft_available():
from peft import LoraConfig
from peft.tuners.tuners_utils import BaseTunerLayer
logger = logging.get_logger(__name__)
enable_full_determinism()
def get_unet_lora_config():
rank = 4
unet_lora_config = LoraConfig(
r=rank,
lora_alpha=rank,
target_modules=["to_q", "to_k", "to_v", "to_out.0"],
init_lora_weights=False,
use_dora=False,
)
return unet_lora_config
def check_if_lora_correctly_set(model) -> bool:
"""
Checks if the LoRA layers are correctly set with peft
"""
for module in model.modules():
if isinstance(module, BaseTunerLayer):
return True
return False
def create_ip_adapter_state_dict(model):
# "ip_adapter" (cross-attention weights)
ip_cross_attn_state_dict = {}
key_id = 1
for name in model.attn_processors.keys():
cross_attention_dim = (
None if name.endswith("attn1.processor") or "motion_module" in name else model.config.cross_attention_dim
)
if name.startswith("mid_block"):
hidden_size = model.config.block_out_channels[-1]
elif name.startswith("up_blocks"):
block_id = int(name[len("up_blocks.")])
hidden_size = list(reversed(model.config.block_out_channels))[block_id]
elif name.startswith("down_blocks"):
block_id = int(name[len("down_blocks.")])
hidden_size = model.config.block_out_channels[block_id]
if cross_attention_dim is not None:
sd = IPAdapterAttnProcessor(
hidden_size=hidden_size, cross_attention_dim=cross_attention_dim, scale=1.0
).state_dict()
ip_cross_attn_state_dict.update(
{
f"{key_id}.to_k_ip.weight": sd["to_k_ip.0.weight"],
f"{key_id}.to_v_ip.weight": sd["to_v_ip.0.weight"],
}
)
key_id += 2
# "image_proj" (ImageProjection layer weights)
cross_attention_dim = model.config["cross_attention_dim"]
image_projection = ImageProjection(
cross_attention_dim=cross_attention_dim, image_embed_dim=cross_attention_dim, num_image_text_embeds=4
)
ip_image_projection_state_dict = {}
sd = image_projection.state_dict()
ip_image_projection_state_dict.update(
{
"proj.weight": sd["image_embeds.weight"],
"proj.bias": sd["image_embeds.bias"],
"norm.weight": sd["norm.weight"],
"norm.bias": sd["norm.bias"],
}
)
del sd
ip_state_dict = {}
ip_state_dict.update({"image_proj": ip_image_projection_state_dict, "ip_adapter": ip_cross_attn_state_dict})
return ip_state_dict
def create_ip_adapter_plus_state_dict(model):
# "ip_adapter" (cross-attention weights)
ip_cross_attn_state_dict = {}
key_id = 1
for name in model.attn_processors.keys():
cross_attention_dim = None if name.endswith("attn1.processor") else model.config.cross_attention_dim
if name.startswith("mid_block"):
hidden_size = model.config.block_out_channels[-1]
elif name.startswith("up_blocks"):
block_id = int(name[len("up_blocks.")])
hidden_size = list(reversed(model.config.block_out_channels))[block_id]
elif name.startswith("down_blocks"):
block_id = int(name[len("down_blocks.")])
hidden_size = model.config.block_out_channels[block_id]
if cross_attention_dim is not None:
sd = IPAdapterAttnProcessor(
hidden_size=hidden_size, cross_attention_dim=cross_attention_dim, scale=1.0
).state_dict()
ip_cross_attn_state_dict.update(
{
f"{key_id}.to_k_ip.weight": sd["to_k_ip.0.weight"],
f"{key_id}.to_v_ip.weight": sd["to_v_ip.0.weight"],
}
)
key_id += 2
# "image_proj" (ImageProjection layer weights)
cross_attention_dim = model.config["cross_attention_dim"]
image_projection = IPAdapterPlusImageProjection(
embed_dims=cross_attention_dim, output_dims=cross_attention_dim, dim_head=32, heads=2, num_queries=4
)
ip_image_projection_state_dict = OrderedDict()
keys = [k for k in image_projection.state_dict() if "layers." in k]
print(keys)
for k, v in image_projection.state_dict().items():
if "2.to" in k:
k = k.replace("2.to", "0.to")
elif "layers.0.ln0" in k:
k = k.replace("layers.0.ln0", "layers.0.0.norm1")
elif "layers.0.ln1" in k:
k = k.replace("layers.0.ln1", "layers.0.0.norm2")
elif "layers.1.ln0" in k:
k = k.replace("layers.1.ln0", "layers.1.0.norm1")
elif "layers.1.ln1" in k:
k = k.replace("layers.1.ln1", "layers.1.0.norm2")
elif "layers.2.ln0" in k:
k = k.replace("layers.2.ln0", "layers.2.0.norm1")
elif "layers.2.ln1" in k:
k = k.replace("layers.2.ln1", "layers.2.0.norm2")
elif "layers.3.ln0" in k:
k = k.replace("layers.3.ln0", "layers.3.0.norm1")
elif "layers.3.ln1" in k:
k = k.replace("layers.3.ln1", "layers.3.0.norm2")
elif "to_q" in k:
parts = k.split(".")
parts[2] = "attn"
k = ".".join(parts)
elif "to_out.0" in k:
parts = k.split(".")
parts[2] = "attn"
k = ".".join(parts)
k = k.replace("to_out.0", "to_out")
else:
k = k.replace("0.ff.0", "0.1.0")
k = k.replace("0.ff.1.net.0.proj", "0.1.1")
k = k.replace("0.ff.1.net.2", "0.1.3")
k = k.replace("1.ff.0", "1.1.0")
k = k.replace("1.ff.1.net.0.proj", "1.1.1")
k = k.replace("1.ff.1.net.2", "1.1.3")
k = k.replace("2.ff.0", "2.1.0")
k = k.replace("2.ff.1.net.0.proj", "2.1.1")
k = k.replace("2.ff.1.net.2", "2.1.3")
k = k.replace("3.ff.0", "3.1.0")
k = k.replace("3.ff.1.net.0.proj", "3.1.1")
k = k.replace("3.ff.1.net.2", "3.1.3")
# if "norm_cross" in k:
# ip_image_projection_state_dict[k.replace("norm_cross", "norm1")] = v
# elif "layer_norm" in k:
# ip_image_projection_state_dict[k.replace("layer_norm", "norm2")] = v
if "to_k" in k:
parts = k.split(".")
parts[2] = "attn"
k = ".".join(parts)
ip_image_projection_state_dict[k.replace("to_k", "to_kv")] = torch.cat([v, v], dim=0)
elif "to_v" in k:
continue
else:
ip_image_projection_state_dict[k] = v
ip_state_dict = {}
ip_state_dict.update({"image_proj": ip_image_projection_state_dict, "ip_adapter": ip_cross_attn_state_dict})
return ip_state_dict
def create_ip_adapter_faceid_state_dict(model):
# "ip_adapter" (cross-attention weights)
# no LoRA weights
ip_cross_attn_state_dict = {}
key_id = 1
for name in model.attn_processors.keys():
cross_attention_dim = (
None if name.endswith("attn1.processor") or "motion_module" in name else model.config.cross_attention_dim
)
if name.startswith("mid_block"):
hidden_size = model.config.block_out_channels[-1]
elif name.startswith("up_blocks"):
block_id = int(name[len("up_blocks.")])
hidden_size = list(reversed(model.config.block_out_channels))[block_id]
elif name.startswith("down_blocks"):
block_id = int(name[len("down_blocks.")])
hidden_size = model.config.block_out_channels[block_id]
if cross_attention_dim is not None:
sd = IPAdapterAttnProcessor(
hidden_size=hidden_size, cross_attention_dim=cross_attention_dim, scale=1.0
).state_dict()
ip_cross_attn_state_dict.update(
{
f"{key_id}.to_k_ip.weight": sd["to_k_ip.0.weight"],
f"{key_id}.to_v_ip.weight": sd["to_v_ip.0.weight"],
}
)
key_id += 2
# "image_proj" (ImageProjection layer weights)
cross_attention_dim = model.config["cross_attention_dim"]
image_projection = IPAdapterFaceIDImageProjection(
cross_attention_dim=cross_attention_dim, image_embed_dim=cross_attention_dim, mult=2, num_tokens=4
)
ip_image_projection_state_dict = {}
sd = image_projection.state_dict()
ip_image_projection_state_dict.update(
{
"proj.0.weight": sd["ff.net.0.proj.weight"],
"proj.0.bias": sd["ff.net.0.proj.bias"],
"proj.2.weight": sd["ff.net.2.weight"],
"proj.2.bias": sd["ff.net.2.bias"],
"norm.weight": sd["norm.weight"],
"norm.bias": sd["norm.bias"],
}
)
del sd
ip_state_dict = {}
ip_state_dict.update({"image_proj": ip_image_projection_state_dict, "ip_adapter": ip_cross_attn_state_dict})
return ip_state_dict
def create_custom_diffusion_layers(model, mock_weights: bool = True):
train_kv = True
train_q_out = True
custom_diffusion_attn_procs = {}
st = model.state_dict()
for name, _ in model.attn_processors.items():
cross_attention_dim = None if name.endswith("attn1.processor") else model.config.cross_attention_dim
if name.startswith("mid_block"):
hidden_size = model.config.block_out_channels[-1]
elif name.startswith("up_blocks"):
block_id = int(name[len("up_blocks.")])
hidden_size = list(reversed(model.config.block_out_channels))[block_id]
elif name.startswith("down_blocks"):
block_id = int(name[len("down_blocks.")])
hidden_size = model.config.block_out_channels[block_id]
layer_name = name.split(".processor")[0]
weights = {
"to_k_custom_diffusion.weight": st[layer_name + ".to_k.weight"],
"to_v_custom_diffusion.weight": st[layer_name + ".to_v.weight"],
}
if train_q_out:
weights["to_q_custom_diffusion.weight"] = st[layer_name + ".to_q.weight"]
weights["to_out_custom_diffusion.0.weight"] = st[layer_name + ".to_out.0.weight"]
weights["to_out_custom_diffusion.0.bias"] = st[layer_name + ".to_out.0.bias"]
if cross_attention_dim is not None:
custom_diffusion_attn_procs[name] = CustomDiffusionAttnProcessor(
train_kv=train_kv,
train_q_out=train_q_out,
hidden_size=hidden_size,
cross_attention_dim=cross_attention_dim,
).to(model.device)
custom_diffusion_attn_procs[name].load_state_dict(weights)
if mock_weights:
# add 1 to weights to mock trained weights
with torch.no_grad():
custom_diffusion_attn_procs[name].to_k_custom_diffusion.weight += 1
custom_diffusion_attn_procs[name].to_v_custom_diffusion.weight += 1
else:
custom_diffusion_attn_procs[name] = CustomDiffusionAttnProcessor(
train_kv=False,
train_q_out=False,
hidden_size=hidden_size,
cross_attention_dim=cross_attention_dim,
)
del st
return custom_diffusion_attn_procs
class UNet2DConditionModelTests(ModelTesterMixin, UNetTesterMixin, unittest.TestCase):
model_class = UNet2DConditionModel
main_input_name = "sample"
# We override the items here because the unet under consideration is small.
model_split_percents = [0.5, 0.3, 0.4]
@property
def dummy_input(self):
batch_size = 4
num_channels = 4
sizes = (16, 16)
noise = floats_tensor((batch_size, num_channels) + sizes).to(torch_device)
time_step = torch.tensor([10]).to(torch_device)
encoder_hidden_states = floats_tensor((batch_size, 4, 8)).to(torch_device)
return {"sample": noise, "timestep": time_step, "encoder_hidden_states": encoder_hidden_states}
@property
def input_shape(self):
return (4, 16, 16)
@property
def output_shape(self):
return (4, 16, 16)
def prepare_init_args_and_inputs_for_common(self):
init_dict = {
"block_out_channels": (4, 8),
"norm_num_groups": 4,
"down_block_types": ("CrossAttnDownBlock2D", "DownBlock2D"),
"up_block_types": ("UpBlock2D", "CrossAttnUpBlock2D"),
"cross_attention_dim": 8,
"attention_head_dim": 2,
"out_channels": 4,
"in_channels": 4,
"layers_per_block": 1,
"sample_size": 16,
}
inputs_dict = self.dummy_input
return init_dict, inputs_dict
@unittest.skipIf(
torch_device != "cuda" or not is_xformers_available(),
reason="XFormers attention is only available with CUDA and `xformers` installed",
)
def test_xformers_enable_works(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**init_dict)
model.enable_xformers_memory_efficient_attention()
assert (
model.mid_block.attentions[0].transformer_blocks[0].attn1.processor.__class__.__name__
== "XFormersAttnProcessor"
), "xformers is not enabled"
@require_torch_accelerator_with_training
def test_gradient_checkpointing(self):
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**init_dict)
model.to(torch_device)
assert not model.is_gradient_checkpointing and model.training
out = model(**inputs_dict).sample
# run the backwards pass on the model. For backwards pass, for simplicity purpose,
# we won't calculate the loss and rather backprop on out.sum()
model.zero_grad()
labels = torch.randn_like(out)
loss = (out - labels).mean()
loss.backward()
# re-instantiate the model now enabling gradient checkpointing
model_2 = self.model_class(**init_dict)
# clone model
model_2.load_state_dict(model.state_dict())
model_2.to(torch_device)
model_2.enable_gradient_checkpointing()
assert model_2.is_gradient_checkpointing and model_2.training
out_2 = model_2(**inputs_dict).sample
# run the backwards pass on the model. For backwards pass, for simplicity purpose,
# we won't calculate the loss and rather backprop on out.sum()
model_2.zero_grad()
loss_2 = (out_2 - labels).mean()
loss_2.backward()
# compare the output and parameters gradients
self.assertTrue((loss - loss_2).abs() < 1e-5)
named_params = dict(model.named_parameters())
named_params_2 = dict(model_2.named_parameters())
for name, param in named_params.items():
self.assertTrue(torch_all_close(param.grad.data, named_params_2[name].grad.data, atol=5e-5))
def test_model_with_attention_head_dim_tuple(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
with torch.no_grad():
output = model(**inputs_dict)
if isinstance(output, dict):
output = output.sample
self.assertIsNotNone(output)
expected_shape = inputs_dict["sample"].shape
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_model_with_use_linear_projection(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["use_linear_projection"] = True
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
with torch.no_grad():
output = model(**inputs_dict)
if isinstance(output, dict):
output = output.sample
self.assertIsNotNone(output)
expected_shape = inputs_dict["sample"].shape
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_model_with_cross_attention_dim_tuple(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["cross_attention_dim"] = (8, 8)
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
with torch.no_grad():
output = model(**inputs_dict)
if isinstance(output, dict):
output = output.sample
self.assertIsNotNone(output)
expected_shape = inputs_dict["sample"].shape
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_model_with_simple_projection(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
batch_size, _, _, sample_size = inputs_dict["sample"].shape
init_dict["class_embed_type"] = "simple_projection"
init_dict["projection_class_embeddings_input_dim"] = sample_size
inputs_dict["class_labels"] = floats_tensor((batch_size, sample_size)).to(torch_device)
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
with torch.no_grad():
output = model(**inputs_dict)
if isinstance(output, dict):
output = output.sample
self.assertIsNotNone(output)
expected_shape = inputs_dict["sample"].shape
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_model_with_class_embeddings_concat(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
batch_size, _, _, sample_size = inputs_dict["sample"].shape
init_dict["class_embed_type"] = "simple_projection"
init_dict["projection_class_embeddings_input_dim"] = sample_size
init_dict["class_embeddings_concat"] = True
inputs_dict["class_labels"] = floats_tensor((batch_size, sample_size)).to(torch_device)
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
with torch.no_grad():
output = model(**inputs_dict)
if isinstance(output, dict):
output = output.sample
self.assertIsNotNone(output)
expected_shape = inputs_dict["sample"].shape
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_model_attention_slicing(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
model.eval()
model.set_attention_slice("auto")
with torch.no_grad():
output = model(**inputs_dict)
assert output is not None
model.set_attention_slice("max")
with torch.no_grad():
output = model(**inputs_dict)
assert output is not None
model.set_attention_slice(2)
with torch.no_grad():
output = model(**inputs_dict)
assert output is not None
def test_model_sliceable_head_dim(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
def check_sliceable_dim_attr(module: torch.nn.Module):
if hasattr(module, "set_attention_slice"):
assert isinstance(module.sliceable_head_dim, int)
for child in module.children():
check_sliceable_dim_attr(child)
# retrieve number of attention layers
for module in model.children():
check_sliceable_dim_attr(module)
def test_gradient_checkpointing_is_applied(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model_class_copy = copy.copy(self.model_class)
modules_with_gc_enabled = {}
# now monkey patch the following function:
# def _set_gradient_checkpointing(self, module, value=False):
# if hasattr(module, "gradient_checkpointing"):
# module.gradient_checkpointing = value
def _set_gradient_checkpointing_new(self, module, value=False):
if hasattr(module, "gradient_checkpointing"):
module.gradient_checkpointing = value
modules_with_gc_enabled[module.__class__.__name__] = True
model_class_copy._set_gradient_checkpointing = _set_gradient_checkpointing_new
model = model_class_copy(**init_dict)
model.enable_gradient_checkpointing()
EXPECTED_SET = {
"CrossAttnUpBlock2D",
"CrossAttnDownBlock2D",
"UNetMidBlock2DCrossAttn",
"UpBlock2D",
"Transformer2DModel",
"DownBlock2D",
}
assert set(modules_with_gc_enabled.keys()) == EXPECTED_SET
assert all(modules_with_gc_enabled.values()), "All modules should be enabled"
def test_special_attn_proc(self):
class AttnEasyProc(torch.nn.Module):
def __init__(self, num):
super().__init__()
self.weight = torch.nn.Parameter(torch.tensor(num))
self.is_run = False
self.number = 0
self.counter = 0
def __call__(self, attn, hidden_states, encoder_hidden_states=None, attention_mask=None, number=None):
batch_size, sequence_length, _ = hidden_states.shape
attention_mask = attn.prepare_attention_mask(attention_mask, sequence_length, batch_size)
query = attn.to_q(hidden_states)
encoder_hidden_states = encoder_hidden_states if encoder_hidden_states is not None else hidden_states
key = attn.to_k(encoder_hidden_states)
value = attn.to_v(encoder_hidden_states)
query = attn.head_to_batch_dim(query)
key = attn.head_to_batch_dim(key)
value = attn.head_to_batch_dim(value)
attention_probs = attn.get_attention_scores(query, key, attention_mask)
hidden_states = torch.bmm(attention_probs, value)
hidden_states = attn.batch_to_head_dim(hidden_states)
# linear proj
hidden_states = attn.to_out[0](hidden_states)
# dropout
hidden_states = attn.to_out[1](hidden_states)
hidden_states += self.weight
self.is_run = True
self.counter += 1
self.number = number
return hidden_states
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
processor = AttnEasyProc(5.0)
model.set_attn_processor(processor)
model(**inputs_dict, cross_attention_kwargs={"number": 123}).sample
assert processor.counter == 8
assert processor.is_run
assert processor.number == 123
@parameterized.expand(
[
# fmt: off
[torch.bool],
[torch.long],
[torch.float],
# fmt: on
]
)
def test_model_xattn_mask(self, mask_dtype):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**{**init_dict, "attention_head_dim": (8, 16), "block_out_channels": (16, 32)})
model.to(torch_device)
model.eval()
cond = inputs_dict["encoder_hidden_states"]
with torch.no_grad():
full_cond_out = model(**inputs_dict).sample
assert full_cond_out is not None
keepall_mask = torch.ones(*cond.shape[:-1], device=cond.device, dtype=mask_dtype)
full_cond_keepallmask_out = model(**{**inputs_dict, "encoder_attention_mask": keepall_mask}).sample
assert full_cond_keepallmask_out.allclose(
full_cond_out, rtol=1e-05, atol=1e-05
), "a 'keep all' mask should give the same result as no mask"
trunc_cond = cond[:, :-1, :]
trunc_cond_out = model(**{**inputs_dict, "encoder_hidden_states": trunc_cond}).sample
assert not trunc_cond_out.allclose(
full_cond_out, rtol=1e-05, atol=1e-05
), "discarding the last token from our cond should change the result"
batch, tokens, _ = cond.shape
mask_last = (torch.arange(tokens) < tokens - 1).expand(batch, -1).to(cond.device, mask_dtype)
masked_cond_out = model(**{**inputs_dict, "encoder_attention_mask": mask_last}).sample
assert masked_cond_out.allclose(
trunc_cond_out, rtol=1e-05, atol=1e-05
), "masking the last token from our cond should be equivalent to truncating that token out of the condition"
# see diffusers.models.attention_processor::Attention#prepare_attention_mask
# note: we may not need to fix mask padding to work for stable-diffusion cross-attn masks.
# since the use-case (somebody passes in a too-short cross-attn mask) is pretty esoteric.
# maybe it's fine that this only works for the unclip use-case.
@mark.skip(
reason="we currently pad mask by target_length tokens (what unclip needs), whereas stable-diffusion's cross-attn needs to instead pad by remaining_length."
)
def test_model_xattn_padding(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**{**init_dict, "attention_head_dim": (8, 16)})
model.to(torch_device)
model.eval()
cond = inputs_dict["encoder_hidden_states"]
with torch.no_grad():
full_cond_out = model(**inputs_dict).sample
assert full_cond_out is not None
batch, tokens, _ = cond.shape
keeplast_mask = (torch.arange(tokens) == tokens - 1).expand(batch, -1).to(cond.device, torch.bool)
keeplast_out = model(**{**inputs_dict, "encoder_attention_mask": keeplast_mask}).sample
assert not keeplast_out.allclose(full_cond_out), "a 'keep last token' mask should change the result"
trunc_mask = torch.zeros(batch, tokens - 1, device=cond.device, dtype=torch.bool)
trunc_mask_out = model(**{**inputs_dict, "encoder_attention_mask": trunc_mask}).sample
assert trunc_mask_out.allclose(
keeplast_out
), "a mask with fewer tokens than condition, will be padded with 'keep' tokens. a 'discard-all' mask missing the final token is thus equivalent to a 'keep last' mask."
def test_custom_diffusion_processors(self):
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
with torch.no_grad():
sample1 = model(**inputs_dict).sample
custom_diffusion_attn_procs = create_custom_diffusion_layers(model, mock_weights=False)
# make sure we can set a list of attention processors
model.set_attn_processor(custom_diffusion_attn_procs)
model.to(torch_device)
# test that attn processors can be set to itself
model.set_attn_processor(model.attn_processors)
with torch.no_grad():
sample2 = model(**inputs_dict).sample
assert (sample1 - sample2).abs().max() < 3e-3
def test_custom_diffusion_save_load(self):
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
torch.manual_seed(0)
model = self.model_class(**init_dict)
model.to(torch_device)
with torch.no_grad():
old_sample = model(**inputs_dict).sample
custom_diffusion_attn_procs = create_custom_diffusion_layers(model, mock_weights=False)
model.set_attn_processor(custom_diffusion_attn_procs)
with torch.no_grad():
sample = model(**inputs_dict).sample
with tempfile.TemporaryDirectory() as tmpdirname:
model.save_attn_procs(tmpdirname, safe_serialization=False)
self.assertTrue(os.path.isfile(os.path.join(tmpdirname, "pytorch_custom_diffusion_weights.bin")))
torch.manual_seed(0)
new_model = self.model_class(**init_dict)
new_model.load_attn_procs(tmpdirname, weight_name="pytorch_custom_diffusion_weights.bin")
new_model.to(torch_device)
with torch.no_grad():
new_sample = new_model(**inputs_dict).sample
assert (sample - new_sample).abs().max() < 1e-4
# custom diffusion and no custom diffusion should be the same
assert (sample - old_sample).abs().max() < 3e-3
@unittest.skipIf(
torch_device != "cuda" or not is_xformers_available(),
reason="XFormers attention is only available with CUDA and `xformers` installed",
)
def test_custom_diffusion_xformers_on_off(self):
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
torch.manual_seed(0)
model = self.model_class(**init_dict)
model.to(torch_device)
custom_diffusion_attn_procs = create_custom_diffusion_layers(model, mock_weights=False)
model.set_attn_processor(custom_diffusion_attn_procs)
# default
with torch.no_grad():
sample = model(**inputs_dict).sample
model.enable_xformers_memory_efficient_attention()
on_sample = model(**inputs_dict).sample
model.disable_xformers_memory_efficient_attention()
off_sample = model(**inputs_dict).sample
assert (sample - on_sample).abs().max() < 1e-4
assert (sample - off_sample).abs().max() < 1e-4
def test_pickle(self):
# enable deterministic behavior for gradient checkpointing
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
with torch.no_grad():
sample = model(**inputs_dict).sample
sample_copy = copy.copy(sample)
assert (sample - sample_copy).abs().max() < 1e-4
def test_asymmetrical_unet(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
# Add asymmetry to configs
init_dict["transformer_layers_per_block"] = [[3, 2], 1]
init_dict["reverse_transformer_layers_per_block"] = [[3, 4], 1]
torch.manual_seed(0)
model = self.model_class(**init_dict)
model.to(torch_device)
output = model(**inputs_dict).sample
expected_shape = inputs_dict["sample"].shape
# Check if input and output shapes are the same
self.assertEqual(output.shape, expected_shape, "Input and output shapes do not match")
def test_ip_adapter(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
# forward pass without ip-adapter
with torch.no_grad():
sample1 = model(**inputs_dict).sample
# update inputs_dict for ip-adapter
batch_size = inputs_dict["encoder_hidden_states"].shape[0]
# for ip-adapter image_embeds has shape [batch_size, num_image, embed_dim]
image_embeds = floats_tensor((batch_size, 1, model.config.cross_attention_dim)).to(torch_device)
inputs_dict["added_cond_kwargs"] = {"image_embeds": [image_embeds]}
# make ip_adapter_1 and ip_adapter_2
ip_adapter_1 = create_ip_adapter_state_dict(model)
image_proj_state_dict_2 = {k: w + 1.0 for k, w in ip_adapter_1["image_proj"].items()}
cross_attn_state_dict_2 = {k: w + 1.0 for k, w in ip_adapter_1["ip_adapter"].items()}
ip_adapter_2 = {}
ip_adapter_2.update({"image_proj": image_proj_state_dict_2, "ip_adapter": cross_attn_state_dict_2})
# forward pass ip_adapter_1
model._load_ip_adapter_weights([ip_adapter_1])
assert model.config.encoder_hid_dim_type == "ip_image_proj"
assert model.encoder_hid_proj is not None
assert model.down_blocks[0].attentions[0].transformer_blocks[0].attn2.processor.__class__.__name__ in (
"IPAdapterAttnProcessor",
"IPAdapterAttnProcessor2_0",
)
with torch.no_grad():
sample2 = model(**inputs_dict).sample
# forward pass with ip_adapter_2
model._load_ip_adapter_weights([ip_adapter_2])
with torch.no_grad():
sample3 = model(**inputs_dict).sample
# forward pass with ip_adapter_1 again
model._load_ip_adapter_weights([ip_adapter_1])
with torch.no_grad():
sample4 = model(**inputs_dict).sample
# forward pass with multiple ip-adapters and multiple images
model._load_ip_adapter_weights([ip_adapter_1, ip_adapter_2])
# set the scale for ip_adapter_2 to 0 so that result should be same as only load ip_adapter_1
for attn_processor in model.attn_processors.values():
if isinstance(attn_processor, (IPAdapterAttnProcessor, IPAdapterAttnProcessor2_0)):
attn_processor.scale = [1, 0]
image_embeds_multi = image_embeds.repeat(1, 2, 1)
inputs_dict["added_cond_kwargs"] = {"image_embeds": [image_embeds_multi, image_embeds_multi]}
with torch.no_grad():
sample5 = model(**inputs_dict).sample
# forward pass with single ip-adapter & single image when image_embeds is not a list and a 2-d tensor
image_embeds = image_embeds.squeeze(1)
inputs_dict["added_cond_kwargs"] = {"image_embeds": image_embeds}
model._load_ip_adapter_weights(ip_adapter_1)
with torch.no_grad():
sample6 = model(**inputs_dict).sample
assert not sample1.allclose(sample2, atol=1e-4, rtol=1e-4)
assert not sample2.allclose(sample3, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample4, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample5, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample6, atol=1e-4, rtol=1e-4)
def test_ip_adapter_plus(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
init_dict["block_out_channels"] = (16, 32)
init_dict["attention_head_dim"] = (8, 16)
model = self.model_class(**init_dict)
model.to(torch_device)
# forward pass without ip-adapter
with torch.no_grad():
sample1 = model(**inputs_dict).sample
# update inputs_dict for ip-adapter
batch_size = inputs_dict["encoder_hidden_states"].shape[0]
# for ip-adapter-plus image_embeds has shape [batch_size, num_image, sequence_length, embed_dim]
image_embeds = floats_tensor((batch_size, 1, 1, model.config.cross_attention_dim)).to(torch_device)
inputs_dict["added_cond_kwargs"] = {"image_embeds": [image_embeds]}
# make ip_adapter_1 and ip_adapter_2
ip_adapter_1 = create_ip_adapter_plus_state_dict(model)
image_proj_state_dict_2 = {k: w + 1.0 for k, w in ip_adapter_1["image_proj"].items()}
cross_attn_state_dict_2 = {k: w + 1.0 for k, w in ip_adapter_1["ip_adapter"].items()}
ip_adapter_2 = {}
ip_adapter_2.update({"image_proj": image_proj_state_dict_2, "ip_adapter": cross_attn_state_dict_2})
# forward pass ip_adapter_1
model._load_ip_adapter_weights([ip_adapter_1])
assert model.config.encoder_hid_dim_type == "ip_image_proj"
assert model.encoder_hid_proj is not None
assert model.down_blocks[0].attentions[0].transformer_blocks[0].attn2.processor.__class__.__name__ in (
"IPAdapterAttnProcessor",
"IPAdapterAttnProcessor2_0",
)
with torch.no_grad():
sample2 = model(**inputs_dict).sample
# forward pass with ip_adapter_2
model._load_ip_adapter_weights([ip_adapter_2])
with torch.no_grad():
sample3 = model(**inputs_dict).sample
# forward pass with ip_adapter_1 again
model._load_ip_adapter_weights([ip_adapter_1])
with torch.no_grad():
sample4 = model(**inputs_dict).sample
# forward pass with multiple ip-adapters and multiple images
model._load_ip_adapter_weights([ip_adapter_1, ip_adapter_2])
# set the scale for ip_adapter_2 to 0 so that result should be same as only load ip_adapter_1
for attn_processor in model.attn_processors.values():
if isinstance(attn_processor, (IPAdapterAttnProcessor, IPAdapterAttnProcessor2_0)):
attn_processor.scale = [1, 0]
image_embeds_multi = image_embeds.repeat(1, 2, 1, 1)
inputs_dict["added_cond_kwargs"] = {"image_embeds": [image_embeds_multi, image_embeds_multi]}
with torch.no_grad():
sample5 = model(**inputs_dict).sample
# forward pass with single ip-adapter & single image when image_embeds is a 3-d tensor
image_embeds = image_embeds[:,].squeeze(1)
inputs_dict["added_cond_kwargs"] = {"image_embeds": image_embeds}
model._load_ip_adapter_weights(ip_adapter_1)
with torch.no_grad():
sample6 = model(**inputs_dict).sample
assert not sample1.allclose(sample2, atol=1e-4, rtol=1e-4)
assert not sample2.allclose(sample3, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample4, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample5, atol=1e-4, rtol=1e-4)
assert sample2.allclose(sample6, atol=1e-4, rtol=1e-4)
@require_torch_gpu
def test_load_sharded_checkpoint_from_hub(self):
_, inputs_dict = self.prepare_init_args_and_inputs_for_common()
loaded_model = self.model_class.from_pretrained("hf-internal-testing/unet2d-sharded-dummy")
loaded_model = loaded_model.to(torch_device)
new_output = loaded_model(**inputs_dict)
assert loaded_model
assert new_output.sample.shape == (4, 4, 16, 16)
@require_torch_gpu
def test_load_sharded_checkpoint_from_hub_local(self):
_, inputs_dict = self.prepare_init_args_and_inputs_for_common()
ckpt_path = snapshot_download("hf-internal-testing/unet2d-sharded-dummy")
loaded_model = self.model_class.from_pretrained(ckpt_path, local_files_only=True)
loaded_model = loaded_model.to(torch_device)
new_output = loaded_model(**inputs_dict)
assert loaded_model
assert new_output.sample.shape == (4, 4, 16, 16)
@require_torch_gpu
def test_load_sharded_checkpoint_device_map_from_hub(self):
_, inputs_dict = self.prepare_init_args_and_inputs_for_common()
loaded_model = self.model_class.from_pretrained("hf-internal-testing/unet2d-sharded-dummy", device_map="auto")
new_output = loaded_model(**inputs_dict)
assert loaded_model
assert new_output.sample.shape == (4, 4, 16, 16)
@require_torch_gpu
def test_load_sharded_checkpoint_device_map_from_hub_local(self):
_, inputs_dict = self.prepare_init_args_and_inputs_for_common()
ckpt_path = snapshot_download("hf-internal-testing/unet2d-sharded-dummy")
loaded_model = self.model_class.from_pretrained(ckpt_path, local_files_only=True, device_map="auto")
new_output = loaded_model(**inputs_dict)
assert loaded_model
assert new_output.sample.shape == (4, 4, 16, 16)
@require_peft_backend
def test_lora(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**init_dict)
model.to(torch_device)
# forward pass without LoRA
with torch.no_grad():
non_lora_sample = model(**inputs_dict).sample
unet_lora_config = get_unet_lora_config()
model.add_adapter(unet_lora_config)
assert check_if_lora_correctly_set(model), "Lora not correctly set in UNet."
# forward pass with LoRA
with torch.no_grad():
lora_sample = model(**inputs_dict).sample
assert not torch.allclose(
non_lora_sample, lora_sample, atol=1e-4, rtol=1e-4
), "LoRA injected UNet should produce different results."
@require_peft_backend
def test_lora_serialization(self):
init_dict, inputs_dict = self.prepare_init_args_and_inputs_for_common()
model = self.model_class(**init_dict)
model.to(torch_device)
# forward pass without LoRA
with torch.no_grad():
non_lora_sample = model(**inputs_dict).sample
unet_lora_config = get_unet_lora_config()
model.add_adapter(unet_lora_config)
assert check_if_lora_correctly_set(model), "Lora not correctly set in UNet."
# forward pass with LoRA
with torch.no_grad():
lora_sample_1 = model(**inputs_dict).sample
with tempfile.TemporaryDirectory() as tmpdirname:
model.save_attn_procs(tmpdirname)
model.unload_lora()
model.load_attn_procs(os.path.join(tmpdirname, "pytorch_lora_weights.safetensors"))
assert check_if_lora_correctly_set(model), "Lora not correctly set in UNet."
with torch.no_grad():
lora_sample_2 = model(**inputs_dict).sample
assert not torch.allclose(
non_lora_sample, lora_sample_1, atol=1e-4, rtol=1e-4
), "LoRA injected UNet should produce different results."
assert torch.allclose(
lora_sample_1, lora_sample_2, atol=1e-4, rtol=1e-4
), "Loading from a saved checkpoint should produce identical results."
@slow
class UNet2DConditionModelIntegrationTests(unittest.TestCase):
def get_file_format(self, seed, shape):
return f"gaussian_noise_s={seed}_shape={'_'.join([str(s) for s in shape])}.npy"
def tearDown(self):
# clean up the VRAM after each test
super().tearDown()
gc.collect()
backend_empty_cache(torch_device)
def get_latents(self, seed=0, shape=(4, 4, 64, 64), fp16=False):
dtype = torch.float16 if fp16 else torch.float32
image = torch.from_numpy(load_hf_numpy(self.get_file_format(seed, shape))).to(torch_device).to(dtype)
return image
def get_unet_model(self, fp16=False, model_id="CompVis/stable-diffusion-v1-4"):
revision = "fp16" if fp16 else None
torch_dtype = torch.float16 if fp16 else torch.float32
model = UNet2DConditionModel.from_pretrained(
model_id, subfolder="unet", torch_dtype=torch_dtype, revision=revision
)
model.to(torch_device).eval()
return model
@require_torch_gpu
def test_set_attention_slice_auto(self):
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
unet = self.get_unet_model()
unet.set_attention_slice("auto")
latents = self.get_latents(33)
encoder_hidden_states = self.get_encoder_hidden_states(33)
timestep = 1
with torch.no_grad():
_ = unet(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
mem_bytes = torch.cuda.max_memory_allocated()
assert mem_bytes < 5 * 10**9
@require_torch_gpu
def test_set_attention_slice_max(self):
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
unet = self.get_unet_model()
unet.set_attention_slice("max")
latents = self.get_latents(33)
encoder_hidden_states = self.get_encoder_hidden_states(33)
timestep = 1
with torch.no_grad():
_ = unet(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
mem_bytes = torch.cuda.max_memory_allocated()
assert mem_bytes < 5 * 10**9
@require_torch_gpu
def test_set_attention_slice_int(self):
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
unet = self.get_unet_model()
unet.set_attention_slice(2)
latents = self.get_latents(33)
encoder_hidden_states = self.get_encoder_hidden_states(33)
timestep = 1
with torch.no_grad():
_ = unet(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
mem_bytes = torch.cuda.max_memory_allocated()
assert mem_bytes < 5 * 10**9
@require_torch_gpu
def test_set_attention_slice_list(self):
torch.cuda.empty_cache()
torch.cuda.reset_max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
# there are 32 sliceable layers
slice_list = 16 * [2, 3]
unet = self.get_unet_model()
unet.set_attention_slice(slice_list)
latents = self.get_latents(33)
encoder_hidden_states = self.get_encoder_hidden_states(33)
timestep = 1
with torch.no_grad():
_ = unet(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
mem_bytes = torch.cuda.max_memory_allocated()
assert mem_bytes < 5 * 10**9
def get_encoder_hidden_states(self, seed=0, shape=(4, 77, 768), fp16=False):
dtype = torch.float16 if fp16 else torch.float32
hidden_states = torch.from_numpy(load_hf_numpy(self.get_file_format(seed, shape))).to(torch_device).to(dtype)
return hidden_states
@parameterized.expand(
[
# fmt: off
[33, 4, [-0.4424, 0.1510, -0.1937, 0.2118, 0.3746, -0.3957, 0.0160, -0.0435]],
[47, 0.55, [-0.1508, 0.0379, -0.3075, 0.2540, 0.3633, -0.0821, 0.1719, -0.0207]],
[21, 0.89, [-0.6479, 0.6364, -0.3464, 0.8697, 0.4443, -0.6289, -0.0091, 0.1778]],
[9, 1000, [0.8888, -0.5659, 0.5834, -0.7469, 1.1912, -0.3923, 1.1241, -0.4424]],
# fmt: on
]
)
@require_torch_accelerator_with_fp16
def test_compvis_sd_v1_4(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4")
latents = self.get_latents(seed)
encoder_hidden_states = self.get_encoder_hidden_states(seed)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == latents.shape
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=1e-3)
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2323, -0.1304, 0.0813, -0.3093, -0.0919, -0.1571, -0.1125, -0.5806]],
[17, 0.55, [-0.0831, -0.2443, 0.0901, -0.0919, 0.3396, 0.0103, -0.3743, 0.0701]],
[8, 0.89, [-0.4863, 0.0859, 0.0875, -0.1658, 0.9199, -0.0114, 0.4839, 0.4639]],
[3, 1000, [-0.5649, 0.2402, -0.5518, 0.1248, 1.1328, -0.2443, -0.0325, -1.0078]],
# fmt: on
]
)
@require_torch_accelerator_with_fp16
def test_compvis_sd_v1_4_fp16(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="CompVis/stable-diffusion-v1-4", fp16=True)
latents = self.get_latents(seed, fp16=True)
encoder_hidden_states = self.get_encoder_hidden_states(seed, fp16=True)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == latents.shape
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=5e-3)
@parameterized.expand(
[
# fmt: off
[33, 4, [-0.4430, 0.1570, -0.1867, 0.2376, 0.3205, -0.3681, 0.0525, -0.0722]],
[47, 0.55, [-0.1415, 0.0129, -0.3136, 0.2257, 0.3430, -0.0536, 0.2114, -0.0436]],
[21, 0.89, [-0.7091, 0.6664, -0.3643, 0.9032, 0.4499, -0.6541, 0.0139, 0.1750]],
[9, 1000, [0.8878, -0.5659, 0.5844, -0.7442, 1.1883, -0.3927, 1.1192, -0.4423]],
# fmt: on
]
)
@require_torch_accelerator
@skip_mps
def test_compvis_sd_v1_5(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="runwayml/stable-diffusion-v1-5")
latents = self.get_latents(seed)
encoder_hidden_states = self.get_encoder_hidden_states(seed)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == latents.shape
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=1e-3)
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.2695, -0.1669, 0.0073, -0.3181, -0.1187, -0.1676, -0.1395, -0.5972]],
[17, 0.55, [-0.1290, -0.2588, 0.0551, -0.0916, 0.3286, 0.0238, -0.3669, 0.0322]],
[8, 0.89, [-0.5283, 0.1198, 0.0870, -0.1141, 0.9189, -0.0150, 0.5474, 0.4319]],
[3, 1000, [-0.5601, 0.2411, -0.5435, 0.1268, 1.1338, -0.2427, -0.0280, -1.0020]],
# fmt: on
]
)
@require_torch_accelerator_with_fp16
def test_compvis_sd_v1_5_fp16(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="runwayml/stable-diffusion-v1-5", fp16=True)
latents = self.get_latents(seed, fp16=True)
encoder_hidden_states = self.get_encoder_hidden_states(seed, fp16=True)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == latents.shape
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=5e-3)
@parameterized.expand(
[
# fmt: off
[33, 4, [-0.7639, 0.0106, -0.1615, -0.3487, -0.0423, -0.7972, 0.0085, -0.4858]],
[47, 0.55, [-0.6564, 0.0795, -1.9026, -0.6258, 1.8235, 1.2056, 1.2169, 0.9073]],
[21, 0.89, [0.0327, 0.4399, -0.6358, 0.3417, 0.4120, -0.5621, -0.0397, -1.0430]],
[9, 1000, [0.1600, 0.7303, -1.0556, -0.3515, -0.7440, -1.2037, -1.8149, -1.8931]],
# fmt: on
]
)
@require_torch_accelerator
@skip_mps
def test_compvis_sd_inpaint(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="runwayml/stable-diffusion-inpainting")
latents = self.get_latents(seed, shape=(4, 9, 64, 64))
encoder_hidden_states = self.get_encoder_hidden_states(seed)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == (4, 4, 64, 64)
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=3e-3)
@parameterized.expand(
[
# fmt: off
[83, 4, [-0.1047, -1.7227, 0.1067, 0.0164, -0.5698, -0.4172, -0.1388, 1.1387]],
[17, 0.55, [0.0975, -0.2856, -0.3508, -0.4600, 0.3376, 0.2930, -0.2747, -0.7026]],
[8, 0.89, [-0.0952, 0.0183, -0.5825, -0.1981, 0.1131, 0.4668, -0.0395, -0.3486]],
[3, 1000, [0.4790, 0.4949, -1.0732, -0.7158, 0.7959, -0.9478, 0.1105, -0.9741]],
# fmt: on
]
)
@require_torch_accelerator_with_fp16
def test_compvis_sd_inpaint_fp16(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="runwayml/stable-diffusion-inpainting", fp16=True)
latents = self.get_latents(seed, shape=(4, 9, 64, 64), fp16=True)
encoder_hidden_states = self.get_encoder_hidden_states(seed, fp16=True)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == (4, 4, 64, 64)
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=5e-3)
@parameterized.expand(
[
# fmt: off
[83, 4, [0.1514, 0.0807, 0.1624, 0.1016, -0.1896, 0.0263, 0.0677, 0.2310]],
[17, 0.55, [0.1164, -0.0216, 0.0170, 0.1589, -0.3120, 0.1005, -0.0581, -0.1458]],
[8, 0.89, [-0.1758, -0.0169, 0.1004, -0.1411, 0.1312, 0.1103, -0.1996, 0.2139]],
[3, 1000, [0.1214, 0.0352, -0.0731, -0.1562, -0.0994, -0.0906, -0.2340, -0.0539]],
# fmt: on
]
)
@require_torch_accelerator_with_fp16
def test_stabilityai_sd_v2_fp16(self, seed, timestep, expected_slice):
model = self.get_unet_model(model_id="stabilityai/stable-diffusion-2", fp16=True)
latents = self.get_latents(seed, shape=(4, 4, 96, 96), fp16=True)
encoder_hidden_states = self.get_encoder_hidden_states(seed, shape=(4, 77, 1024), fp16=True)
timestep = torch.tensor([timestep], dtype=torch.long, device=torch_device)
with torch.no_grad():
sample = model(latents, timestep=timestep, encoder_hidden_states=encoder_hidden_states).sample
assert sample.shape == latents.shape
output_slice = sample[-1, -2:, -2:, :2].flatten().float().cpu()
expected_output_slice = torch.tensor(expected_slice)
assert torch_all_close(output_slice, expected_output_slice, atol=5e-3)