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theluyuan:main theluyuan:dev theluyuan:vram-bugfix theluyuan:docs2.0 theluyuan:cache_learning theluyuan:docs theluyuan:issue-fix theluyuan:examples-update theluyuan:zero3 theluyuan:loader-update theluyuan:z-image-release theluyuan:z-image-omni-base-dev theluyuan:z-imgae-omni-base theluyuan:zimagei2l theluyuan:ascend theluyuan:diffsynth-2.0 theluyuan:dpo-refined theluyuan:dpo theluyuan:qwen-image-interpolate theluyuan:blockwisecontrolnet theluyuan:qwen-image-acc-adapter theluyuan:qwen-image-controlnet-2 theluyuan:fp8 theluyuan:qwen-image-fp8 theluyuan:qwen-image-controlnet theluyuan:value-control theluyuan:lora-retrival theluyuan:refactor theluyuan:wan-refactor theluyuan:nexus-gen theluyuan:flux-ref theluyuan:wan-lora-format theluyuan:wan-models theluyuan:wanx_dev1 theluyuan:doc theluyuan:ExVideo
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3 Commits
v1.1.4 ... lora-retri

Author SHA1 Message Date
Artiprocher
50d2c86ae5 lora retrieval 2025-06-23 17:34:30 +08:00
Artiprocher
44da204dbd lora merger 2025-04-21 15:48:25 +08:00
lzw478614@alibaba-inc.com
04260801a2 support customized lora forward 2025-03-25 11:32:09 +08:00
14 changed files with 1131 additions and 126 deletions
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215
diffsynth/models/flux_dit.py
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@@ -41,6 +41,30 @@ class RoPEEmbedding(torch.nn.Module):
emb = torch.cat([self.rope(ids[..., i], self.axes_dim[i], self.theta) for i in range(n_axes)], dim=-3) emb = torch.cat([self.rope(ids[..., i], self.axes_dim[i], self.theta) for i in range(n_axes)], dim=-3)
return emb.unsqueeze(1) return emb.unsqueeze(1)
class AdaLayerNorm(torch.nn.Module):
def __init__(self, dim, single=False, dual=False):
super().__init__()
self.single = single
self.dual = dual
self.linear = torch.nn.Linear(dim, dim * [[6, 2][single], 9][dual])
self.norm = torch.nn.LayerNorm(dim, elementwise_affine=False, eps=1e-6)
def forward(self, x, emb, **kwargs):
emb = self.linear(torch.nn.functional.silu(emb),**kwargs)
if self.single:
scale, shift = emb.unsqueeze(1).chunk(2, dim=2)
x = self.norm(x) * (1 + scale) + shift
return x
elif self.dual:
shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp, shift_msa2, scale_msa2, gate_msa2 = emb.unsqueeze(1).chunk(9, dim=2)
norm_x = self.norm(x)
x = norm_x * (1 + scale_msa) + shift_msa
norm_x2 = norm_x * (1 + scale_msa2) + shift_msa2
return x, gate_msa, shift_mlp, scale_mlp, gate_mlp, norm_x2, gate_msa2
else:
shift_msa, scale_msa, gate_msa, shift_mlp, scale_mlp, gate_mlp = emb.unsqueeze(1).chunk(6, dim=2)
x = self.norm(x) * (1 + scale_msa) + shift_msa
return x, gate_msa, shift_mlp, scale_mlp, gate_mlp
class FluxJointAttention(torch.nn.Module): class FluxJointAttention(torch.nn.Module):
@@ -70,17 +94,17 @@ class FluxJointAttention(torch.nn.Module):
xk_out = freqs_cis[..., 0] * xk_[..., 0] + freqs_cis[..., 1] * xk_[..., 1] xk_out = freqs_cis[..., 0] * xk_[..., 0] + freqs_cis[..., 1] * xk_[..., 1]
return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk) return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk)
def forward(self, hidden_states_a, hidden_states_b, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None): def forward(self, hidden_states_a, hidden_states_b, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None, **kwargs):
batch_size = hidden_states_a.shape[0] batch_size = hidden_states_a.shape[0]
# Part A # Part A
qkv_a = self.a_to_qkv(hidden_states_a) qkv_a = self.a_to_qkv(hidden_states_a,**kwargs)
qkv_a = qkv_a.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2) qkv_a = qkv_a.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2)
q_a, k_a, v_a = qkv_a.chunk(3, dim=1) q_a, k_a, v_a = qkv_a.chunk(3, dim=1)
q_a, k_a = self.norm_q_a(q_a), self.norm_k_a(k_a) q_a, k_a = self.norm_q_a(q_a), self.norm_k_a(k_a)
# Part B # Part B
qkv_b = self.b_to_qkv(hidden_states_b) qkv_b = self.b_to_qkv(hidden_states_b,**kwargs)
qkv_b = qkv_b.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2) qkv_b = qkv_b.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2)
q_b, k_b, v_b = qkv_b.chunk(3, dim=1) q_b, k_b, v_b = qkv_b.chunk(3, dim=1)
q_b, k_b = self.norm_q_b(q_b), self.norm_k_b(k_b) q_b, k_b = self.norm_q_b(q_b), self.norm_k_b(k_b)
@@ -97,13 +121,25 @@ class FluxJointAttention(torch.nn.Module):
hidden_states_b, hidden_states_a = hidden_states[:, :hidden_states_b.shape[1]], hidden_states[:, hidden_states_b.shape[1]:] hidden_states_b, hidden_states_a = hidden_states[:, :hidden_states_b.shape[1]], hidden_states[:, hidden_states_b.shape[1]:]
if ipadapter_kwargs_list is not None: if ipadapter_kwargs_list is not None:
hidden_states_a = interact_with_ipadapter(hidden_states_a, q_a, **ipadapter_kwargs_list) hidden_states_a = interact_with_ipadapter(hidden_states_a, q_a, **ipadapter_kwargs_list)
hidden_states_a = self.a_to_out(hidden_states_a) hidden_states_a = self.a_to_out(hidden_states_a,**kwargs)
if self.only_out_a: if self.only_out_a:
return hidden_states_a return hidden_states_a
else: else:
hidden_states_b = self.b_to_out(hidden_states_b) hidden_states_b = self.b_to_out(hidden_states_b,**kwargs)
return hidden_states_a, hidden_states_b return hidden_states_a, hidden_states_b
class AutoSequential(torch.nn.Sequential):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
def forward(self, input, **kwargs):
for module in self:
if isinstance(module, torch.nn.Linear):
# print("##"*10)
input = module(input, **kwargs)
else:
input = module(input)
return input
class FluxJointTransformerBlock(torch.nn.Module): class FluxJointTransformerBlock(torch.nn.Module):
@@ -120,6 +156,11 @@ class FluxJointTransformerBlock(torch.nn.Module):
torch.nn.GELU(approximate="tanh"), torch.nn.GELU(approximate="tanh"),
torch.nn.Linear(dim*4, dim) torch.nn.Linear(dim*4, dim)
) )
# self.ff_a = AutoSequential(
# torch.nn.Linear(dim, dim*4),
# torch.nn.GELU(approximate="tanh"),
# torch.nn.Linear(dim*4, dim)
# )
self.norm2_b = torch.nn.LayerNorm(dim, elementwise_affine=False, eps=1e-6) self.norm2_b = torch.nn.LayerNorm(dim, elementwise_affine=False, eps=1e-6)
self.ff_b = torch.nn.Sequential( self.ff_b = torch.nn.Sequential(
@@ -127,14 +168,18 @@ class FluxJointTransformerBlock(torch.nn.Module):
torch.nn.GELU(approximate="tanh"), torch.nn.GELU(approximate="tanh"),
torch.nn.Linear(dim*4, dim) torch.nn.Linear(dim*4, dim)
) )
# self.ff_b = AutoSequential(
# torch.nn.Linear(dim, dim*4),
# torch.nn.GELU(approximate="tanh"),
# torch.nn.Linear(dim*4, dim)
# )
def forward(self, hidden_states_a, hidden_states_b, temb, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None, **kwargs):
def forward(self, hidden_states_a, hidden_states_b, temb, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None): norm_hidden_states_a, gate_msa_a, shift_mlp_a, scale_mlp_a, gate_mlp_a = self.norm1_a(hidden_states_a, emb=temb, **kwargs)
norm_hidden_states_a, gate_msa_a, shift_mlp_a, scale_mlp_a, gate_mlp_a = self.norm1_a(hidden_states_a, emb=temb) norm_hidden_states_b, gate_msa_b, shift_mlp_b, scale_mlp_b, gate_mlp_b = self.norm1_b(hidden_states_b, emb=temb, **kwargs)
norm_hidden_states_b, gate_msa_b, shift_mlp_b, scale_mlp_b, gate_mlp_b = self.norm1_b(hidden_states_b, emb=temb)
# Attention # Attention
attn_output_a, attn_output_b = self.attn(norm_hidden_states_a, norm_hidden_states_b, image_rotary_emb, attn_mask, ipadapter_kwargs_list) attn_output_a, attn_output_b = self.attn(norm_hidden_states_a, norm_hidden_states_b, image_rotary_emb, attn_mask, ipadapter_kwargs_list, **kwargs)
# Part A # Part A
hidden_states_a = hidden_states_a + gate_msa_a * attn_output_a hidden_states_a = hidden_states_a + gate_msa_a * attn_output_a
@@ -149,7 +194,6 @@ class FluxJointTransformerBlock(torch.nn.Module):
return hidden_states_a, hidden_states_b return hidden_states_a, hidden_states_b
class FluxSingleAttention(torch.nn.Module): class FluxSingleAttention(torch.nn.Module):
def __init__(self, dim_a, dim_b, num_heads, head_dim): def __init__(self, dim_a, dim_b, num_heads, head_dim):
super().__init__() super().__init__()
@@ -170,10 +214,10 @@ class FluxSingleAttention(torch.nn.Module):
return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk) return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk)
def forward(self, hidden_states, image_rotary_emb): def forward(self, hidden_states, image_rotary_emb, **kwargs):
batch_size = hidden_states.shape[0] batch_size = hidden_states.shape[0]
qkv_a = self.a_to_qkv(hidden_states) qkv_a = self.a_to_qkv(hidden_states,**kwargs)
qkv_a = qkv_a.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2) qkv_a = qkv_a.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2)
q_a, k_a, v = qkv_a.chunk(3, dim=1) q_a, k_a, v = qkv_a.chunk(3, dim=1)
q_a, k_a = self.norm_q_a(q_a), self.norm_k_a(k_a) q_a, k_a = self.norm_q_a(q_a), self.norm_k_a(k_a)
@@ -195,8 +239,8 @@ class AdaLayerNormSingle(torch.nn.Module):
self.norm = torch.nn.LayerNorm(dim, elementwise_affine=False, eps=1e-6) self.norm = torch.nn.LayerNorm(dim, elementwise_affine=False, eps=1e-6)
def forward(self, x, emb): def forward(self, x, emb, **kwargs):
emb = self.linear(self.silu(emb)) emb = self.linear(self.silu(emb),**kwargs)
shift_msa, scale_msa, gate_msa = emb.chunk(3, dim=1) shift_msa, scale_msa, gate_msa = emb.chunk(3, dim=1)
x = self.norm(x) * (1 + scale_msa[:, None]) + shift_msa[:, None] x = self.norm(x) * (1 + scale_msa[:, None]) + shift_msa[:, None]
return x, gate_msa return x, gate_msa
@@ -226,7 +270,7 @@ class FluxSingleTransformerBlock(torch.nn.Module):
return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk) return xq_out.reshape(*xq.shape).type_as(xq), xk_out.reshape(*xk.shape).type_as(xk)
def process_attention(self, hidden_states, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None): def process_attention(self, hidden_states, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None, **kwargs):
batch_size = hidden_states.shape[0] batch_size = hidden_states.shape[0]
qkv = hidden_states.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2) qkv = hidden_states.view(batch_size, -1, 3 * self.num_heads, self.head_dim).transpose(1, 2)
@@ -243,17 +287,17 @@ class FluxSingleTransformerBlock(torch.nn.Module):
return hidden_states return hidden_states
def forward(self, hidden_states_a, hidden_states_b, temb, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None): def forward(self, hidden_states_a, hidden_states_b, temb, image_rotary_emb, attn_mask=None, ipadapter_kwargs_list=None, **kwargs):
residual = hidden_states_a residual = hidden_states_a
norm_hidden_states, gate = self.norm(hidden_states_a, emb=temb) norm_hidden_states, gate = self.norm(hidden_states_a, emb=temb, **kwargs)
hidden_states_a = self.to_qkv_mlp(norm_hidden_states) hidden_states_a = self.to_qkv_mlp(norm_hidden_states, **kwargs)
attn_output, mlp_hidden_states = hidden_states_a[:, :, :self.dim * 3], hidden_states_a[:, :, self.dim * 3:] attn_output, mlp_hidden_states = hidden_states_a[:, :, :self.dim * 3], hidden_states_a[:, :, self.dim * 3:]
attn_output = self.process_attention(attn_output, image_rotary_emb, attn_mask, ipadapter_kwargs_list) attn_output = self.process_attention(attn_output, image_rotary_emb, attn_mask, ipadapter_kwargs_list, **kwargs)
mlp_hidden_states = torch.nn.functional.gelu(mlp_hidden_states, approximate="tanh") mlp_hidden_states = torch.nn.functional.gelu(mlp_hidden_states, approximate="tanh")
hidden_states_a = torch.cat([attn_output, mlp_hidden_states], dim=2) hidden_states_a = torch.cat([attn_output, mlp_hidden_states], dim=2)
hidden_states_a = gate.unsqueeze(1) * self.proj_out(hidden_states_a) hidden_states_a = gate.unsqueeze(1) * self.proj_out(hidden_states_a, **kwargs)
hidden_states_a = residual + hidden_states_a hidden_states_a = residual + hidden_states_a
return hidden_states_a, hidden_states_b return hidden_states_a, hidden_states_b
@@ -267,14 +311,13 @@ class AdaLayerNormContinuous(torch.nn.Module):
self.linear = torch.nn.Linear(dim, dim * 2, bias=True) self.linear = torch.nn.Linear(dim, dim * 2, bias=True)
self.norm = torch.nn.LayerNorm(dim, eps=1e-6, elementwise_affine=False) self.norm = torch.nn.LayerNorm(dim, eps=1e-6, elementwise_affine=False)
def forward(self, x, conditioning): def forward(self, x, conditioning, **kwargs):
emb = self.linear(self.silu(conditioning)) emb = self.linear(self.silu(conditioning),**kwargs)
scale, shift = torch.chunk(emb, 2, dim=1) scale, shift = torch.chunk(emb, 2, dim=1)
x = self.norm(x) * (1 + scale)[:, None] + shift[:, None] x = self.norm(x) * (1 + scale)[:, None] + shift[:, None]
return x return x
class FluxDiT(torch.nn.Module): class FluxDiT(torch.nn.Module):
def __init__(self, disable_guidance_embedder=False): def __init__(self, disable_guidance_embedder=False):
super().__init__() super().__init__()
@@ -282,6 +325,8 @@ class FluxDiT(torch.nn.Module):
self.time_embedder = TimestepEmbeddings(256, 3072) self.time_embedder = TimestepEmbeddings(256, 3072)
self.guidance_embedder = None if disable_guidance_embedder else TimestepEmbeddings(256, 3072) self.guidance_embedder = None if disable_guidance_embedder else TimestepEmbeddings(256, 3072)
self.pooled_text_embedder = torch.nn.Sequential(torch.nn.Linear(768, 3072), torch.nn.SiLU(), torch.nn.Linear(3072, 3072)) self.pooled_text_embedder = torch.nn.Sequential(torch.nn.Linear(768, 3072), torch.nn.SiLU(), torch.nn.Linear(3072, 3072))
# self.pooled_text_embedder = AutoSequential(torch.nn.Linear(768, 3072), torch.nn.SiLU(), torch.nn.Linear(3072, 3072))
self.context_embedder = torch.nn.Linear(4096, 3072) self.context_embedder = torch.nn.Linear(4096, 3072)
self.x_embedder = torch.nn.Linear(64, 3072) self.x_embedder = torch.nn.Linear(64, 3072)
@@ -428,12 +473,12 @@ class FluxDiT(torch.nn.Module):
height, width = hidden_states.shape[-2:] height, width = hidden_states.shape[-2:]
hidden_states = self.patchify(hidden_states) hidden_states = self.patchify(hidden_states)
hidden_states = self.x_embedder(hidden_states) hidden_states = self.x_embedder(hidden_states,**kwargs)
if entity_prompt_emb is not None and entity_masks is not None: if entity_prompt_emb is not None and entity_masks is not None:
prompt_emb, image_rotary_emb, attention_mask = self.process_entity_masks(hidden_states, prompt_emb, entity_prompt_emb, entity_masks, text_ids, image_ids) prompt_emb, image_rotary_emb, attention_mask = self.process_entity_masks(hidden_states, prompt_emb, entity_prompt_emb, entity_masks, text_ids, image_ids)
else: else:
prompt_emb = self.context_embedder(prompt_emb) prompt_emb = self.context_embedder(prompt_emb, **kwargs)
image_rotary_emb = self.pos_embedder(torch.cat((text_ids, image_ids), dim=1)) image_rotary_emb = self.pos_embedder(torch.cat((text_ids, image_ids), dim=1))
attention_mask = None attention_mask = None
@@ -446,26 +491,26 @@ class FluxDiT(torch.nn.Module):
if self.training and use_gradient_checkpointing: if self.training and use_gradient_checkpointing:
hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint( hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint(
create_custom_forward(block), create_custom_forward(block),
hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, **kwargs,
use_reentrant=False, use_reentrant=False,
) )
else: else:
hidden_states, prompt_emb = block(hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask) hidden_states, prompt_emb = block(hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, **kwargs)
hidden_states = torch.cat([prompt_emb, hidden_states], dim=1) hidden_states = torch.cat([prompt_emb, hidden_states], dim=1)
for block in self.single_blocks: for block in self.single_blocks:
if self.training and use_gradient_checkpointing: if self.training and use_gradient_checkpointing:
hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint( hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint(
create_custom_forward(block), create_custom_forward(block),
hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, **kwargs,
use_reentrant=False, use_reentrant=False,
) )
else: else:
hidden_states, prompt_emb = block(hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask) hidden_states, prompt_emb = block(hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, **kwargs)
hidden_states = hidden_states[:, prompt_emb.shape[1]:] hidden_states = hidden_states[:, prompt_emb.shape[1]:]
hidden_states = self.final_norm_out(hidden_states, conditioning) hidden_states = self.final_norm_out(hidden_states, conditioning, **kwargs)
hidden_states = self.final_proj_out(hidden_states) hidden_states = self.final_proj_out(hidden_states, **kwargs)
hidden_states = self.unpatchify(hidden_states, height, width) hidden_states = self.unpatchify(hidden_states, height, width)
return hidden_states return hidden_states
@@ -606,6 +651,10 @@ class FluxDiTStateDictConverter:
for name, param in state_dict.items(): for name, param in state_dict.items():
if name.endswith(".weight") or name.endswith(".bias"): if name.endswith(".weight") or name.endswith(".bias"):
suffix = ".weight" if name.endswith(".weight") else ".bias" suffix = ".weight" if name.endswith(".weight") else ".bias"
if "lora_B" in name:
suffix = ".lora_B" + suffix
if "lora_A" in name:
suffix = ".lora_A" + suffix
prefix = name[:-len(suffix)] prefix = name[:-len(suffix)]
if prefix in global_rename_dict: if prefix in global_rename_dict:
state_dict_[global_rename_dict[prefix] + suffix] = param state_dict_[global_rename_dict[prefix] + suffix] = param
@@ -630,29 +679,73 @@ class FluxDiTStateDictConverter:
for name in list(state_dict_.keys()): for name in list(state_dict_.keys()):
if "single_blocks." in name and ".a_to_q." in name: if "single_blocks." in name and ".a_to_q." in name:
mlp = state_dict_.get(name.replace(".a_to_q.", ".proj_in_besides_attn."), None) mlp = state_dict_.get(name.replace(".a_to_q.", ".proj_in_besides_attn."), None)
if mlp is None: if mlp is None:
mlp = torch.zeros(4 * state_dict_[name].shape[0], dim = 4
if 'lora_A' in name:
dim = 1
mlp = torch.zeros(dim * state_dict_[name].shape[0],
*state_dict_[name].shape[1:], *state_dict_[name].shape[1:],
dtype=state_dict_[name].dtype) dtype=state_dict_[name].dtype)
else: else:
# print('$$'*10)
# mlp_name = name.replace(".a_to_q.", ".proj_in_besides_attn.")
# print(f'mlp name: {mlp_name}')
# print(f'mlp shape: {mlp.shape}')
state_dict_.pop(name.replace(".a_to_q.", ".proj_in_besides_attn.")) state_dict_.pop(name.replace(".a_to_q.", ".proj_in_besides_attn."))
param = torch.concat([ # print(f'mlp shape: {mlp.shape}')
state_dict_.pop(name), if 'lora_A' in name:
state_dict_.pop(name.replace(".a_to_q.", ".a_to_k.")),
state_dict_.pop(name.replace(".a_to_q.", ".a_to_v.")), param = torch.concat([
mlp, state_dict_.pop(name),
], dim=0) state_dict_.pop(name.replace(".a_to_q.", ".a_to_k.")),
state_dict_.pop(name.replace(".a_to_q.", ".a_to_v.")),
mlp,
], dim=0)
elif 'lora_B' in name:
# create zreo matrix
d, r = state_dict_[name].shape
# print('--'*10)
# print(d, r)
param = torch.zeros((3*d+mlp.shape[0], 3*r+mlp.shape[1]), dtype=state_dict_[name].dtype, device=state_dict_[name].device)
param[:d, :r] = state_dict_.pop(name)
param[d:2*d, r:2*r] = state_dict_.pop(name.replace(".a_to_q.", ".a_to_k."))
param[2*d:3*d, 2*r:3*r] = state_dict_.pop(name.replace(".a_to_q.", ".a_to_v."))
param[3*d:, 3*r:] = mlp
else:
param = torch.concat([
state_dict_.pop(name),
state_dict_.pop(name.replace(".a_to_q.", ".a_to_k.")),
state_dict_.pop(name.replace(".a_to_q.", ".a_to_v.")),
mlp,
], dim=0)
name_ = name.replace(".a_to_q.", ".to_qkv_mlp.") name_ = name.replace(".a_to_q.", ".to_qkv_mlp.")
state_dict_[name_] = param state_dict_[name_] = param
for name in list(state_dict_.keys()): for name in list(state_dict_.keys()):
for component in ["a", "b"]: for component in ["a", "b"]:
if f".{component}_to_q." in name: if f".{component}_to_q." in name:
name_ = name.replace(f".{component}_to_q.", f".{component}_to_qkv.") name_ = name.replace(f".{component}_to_q.", f".{component}_to_qkv.")
param = torch.concat([ concat_dim = 0
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_q.")], if 'lora_A' in name:
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_k.")], param = torch.concat([
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_v.")], state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_q.")],
], dim=0) state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_k.")],
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_v.")],
], dim=0)
elif 'lora_B' in name:
origin = state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_q.")]
d, r = origin.shape
# print(d, r)
param = torch.zeros((3*d, 3*r), dtype=origin.dtype, device=origin.device)
param[:d, :r] = state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_q.")]
param[d:2*d, r:2*r] = state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_k.")]
param[2*d:3*d, 2*r:3*r] = state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_v.")]
else:
param = torch.concat([
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_q.")],
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_k.")],
state_dict_[name.replace(f".{component}_to_q.", f".{component}_to_v.")],
], dim=0)
state_dict_[name_] = param state_dict_[name_] = param
state_dict_.pop(name.replace(f".{component}_to_q.", f".{component}_to_q.")) state_dict_.pop(name.replace(f".{component}_to_q.", f".{component}_to_q."))
state_dict_.pop(name.replace(f".{component}_to_q.", f".{component}_to_k.")) state_dict_.pop(name.replace(f".{component}_to_q.", f".{component}_to_k."))
@@ -718,22 +811,48 @@ class FluxDiTStateDictConverter:
"norm.query_norm.scale": "norm_q_a.weight", "norm.query_norm.scale": "norm_q_a.weight",
} }
state_dict_ = {} state_dict_ = {}
for name, param in state_dict.items(): for name, param in state_dict.items():
# match lora load
l_name = ''
if 'lora_A' in name :
l_name = 'lora_A'
if 'lora_B' in name :
l_name = 'lora_B'
if l_name != '':
name = name.replace(l_name+'.', '')
if name.startswith("model.diffusion_model."): if name.startswith("model.diffusion_model."):
name = name[len("model.diffusion_model."):] name = name[len("model.diffusion_model."):]
names = name.split(".") names = name.split(".")
if name in rename_dict: if name in rename_dict:
rename = rename_dict[name] rename = rename_dict[name]
if name.startswith("final_layer.adaLN_modulation.1."): if name.startswith("final_layer.adaLN_modulation.1."):
param = torch.concat([param[3072:], param[:3072]], dim=0) if l_name == 'lora_A':
state_dict_[rename] = param param = torch.concat([param[:,3072:], param[:,:3072]], dim=1)
else:
param = torch.concat([param[3072:], param[:3072]], dim=0)
if l_name != '':
state_dict_[rename.replace('weight',l_name+'.weight')] = param
else:
state_dict_[rename] = param
elif names[0] == "double_blocks": elif names[0] == "double_blocks":
rename = f"blocks.{names[1]}." + suffix_rename_dict[".".join(names[2:])] rename = f"blocks.{names[1]}." + suffix_rename_dict[".".join(names[2:])]
state_dict_[rename] = param if l_name != '':
state_dict_[rename.replace('weight',l_name+'.weight')] = param
else:
state_dict_[rename] = param
elif names[0] == "single_blocks": elif names[0] == "single_blocks":
if ".".join(names[2:]) in suffix_rename_dict: if ".".join(names[2:]) in suffix_rename_dict:
rename = f"single_blocks.{names[1]}." + suffix_rename_dict[".".join(names[2:])] rename = f"single_blocks.{names[1]}." + suffix_rename_dict[".".join(names[2:])]
state_dict_[rename] = param if l_name != '':
state_dict_[rename.replace('weight',l_name+'.weight')] = param
else:
state_dict_[rename] = param
else: else:
pass pass
if "guidance_embedder.timestep_embedder.0.weight" not in state_dict_: if "guidance_embedder.timestep_embedder.0.weight" not in state_dict_:

205
diffsynth/models/lora.py
View File

@@ -26,6 +26,12 @@ class LoRAFromCivitai:
return self.convert_state_dict_up_down(state_dict, lora_prefix, alpha) return self.convert_state_dict_up_down(state_dict, lora_prefix, alpha)
return self.convert_state_dict_AB(state_dict, lora_prefix, alpha) return self.convert_state_dict_AB(state_dict, lora_prefix, alpha)
def convert_state_name(self, state_dict, lora_prefix="lora_unet_", alpha=1.0):
for key in state_dict:
if ".lora_up" in key:
return self.convert_state_name_up_down(state_dict, lora_prefix, alpha)
return self.convert_state_name_AB(state_dict, lora_prefix, alpha)
def convert_state_dict_up_down(self, state_dict, lora_prefix="lora_unet_", alpha=1.0): def convert_state_dict_up_down(self, state_dict, lora_prefix="lora_unet_", alpha=1.0):
renamed_lora_prefix = self.renamed_lora_prefix.get(lora_prefix, "") renamed_lora_prefix = self.renamed_lora_prefix.get(lora_prefix, "")
@@ -50,13 +56,37 @@ class LoRAFromCivitai:
return state_dict_ return state_dict_
def convert_state_name_up_down(self, state_dict, lora_prefix="lora_unet_", alpha=1.0):
renamed_lora_prefix = self.renamed_lora_prefix.get(lora_prefix, "")
state_dict_ = {}
for key in state_dict:
if ".lora_up" not in key:
continue
if not key.startswith(lora_prefix):
continue
weight_up = state_dict[key].to(device="cuda", dtype=torch.float16)
weight_down = state_dict[key.replace(".lora_up", ".lora_down")].to(device="cuda", dtype=torch.float16)
if len(weight_up.shape) == 4:
weight_up = weight_up.squeeze(3).squeeze(2).to(torch.float32)
weight_down = weight_down.squeeze(3).squeeze(2).to(torch.float32)
target_name = key.split(".")[0].replace(lora_prefix, renamed_lora_prefix).replace("_", ".") + ".weight"
for special_key in self.special_keys:
target_name = target_name.replace(special_key, self.special_keys[special_key])
state_dict_[target_name.replace(".weight",".lora_B.weight")] = weight_up.cpu()
state_dict_[target_name.replace(".weight",".lora_A.weight")] = weight_down.cpu()
return state_dict_
def convert_state_dict_AB(self, state_dict, lora_prefix="", alpha=1.0, device="cuda", torch_dtype=torch.float16): def convert_state_dict_AB(self, state_dict, lora_prefix="", alpha=1.0, device="cuda", torch_dtype=torch.float16):
state_dict_ = {} state_dict_ = {}
for key in state_dict: for key in state_dict:
if ".lora_B." not in key: if ".lora_B." not in key:
continue continue
if not key.startswith(lora_prefix): if not key.startswith(lora_prefix):
continue continue
weight_up = state_dict[key].to(device=device, dtype=torch_dtype) weight_up = state_dict[key].to(device=device, dtype=torch_dtype)
weight_down = state_dict[key.replace(".lora_B.", ".lora_A.")].to(device=device, dtype=torch_dtype) weight_down = state_dict[key.replace(".lora_B.", ".lora_A.")].to(device=device, dtype=torch_dtype)
if len(weight_up.shape) == 4: if len(weight_up.shape) == 4:
@@ -67,11 +97,39 @@ class LoRAFromCivitai:
lora_weight = alpha * torch.mm(weight_up, weight_down) lora_weight = alpha * torch.mm(weight_up, weight_down)
keys = key.split(".") keys = key.split(".")
keys.pop(keys.index("lora_B")) keys.pop(keys.index("lora_B"))
target_name = ".".join(keys) target_name = ".".join(keys)
target_name = target_name[len(lora_prefix):] target_name = target_name[len(lora_prefix):]
state_dict_[target_name] = lora_weight.cpu() state_dict_[target_name] = lora_weight.cpu()
return state_dict_ return state_dict_
def convert_state_name_AB(self, state_dict, lora_prefix="", alpha=1.0, device="cuda", torch_dtype=torch.float16):
state_dict_ = {}
for key in state_dict:
if ".lora_B." not in key:
continue
if not key.startswith(lora_prefix):
continue
weight_up = state_dict[key].to(device=device, dtype=torch_dtype)
weight_down = state_dict[key.replace(".lora_B.", ".lora_A.")].to(device=device, dtype=torch_dtype)
if len(weight_up.shape) == 4:
weight_up = weight_up.squeeze(3).squeeze(2)
weight_down = weight_down.squeeze(3).squeeze(2)
keys = key.split(".")
keys.pop(keys.index("lora_B"))
target_name = ".".join(keys)
target_name = target_name[len(lora_prefix):]
state_dict_[target_name.replace(".weight",".lora_B.weight")] = weight_up.cpu()
state_dict_[target_name.replace(".weight",".lora_A.weight")] = weight_down.cpu()
return state_dict_
def load(self, model, state_dict_lora, lora_prefix, alpha=1.0, model_resource=None): def load(self, model, state_dict_lora, lora_prefix, alpha=1.0, model_resource=None):
state_dict_model = model.state_dict() state_dict_model = model.state_dict()
@@ -100,13 +158,16 @@ class LoRAFromCivitai:
for lora_prefix, model_class in zip(self.lora_prefix, self.supported_model_classes): for lora_prefix, model_class in zip(self.lora_prefix, self.supported_model_classes):
if not isinstance(model, model_class): if not isinstance(model, model_class):
continue continue
# print(f'lora_prefix: {lora_prefix}')
state_dict_model = model.state_dict() state_dict_model = model.state_dict()
for model_resource in ["diffusers", "civitai"]: for model_resource in ["diffusers", "civitai"]:
try: try:
state_dict_lora_ = self.convert_state_dict(state_dict_lora, lora_prefix=lora_prefix, alpha=1.0) state_dict_lora_ = self.convert_state_dict(state_dict_lora, lora_prefix=lora_prefix, alpha=1.0)
# print(f'after convert_state_dict lora state_dict:{state_dict_lora_.keys()}')
converter_fn = model.__class__.state_dict_converter().from_diffusers if model_resource == "diffusers" \ converter_fn = model.__class__.state_dict_converter().from_diffusers if model_resource == "diffusers" \
else model.__class__.state_dict_converter().from_civitai else model.__class__.state_dict_converter().from_civitai
state_dict_lora_ = converter_fn(state_dict_lora_) state_dict_lora_ = converter_fn(state_dict_lora_)
# print(f'after converter_fn lora state_dict:{state_dict_lora_.keys()}')
if isinstance(state_dict_lora_, tuple): if isinstance(state_dict_lora_, tuple):
state_dict_lora_ = state_dict_lora_[0] state_dict_lora_ = state_dict_lora_[0]
if len(state_dict_lora_) == 0: if len(state_dict_lora_) == 0:
@@ -120,7 +181,35 @@ class LoRAFromCivitai:
pass pass
return None return None
def get_converted_lora_state_dict(self, model, state_dict_lora):
for lora_prefix, model_class in zip(self.lora_prefix, self.supported_model_classes):
if not isinstance(model, model_class):
continue
state_dict_model = model.state_dict()
for model_resource in ["diffusers","civitai"]:
try:
state_dict_lora_ = self.convert_state_name(state_dict_lora, lora_prefix=lora_prefix, alpha=1.0)
converter_fn = model.__class__.state_dict_converter().from_diffusers if model_resource == 'diffusers' \
else model.__class__.state_dict_converter().from_civitai
state_dict_lora_ = converter_fn(state_dict_lora_)
if isinstance(state_dict_lora_, tuple):
state_dict_lora_ = state_dict_lora_[0]
if len(state_dict_lora_) == 0:
continue
# return state_dict_lora_
for name in state_dict_lora_:
if name.replace('.lora_B','').replace('.lora_A','') not in state_dict_model:
print(f" lora's {name} is not in model.")
break
else:
return state_dict_lora_
except Exception as e:
print(f"error {str(e)}")
return None
class SDLoRAFromCivitai(LoRAFromCivitai): class SDLoRAFromCivitai(LoRAFromCivitai):
def __init__(self): def __init__(self):
@@ -195,73 +284,85 @@ class FluxLoRAFromCivitai(LoRAFromCivitai):
"txt.mod": "txt_mod", "txt.mod": "txt_mod",
} }
class GeneralLoRAFromPeft: class GeneralLoRAFromPeft:
def __init__(self): def __init__(self):
self.supported_model_classes = [SDUNet, SDXLUNet, SD3DiT, HunyuanDiT, FluxDiT, CogDiT, WanModel] self.supported_model_classes = [SDUNet, SDXLUNet, SD3DiT, HunyuanDiT, FluxDiT, CogDiT, WanModel]
def get_name_dict(self, lora_state_dict): def fetch_device_dtype_from_state_dict(self, state_dict):
lora_name_dict = {} device, torch_dtype = None, None
for key in lora_state_dict: for name, param in state_dict.items():
device, torch_dtype = param.device, param.dtype
break
return device, torch_dtype
def convert_state_dict(self, state_dict, alpha=1.0, target_state_dict={}):
device, torch_dtype = self.fetch_device_dtype_from_state_dict(target_state_dict)
if torch_dtype == torch.float8_e4m3fn:
torch_dtype = torch.float32
state_dict_ = {}
for key in state_dict:
if ".lora_B." not in key: if ".lora_B." not in key:
continue continue
weight_up = state_dict[key].to(device=device, dtype=torch_dtype)
weight_down = state_dict[key.replace(".lora_B.", ".lora_A.")].to(device=device, dtype=torch_dtype)
if len(weight_up.shape) == 4:
weight_up = weight_up.squeeze(3).squeeze(2)
weight_down = weight_down.squeeze(3).squeeze(2)
lora_weight = alpha * torch.mm(weight_up, weight_down).unsqueeze(2).unsqueeze(3)
else:
lora_weight = alpha * torch.mm(weight_up, weight_down)
keys = key.split(".") keys = key.split(".")
if len(keys) > keys.index("lora_B") + 2: if len(keys) > keys.index("lora_B") + 2:
keys.pop(keys.index("lora_B") + 1) keys.pop(keys.index("lora_B") + 1)
keys.pop(keys.index("lora_B")) keys.pop(keys.index("lora_B"))
if keys[0] == "diffusion_model":
keys.pop(0)
target_name = ".".join(keys) target_name = ".".join(keys)
lora_name_dict[target_name] = (key, key.replace(".lora_B.", ".lora_A.")) if target_name.startswith("diffusion_model."):
return lora_name_dict target_name = target_name[len("diffusion_model."):]
if target_name not in target_state_dict:
return {}
state_dict_[target_name] = lora_weight.cpu()
return state_dict_
def match(self, model: torch.nn.Module, state_dict_lora):
lora_name_dict = self.get_name_dict(state_dict_lora)
model_name_dict = {name: None for name, _ in model.named_parameters()}
matched_num = sum([i in model_name_dict for i in lora_name_dict])
if matched_num == len(lora_name_dict):
return "", ""
else:
return None
def fetch_device_and_dtype(self, state_dict):
device, dtype = None, None
for name, param in state_dict.items():
device, dtype = param.device, param.dtype
break
computation_device = device
computation_dtype = dtype
if computation_device == torch.device("cpu"):
if torch.cuda.is_available():
computation_device = torch.device("cuda")
if computation_dtype == torch.float8_e4m3fn:
computation_dtype = torch.float32
return device, dtype, computation_device, computation_dtype
def load(self, model, state_dict_lora, lora_prefix="", alpha=1.0, model_resource=""): def load(self, model, state_dict_lora, lora_prefix="", alpha=1.0, model_resource=""):
state_dict_model = model.state_dict() state_dict_model = model.state_dict()
device, dtype, computation_device, computation_dtype = self.fetch_device_and_dtype(state_dict_model) state_dict_lora = self.convert_state_dict(state_dict_lora, alpha=alpha, target_state_dict=state_dict_model)
lora_name_dict = self.get_name_dict(state_dict_lora) if len(state_dict_lora) > 0:
for name in lora_name_dict: print(f" {len(state_dict_lora)} tensors are updated.")
weight_up = state_dict_lora[lora_name_dict[name][0]].to(device=computation_device, dtype=computation_dtype) for name in state_dict_lora:
weight_down = state_dict_lora[lora_name_dict[name][1]].to(device=computation_device, dtype=computation_dtype) if state_dict_model[name].dtype == torch.float8_e4m3fn:
if len(weight_up.shape) == 4: weight = state_dict_model[name].to(torch.float32)
weight_up = weight_up.squeeze(3).squeeze(2) lora_weight = state_dict_lora[name].to(
weight_down = weight_down.squeeze(3).squeeze(2) dtype=torch.float32,
weight_lora = alpha * torch.mm(weight_up, weight_down).unsqueeze(2).unsqueeze(3) device=state_dict_model[name].device
else: )
weight_lora = alpha * torch.mm(weight_up, weight_down) state_dict_model[name] = (weight + lora_weight).to(
weight_model = state_dict_model[name].to(device=computation_device, dtype=computation_dtype) dtype=state_dict_model[name].dtype,
weight_patched = weight_model + weight_lora device=state_dict_model[name].device
state_dict_model[name] = weight_patched.to(device=device, dtype=dtype) )
print(f" {len(lora_name_dict)} tensors are updated.") else:
model.load_state_dict(state_dict_model) state_dict_model[name] += state_dict_lora[name].to(
dtype=state_dict_model[name].dtype,
device=state_dict_model[name].device
)
model.load_state_dict(state_dict_model)
def match(self, model, state_dict_lora):
for model_class in self.supported_model_classes:
if not isinstance(model, model_class):
continue
state_dict_model = model.state_dict()
try:
state_dict_lora_ = self.convert_state_dict(state_dict_lora, alpha=1.0, target_state_dict=state_dict_model)
if len(state_dict_lora_) > 0:
return "", ""
except:
pass
return None
class HunyuanVideoLoRAFromCivitai(LoRAFromCivitai): class HunyuanVideoLoRAFromCivitai(LoRAFromCivitai):

13
diffsynth/models/utils.py
View File

@@ -62,25 +62,26 @@ def load_state_dict_from_folder(file_path, torch_dtype=None):
return state_dict return state_dict
def load_state_dict(file_path, torch_dtype=None): def load_state_dict(file_path, torch_dtype=None, device="cpu"):
if file_path.endswith(".safetensors"): if file_path.endswith(".safetensors"):
return load_state_dict_from_safetensors(file_path, torch_dtype=torch_dtype) return load_state_dict_from_safetensors(file_path, torch_dtype=torch_dtype, device=device)
else: else:
return load_state_dict_from_bin(file_path, torch_dtype=torch_dtype) return load_state_dict_from_bin(file_path, torch_dtype=torch_dtype, device=device)
def load_state_dict_from_safetensors(file_path, torch_dtype=None): def load_state_dict_from_safetensors(file_path, torch_dtype=None, device="cpu"):
state_dict = {} state_dict = {}
with safe_open(file_path, framework="pt", device="cpu") as f: with safe_open(file_path, framework="pt", device="cpu") as f:
for k in f.keys(): for k in f.keys():
state_dict[k] = f.get_tensor(k) state_dict[k] = f.get_tensor(k)
if torch_dtype is not None: if torch_dtype is not None:
state_dict[k] = state_dict[k].to(torch_dtype) state_dict[k] = state_dict[k].to(torch_dtype)
state_dict[k] = state_dict[k].to(device)
return state_dict return state_dict
def load_state_dict_from_bin(file_path, torch_dtype=None): def load_state_dict_from_bin(file_path, torch_dtype=None, device="cpu"):
state_dict = torch.load(file_path, map_location="cpu", weights_only=True) state_dict = torch.load(file_path, map_location=device, weights_only=True)
if torch_dtype is not None: if torch_dtype is not None:
for i in state_dict: for i in state_dict:
if isinstance(state_dict[i], torch.Tensor): if isinstance(state_dict[i], torch.Tensor):

80
diffsynth/pipelines/flux_image.py
View File

@@ -13,7 +13,7 @@ from transformers import SiglipVisionModel
from copy import deepcopy from copy import deepcopy
from transformers.models.t5.modeling_t5 import T5LayerNorm, T5DenseActDense, T5DenseGatedActDense from transformers.models.t5.modeling_t5 import T5LayerNorm, T5DenseActDense, T5DenseGatedActDense
from ..models.flux_dit import RMSNorm from ..models.flux_dit import RMSNorm
from ..vram_management import enable_vram_management, AutoWrappedModule, AutoWrappedLinear from ..vram_management import enable_vram_management, enable_auto_lora, AutoLoRALinear, AutoWrappedModule, AutoWrappedLinear
class FluxImagePipeline(BasePipeline): class FluxImagePipeline(BasePipeline):
@@ -132,6 +132,15 @@ class FluxImagePipeline(BasePipeline):
) )
self.enable_cpu_offload() self.enable_cpu_offload()
def enable_auto_lora(self):
enable_auto_lora(
self.dit,
module_map={
RMSNorm: AutoWrappedModule,
torch.nn.Linear: AutoLoRALinear,
},
name_prefix=''
)
def denoising_model(self): def denoising_model(self):
return self.dit return self.dit
@@ -391,6 +400,9 @@ class FluxImagePipeline(BasePipeline):
# Progress bar # Progress bar
progress_bar_cmd=tqdm, progress_bar_cmd=tqdm,
progress_bar_st=None, progress_bar_st=None,
lora_state_dicts=[],
lora_alphas=[],
lora_patcher=None,
): ):
height, width = self.check_resize_height_width(height, width) height, width = self.check_resize_height_width(height, width)
@@ -430,6 +442,9 @@ class FluxImagePipeline(BasePipeline):
inference_callback = lambda prompt_emb_posi, controlnet_kwargs: lets_dance_flux( inference_callback = lambda prompt_emb_posi, controlnet_kwargs: lets_dance_flux(
dit=self.dit, controlnet=self.controlnet, dit=self.dit, controlnet=self.controlnet,
hidden_states=latents, timestep=timestep, hidden_states=latents, timestep=timestep,
lora_state_dicts=lora_state_dicts,
lora_alphas = lora_alphas,
lora_patcher=lora_patcher,
**prompt_emb_posi, **tiler_kwargs, **extra_input, **controlnet_kwargs, **ipadapter_kwargs_list_posi, **eligen_kwargs_posi, **tea_cache_kwargs, **prompt_emb_posi, **tiler_kwargs, **extra_input, **controlnet_kwargs, **ipadapter_kwargs_list_posi, **eligen_kwargs_posi, **tea_cache_kwargs,
) )
noise_pred_posi = self.control_noise_via_local_prompts( noise_pred_posi = self.control_noise_via_local_prompts(
@@ -447,6 +462,9 @@ class FluxImagePipeline(BasePipeline):
noise_pred_nega = lets_dance_flux( noise_pred_nega = lets_dance_flux(
dit=self.dit, controlnet=self.controlnet, dit=self.dit, controlnet=self.controlnet,
hidden_states=latents, timestep=timestep, hidden_states=latents, timestep=timestep,
lora_state_dicts=lora_state_dicts,
lora_alphas = lora_alphas,
lora_patcher=lora_patcher,
**prompt_emb_nega, **tiler_kwargs, **extra_input, **controlnet_kwargs_nega, **ipadapter_kwargs_list_nega, **eligen_kwargs_nega, **prompt_emb_nega, **tiler_kwargs, **extra_input, **controlnet_kwargs_nega, **ipadapter_kwargs_list_nega, **eligen_kwargs_nega,
) )
noise_pred = noise_pred_nega + cfg_scale * (noise_pred_posi - noise_pred_nega) noise_pred = noise_pred_nega + cfg_scale * (noise_pred_posi - noise_pred_nega)
@@ -511,7 +529,6 @@ class TeaCache:
hidden_states = hidden_states + self.previous_residual hidden_states = hidden_states + self.previous_residual
return hidden_states return hidden_states
def lets_dance_flux( def lets_dance_flux(
dit: FluxDiT, dit: FluxDiT,
controlnet: FluxMultiControlNetManager = None, controlnet: FluxMultiControlNetManager = None,
@@ -530,8 +547,10 @@ def lets_dance_flux(
entity_masks=None, entity_masks=None,
ipadapter_kwargs_list={}, ipadapter_kwargs_list={},
tea_cache: TeaCache = None, tea_cache: TeaCache = None,
use_gradient_checkpointing=False,
**kwargs **kwargs
): ):
if tiled: if tiled:
def flux_forward_fn(hl, hr, wl, wr): def flux_forward_fn(hl, hr, wl, wr):
tiled_controlnet_frames = [f[:, :, hl: hr, wl: wr] for f in controlnet_frames] if controlnet_frames is not None else None tiled_controlnet_frames = [f[:, :, hl: hr, wl: wr] for f in controlnet_frames] if controlnet_frames is not None else None
@@ -595,6 +614,11 @@ def lets_dance_flux(
prompt_emb = dit.context_embedder(prompt_emb) prompt_emb = dit.context_embedder(prompt_emb)
image_rotary_emb = dit.pos_embedder(torch.cat((text_ids, image_ids), dim=1)) image_rotary_emb = dit.pos_embedder(torch.cat((text_ids, image_ids), dim=1))
attention_mask = None attention_mask = None
def create_custom_forward(module):
def custom_forward(*inputs, **kwargs):
return module(*inputs, **kwargs)
return custom_forward
# TeaCache # TeaCache
if tea_cache is not None: if tea_cache is not None:
@@ -607,14 +631,22 @@ def lets_dance_flux(
else: else:
# Joint Blocks # Joint Blocks
for block_id, block in enumerate(dit.blocks): for block_id, block in enumerate(dit.blocks):
hidden_states, prompt_emb = block( if use_gradient_checkpointing:
hidden_states, hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint(
prompt_emb, create_custom_forward(block),
conditioning, hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, ipadapter_kwargs_list.get(block_id, None), **kwargs,
image_rotary_emb, use_reentrant=False,
attention_mask, )
ipadapter_kwargs_list=ipadapter_kwargs_list.get(block_id, None) else:
) hidden_states, prompt_emb = block(
hidden_states,
prompt_emb,
conditioning,
image_rotary_emb,
attention_mask,
ipadapter_kwargs_list=ipadapter_kwargs_list.get(block_id, None),
**kwargs
)
# ControlNet # ControlNet
if controlnet is not None and controlnet_frames is not None: if controlnet is not None and controlnet_frames is not None:
hidden_states = hidden_states + controlnet_res_stack[block_id] hidden_states = hidden_states + controlnet_res_stack[block_id]
@@ -623,14 +655,22 @@ def lets_dance_flux(
hidden_states = torch.cat([prompt_emb, hidden_states], dim=1) hidden_states = torch.cat([prompt_emb, hidden_states], dim=1)
num_joint_blocks = len(dit.blocks) num_joint_blocks = len(dit.blocks)
for block_id, block in enumerate(dit.single_blocks): for block_id, block in enumerate(dit.single_blocks):
hidden_states, prompt_emb = block( if use_gradient_checkpointing:
hidden_states, hidden_states, prompt_emb = torch.utils.checkpoint.checkpoint(
prompt_emb, create_custom_forward(block),
conditioning, hidden_states, prompt_emb, conditioning, image_rotary_emb, attention_mask, ipadapter_kwargs_list.get(block_id + num_joint_blocks, None), **kwargs,
image_rotary_emb, use_reentrant=False,
attention_mask, )
ipadapter_kwargs_list=ipadapter_kwargs_list.get(block_id + num_joint_blocks, None) else:
) hidden_states, prompt_emb = block(
hidden_states,
prompt_emb,
conditioning,
image_rotary_emb,
attention_mask,
ipadapter_kwargs_list=ipadapter_kwargs_list.get(block_id + num_joint_blocks, None),
**kwargs
)
# ControlNet # ControlNet
if controlnet is not None and controlnet_frames is not None: if controlnet is not None and controlnet_frames is not None:
hidden_states[:, prompt_emb.shape[1]:] = hidden_states[:, prompt_emb.shape[1]:] + controlnet_single_res_stack[block_id] hidden_states[:, prompt_emb.shape[1]:] = hidden_states[:, prompt_emb.shape[1]:] + controlnet_single_res_stack[block_id]
@@ -639,8 +679,8 @@ def lets_dance_flux(
if tea_cache is not None: if tea_cache is not None:
tea_cache.store(hidden_states) tea_cache.store(hidden_states)
hidden_states = dit.final_norm_out(hidden_states, conditioning) hidden_states = dit.final_norm_out(hidden_states, conditioning, **kwargs)
hidden_states = dit.final_proj_out(hidden_states) hidden_states = dit.final_proj_out(hidden_states, **kwargs)
hidden_states = dit.unpatchify(hidden_states, height, width) hidden_states = dit.unpatchify(hidden_states, height, width)
return hidden_states return hidden_states

50
diffsynth/vram_management/layers.py
View File

@@ -70,6 +70,56 @@ class AutoWrappedLinear(torch.nn.Linear):
bias = None if self.bias is None else cast_to(self.bias, self.computation_dtype, self.computation_device) bias = None if self.bias is None else cast_to(self.bias, self.computation_dtype, self.computation_device)
return torch.nn.functional.linear(x, weight, bias) return torch.nn.functional.linear(x, weight, bias)
class AutoLoRALinear(torch.nn.Linear):
def __init__(self, name='', in_features=1, out_features=2, bias=True, device=None, dtype=None):
super().__init__(in_features, out_features, bias, device, dtype)
self.name = name
def forward(self, x, lora_state_dicts=[], lora_alphas=[1.0,1.0], lora_patcher=None, **kwargs):
out = torch.nn.functional.linear(x, self.weight, self.bias)
lora_a_name = f'{self.name}.lora_A.default.weight'
lora_b_name = f'{self.name}.lora_B.default.weight'
lora_output = []
for i, lora_state_dict in enumerate(lora_state_dicts):
if lora_state_dict is None:
break
if lora_a_name in lora_state_dict and lora_b_name in lora_state_dict:
lora_A = lora_state_dict[lora_a_name].to(dtype=self.weight.dtype,device=self.weight.device)
lora_B = lora_state_dict[lora_b_name].to(dtype=self.weight.dtype,device=self.weight.device)
out_lora = x @ lora_A.T @ lora_B.T
lora_output.append(out_lora)
if len(lora_output) > 0:
lora_output = torch.stack(lora_output)
out = lora_patcher(out, lora_output, self.name)
return out
def enable_auto_lora(model:torch.nn.Module, module_map: dict, name_prefix=''):
targets = list(module_map.keys())
for name, module in model.named_children():
if name_prefix != '':
full_name = name_prefix + '.' + name
else:
full_name = name
if isinstance(module,targets[1]):
# print(full_name)
# print(module)
# ToDo: replace the linear to the AutoLoRALinear
new_module = AutoLoRALinear(
name=full_name,
in_features=module.in_features,
out_features=module.out_features,
bias=module.bias is not None,
device=module.weight.device,
dtype=module.weight.dtype)
new_module.weight.data.copy_(module.weight.data)
new_module.bias.data.copy_(module.bias.data)
setattr(model, name, new_module)
elif isinstance(module, targets[0]):
pass
else:
enable_auto_lora(module, module_map, full_name)
def enable_vram_management_recursively(model: torch.nn.Module, module_map: dict, module_config: dict, max_num_param=None, overflow_module_config: dict = None, total_num_param=0): def enable_vram_management_recursively(model: torch.nn.Module, module_map: dict, module_config: dict, max_num_param=None, overflow_module_config: dict = None, total_num_param=0):
for name, module in model.named_children(): for name, module in model.named_children():

0
models/lora/Put lora files here.txt → lora/__init__.py
View File

54
lora/dataset.py Normal file
View File

@@ -0,0 +1,54 @@
import torch, os
import pandas as pd
from PIL import Image
from torchvision.transforms import v2
from diffsynth.data.video import crop_and_resize
class LoraDataset(torch.utils.data.Dataset):
def __init__(self, base_path, metadata_path, steps_per_epoch=1000, loras_per_item=1):
self.base_path = base_path
data_df = pd.read_csv(metadata_path)
self.model_file = data_df["model_file"].tolist()
self.image_file = data_df["image_file"].tolist()
self.text = data_df["text"].tolist()
self.max_resolution = 1920 * 1080
self.steps_per_epoch = steps_per_epoch
self.loras_per_item = loras_per_item
def read_image(self, image_file):
image = Image.open(image_file).convert("RGB")
width, height = image.size
if width * height > self.max_resolution:
scale = (width * height / self.max_resolution) ** 0.5
image = image.resize((int(width / scale), int(height / scale)))
width, height = image.size
if width % 16 != 0 or height % 16 != 0:
image = crop_and_resize(image, height // 16 * 16, width // 16 * 16)
image = v2.functional.to_image(image)
image = v2.functional.to_dtype(image, dtype=torch.float32, scale=True)
image = v2.functional.normalize(image, [0.5], [0.5])
return image
def get_data(self, data_id):
data = {
"model_file": os.path.join(self.base_path, self.model_file[data_id]),
"image": self.read_image(os.path.join(self.base_path, self.image_file[data_id])),
"text": self.text[data_id]
}
return data
def __getitem__(self, index):
data = []
while len(data) < self.loras_per_item:
data_id = torch.randint(0, len(self.model_file), (1,))[0]
data_id = (data_id + index) % len(self.model_file) # For fixed seed.
data.append(self.get_data(data_id))
return data
def __len__(self):
return self.steps_per_epoch

61
lora/merger.py Normal file
View File

@@ -0,0 +1,61 @@
import torch
class LoraMerger(torch.nn.Module):
def __init__(self, dim):
super().__init__()
self.weight_base = torch.nn.Parameter(torch.randn((dim,)))
self.weight_lora = torch.nn.Parameter(torch.randn((dim,)))
self.weight_cross = torch.nn.Parameter(torch.randn((dim,)))
self.weight_out = torch.nn.Parameter(torch.ones((dim,)))
self.bias = torch.nn.Parameter(torch.randn((dim,)))
self.activation = torch.nn.Sigmoid()
self.norm_base = torch.nn.LayerNorm(dim, eps=1e-5)
self.norm_lora = torch.nn.LayerNorm(dim, eps=1e-5)
def forward(self, base_output, lora_outputs):
norm_base_output = self.norm_base(base_output)
norm_lora_outputs = self.norm_lora(lora_outputs)
gate = self.activation(
norm_base_output * self.weight_base \
+ norm_lora_outputs * self.weight_lora \
+ norm_base_output * norm_lora_outputs * self.weight_cross + self.bias
)
output = base_output + (self.weight_out * gate * lora_outputs).sum(dim=0)
return output
class LoraPatcher(torch.nn.Module):
def __init__(self, lora_patterns=None):
super().__init__()
if lora_patterns is None:
lora_patterns = self.default_lora_patterns()
model_dict = {}
for lora_pattern in lora_patterns:
name, dim = lora_pattern["name"], lora_pattern["dim"]
model_dict[name.replace(".", "___")] = LoraMerger(dim)
self.model_dict = torch.nn.ModuleDict(model_dict)
def default_lora_patterns(self):
lora_patterns = []
lora_dict = {
"attn.a_to_qkv": 9216, "attn.a_to_out": 3072, "ff_a.0": 12288, "ff_a.2": 3072, "norm1_a.linear": 18432,
"attn.b_to_qkv": 9216, "attn.b_to_out": 3072, "ff_b.0": 12288, "ff_b.2": 3072, "norm1_b.linear": 18432,
}
for i in range(19):
for suffix in lora_dict:
lora_patterns.append({
"name": f"blocks.{i}.{suffix}",
"dim": lora_dict[suffix]
})
lora_dict = {"to_qkv_mlp": 21504, "proj_out": 3072, "norm.linear": 9216}
for i in range(38):
for suffix in lora_dict:
lora_patterns.append({
"name": f"single_blocks.{i}.{suffix}",
"dim": lora_dict[suffix]
})
return lora_patterns
def forward(self, base_output, lora_outputs, name):
return self.model_dict[name.replace(".", "___")](base_output, lora_outputs)

149
lora/retriever.py Normal file
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@@ -0,0 +1,149 @@
import torch
from diffsynth import SDTextEncoder
from diffsynth.models.sd3_text_encoder import SD3TextEncoder1StateDictConverter
from diffsynth.models.sd_text_encoder import CLIPEncoderLayer
class LoRALayerBlock(torch.nn.Module):
def __init__(self, L, dim_in):
super().__init__()
self.x = torch.nn.Parameter(torch.randn(1, L, dim_in))
def forward(self, lora_A, lora_B):
out = self.x @ lora_A.T @ lora_B.T
return out
class LoRAEmbedder(torch.nn.Module):
def __init__(self, lora_patterns=None, L=1, out_dim=2048):
super().__init__()
if lora_patterns is None:
lora_patterns = self.default_lora_patterns()
model_dict = {}
for lora_pattern in lora_patterns:
name, dim = lora_pattern["name"], lora_pattern["dim"][0]
model_dict[name.replace(".", "___")] = LoRALayerBlock(L, dim)
self.model_dict = torch.nn.ModuleDict(model_dict)
proj_dict = {}
for lora_pattern in lora_patterns:
layer_type, dim = lora_pattern["type"], lora_pattern["dim"][1]
if layer_type not in proj_dict:
proj_dict[layer_type.replace(".", "___")] = torch.nn.Linear(dim, out_dim)
self.proj_dict = torch.nn.ModuleDict(proj_dict)
self.lora_patterns = lora_patterns
def default_lora_patterns(self):
lora_patterns = []
lora_dict = {
"attn.a_to_qkv": (3072, 9216), "attn.a_to_out": (3072, 3072), "ff_a.0": (3072, 12288), "ff_a.2": (12288, 3072), "norm1_a.linear": (3072, 18432),
"attn.b_to_qkv": (3072, 9216), "attn.b_to_out": (3072, 3072), "ff_b.0": (3072, 12288), "ff_b.2": (12288, 3072), "norm1_b.linear": (3072, 18432),
}
for i in range(19):
for suffix in lora_dict:
lora_patterns.append({
"name": f"blocks.{i}.{suffix}",
"dim": lora_dict[suffix],
"type": suffix,
})
lora_dict = {"to_qkv_mlp": (3072, 21504), "proj_out": (15360, 3072), "norm.linear": (3072, 9216)}
for i in range(38):
for suffix in lora_dict:
lora_patterns.append({
"name": f"single_blocks.{i}.{suffix}",
"dim": lora_dict[suffix],
"type": suffix,
})
return lora_patterns
def forward(self, lora):
lora_emb = []
for lora_pattern in self.lora_patterns:
name, layer_type = lora_pattern["name"], lora_pattern["type"]
lora_A = lora[name + ".lora_A.default.weight"]
lora_B = lora[name + ".lora_B.default.weight"]
lora_out = self.model_dict[name.replace(".", "___")](lora_A, lora_B)
lora_out = self.proj_dict[layer_type.replace(".", "___")](lora_out)
lora_emb.append(lora_out)
lora_emb = torch.concat(lora_emb, dim=1)
return lora_emb
class TextEncoder(torch.nn.Module):
def __init__(self, embed_dim=768, vocab_size=49408, max_position_embeddings=77, num_encoder_layers=12, encoder_intermediate_size=3072):
super().__init__()
# token_embedding
self.token_embedding = torch.nn.Embedding(vocab_size, embed_dim)
# position_embeds (This is a fixed tensor)
self.position_embeds = torch.nn.Parameter(torch.zeros(1, max_position_embeddings, embed_dim))
# encoders
self.encoders = torch.nn.ModuleList([CLIPEncoderLayer(embed_dim, encoder_intermediate_size) for _ in range(num_encoder_layers)])
# attn_mask
self.attn_mask = self.attention_mask(max_position_embeddings)
# final_layer_norm
self.final_layer_norm = torch.nn.LayerNorm(embed_dim)
def attention_mask(self, length):
mask = torch.empty(length, length)
mask.fill_(float("-inf"))
mask.triu_(1)
return mask
def forward(self, input_ids, clip_skip=1):
embeds = self.token_embedding(input_ids) + self.position_embeds
attn_mask = self.attn_mask.to(device=embeds.device, dtype=embeds.dtype)
for encoder_id, encoder in enumerate(self.encoders):
embeds = encoder(embeds, attn_mask=attn_mask)
if encoder_id + clip_skip == len(self.encoders):
break
embeds = self.final_layer_norm(embeds)
pooled_embeds = embeds[torch.arange(embeds.shape[0]), input_ids.to(dtype=torch.int).argmax(dim=-1)]
return pooled_embeds
@staticmethod
def state_dict_converter():
return SD3TextEncoder1StateDictConverter()
class LoRAEncoder(torch.nn.Module):
def __init__(self, embed_dim=768, max_position_embeddings=304, num_encoder_layers=2, encoder_intermediate_size=3072, L=1):
super().__init__()
max_position_embeddings *= L
# Embedder
self.embedder = LoRAEmbedder(L=L, out_dim=embed_dim)
# position_embeds (This is a fixed tensor)
self.position_embeds = torch.nn.Parameter(torch.zeros(1, max_position_embeddings, embed_dim))
# encoders
self.encoders = torch.nn.ModuleList([CLIPEncoderLayer(embed_dim, encoder_intermediate_size) for _ in range(num_encoder_layers)])
# attn_mask
self.attn_mask = self.attention_mask(max_position_embeddings)
# final_layer_norm
self.final_layer_norm = torch.nn.LayerNorm(embed_dim)
def attention_mask(self, length):
mask = torch.empty(length, length)
mask.fill_(float("-inf"))
mask.triu_(1)
return mask
def forward(self, lora):
embeds = self.embedder(lora) + self.position_embeds
attn_mask = self.attn_mask.to(device=embeds.device, dtype=embeds.dtype)
for encoder_id, encoder in enumerate(self.encoders):
embeds = encoder(embeds, attn_mask=attn_mask)
embeds = self.final_layer_norm(embeds)
embeds = embeds.mean(dim=1)
return embeds

46
lora/test_merger.py Normal file
View File

@@ -0,0 +1,46 @@
from diffsynth import FluxImagePipeline, ModelManager, load_state_dict
from diffsynth.models.lora import FluxLoRAConverter
from diffsynth.pipelines.flux_image import lets_dance_flux
from lora.dataset import LoraDataset
from lora.merger import LoraPatcher
from lora.utils import load_lora
import torch, os
from accelerate import Accelerator, DistributedDataParallelKwargs
from tqdm import tqdm
model_manager = ModelManager(torch_dtype=torch.bfloat16, device="cuda", model_id_list=["FLUX.1-dev"])
pipe = FluxImagePipeline.from_model_manager(model_manager)
pipe.enable_auto_lora()
lora_patcher = LoraPatcher().to(dtype=torch.bfloat16, device="cuda")
lora_patcher.load_state_dict(load_state_dict("models/lora_merger/epoch-3.safetensors"))
dataset = LoraDataset("data/lora/models", "data/lora/lora_dataset_1000.csv", steps_per_epoch=800, loras_per_item=4)
for seed in range(100):
batch = dataset[0]
num_lora = torch.randint(1, len(batch), (1,))[0]
lora_state_dicts = [
FluxLoRAConverter.align_to_diffsynth_format(load_lora(batch[i]["model_file"], device="cuda")) for i in range(num_lora)
]
image = pipe(
prompt=batch[0]["text"],
seed=seed,
)
image.save(f"data/lora/lora_outputs/image_{seed}_nolora.jpg")
for i in range(num_lora):
image = pipe(
prompt=batch[0]["text"],
lora_state_dicts=[lora_state_dicts[i]],
lora_patcher=lora_patcher,
seed=seed,
)
image.save(f"data/lora/lora_outputs/image_{seed}_{i}.jpg")
image = pipe(
prompt=batch[0]["text"],
lora_state_dicts=lora_state_dicts,
lora_patcher=lora_patcher,
seed=seed,
)
image.save(f"data/lora/lora_outputs/image_{seed}_merger.jpg")

148
lora/test_retriever.py Normal file
View File

@@ -0,0 +1,148 @@
from diffsynth import FluxImagePipeline, ModelManager, load_state_dict
from diffsynth.models.lora import FluxLoRAConverter
from diffsynth.pipelines.flux_image import lets_dance_flux
from lora.dataset import LoraDataset
from lora.retriever import TextEncoder, LoRAEncoder
from lora.merger import LoraPatcher
from lora.utils import load_lora
import torch, os
from accelerate import Accelerator, DistributedDataParallelKwargs
from tqdm import tqdm
from transformers import CLIPTokenizer, CLIPModel
import pandas as pd
class LoRARetrieverTrainingModel(torch.nn.Module):
def __init__(self, pretrained_path):
super().__init__()
self.text_encoder = TextEncoder().to(torch.bfloat16)
state_dict = load_state_dict("models/FLUX/FLUX.1-dev/text_encoder/model.safetensors")
self.text_encoder.load_state_dict(TextEncoder.state_dict_converter().from_civitai(state_dict))
self.text_encoder.requires_grad_(False)
self.text_encoder.eval()
self.lora_encoder = LoRAEncoder().to(torch.bfloat16)
state_dict = load_state_dict(pretrained_path)
self.lora_encoder.load_state_dict(state_dict)
self.tokenizer = CLIPTokenizer.from_pretrained("diffsynth/tokenizer_configs/stable_diffusion_3/tokenizer_1")
def to(self, *args, **kwargs):
device, dtype, non_blocking, convert_to_format = torch._C._nn._parse_to(*args, **kwargs)
if device is not None:
self.device = device
if dtype is not None:
self.torch_dtype = dtype
super().to(*args, **kwargs)
return self
def forward(self, batch):
text = [data["text"] for data in batch]
input_ids = self.tokenizer(
text,
return_tensors="pt",
padding="max_length",
max_length=77,
truncation=True
).input_ids.to(self.device)
text_emb = self.text_encoder(input_ids)
text_emb = text_emb / text_emb.norm()
lora_emb = []
for data in batch:
lora = FluxLoRAConverter.align_to_diffsynth_format(load_lora(data["model_file"], device=self.device))
lora_emb.append(self.lora_encoder(lora))
lora_emb = torch.concat(lora_emb)
lora_emb = lora_emb / lora_emb.norm()
similarity = text_emb @ lora_emb.T
print(similarity)
loss = -torch.log(torch.softmax(similarity, dim=0).diag()) - torch.log(torch.softmax(similarity, dim=1).diag())
loss = 10 * loss.mean()
return loss
def trainable_modules(self):
return self.lora_encoder.parameters()
@torch.no_grad()
def process_lora_list(self, lora_list):
lora_emb = []
for lora in tqdm(lora_list):
lora = FluxLoRAConverter.align_to_diffsynth_format(load_lora(lora, device="cuda"))
lora_emb.append(self.lora_encoder(lora))
lora_emb = torch.concat(lora_emb)
lora_emb = lora_emb / lora_emb.norm()
self.lora_emb = lora_emb
self.lora_list = lora_list
@torch.no_grad()
def retrieve(self, text, k=1):
input_ids = self.tokenizer(
text,
return_tensors="pt",
padding="max_length",
max_length=77,
truncation=True
).input_ids.to(self.device)
text_emb = self.text_encoder(input_ids)
text_emb = text_emb / text_emb.norm()
similarity = text_emb @ self.lora_emb.T
topk = torch.topk(similarity, k, dim=1).indices[0]
lora_list = []
model_url_list = []
for lora_id in topk:
print(self.lora_list[lora_id])
lora = FluxLoRAConverter.align_to_diffsynth_format(load_lora(self.lora_list[lora_id], device="cuda"))
lora_list.append(lora)
model_id = self.lora_list[lora_id].split("/")[3:5]
model_url_list.append(f"https://www.modelscope.cn/models/{model_id[0]}/{model_id[1]}")
return lora_list, model_url_list
model_manager = ModelManager(torch_dtype=torch.bfloat16, device="cuda", model_id_list=["FLUX.1-dev"])
pipe = FluxImagePipeline.from_model_manager(model_manager)
pipe.enable_auto_lora()
lora_patcher = LoraPatcher().to(dtype=torch.bfloat16, device="cuda")
lora_patcher.load_state_dict(load_state_dict("models/lora_merger/epoch-9.safetensors"))
retriever = LoRARetrieverTrainingModel("models/lora_retriever/epoch-3.safetensors").to(dtype=torch.bfloat16, device="cuda")
retriever.process_lora_list(list(set("data/lora/models/" + i for i in pd.read_csv("data/lora/lora_dataset_1000.csv")["model_file"])))
dataset = LoraDataset("data/lora/models", "data/lora/lora_dataset_1000.csv", steps_per_epoch=800, loras_per_item=1)
text_list = []
model_url_list = []
for seed in range(100):
text = dataset[0][0]["text"]
print(text)
loras, urls = retriever.retrieve(text, k=3)
print(urls)
image = pipe(
prompt=text,
seed=seed,
)
image.save(f"data/lora/lora_outputs/image_{seed}_top0.jpg")
for i in range(2, 3):
image = pipe(
prompt=text,
lora_state_dicts=loras[:i+1],
lora_patcher=lora_patcher,
seed=seed,
)
image.save(f"data/lora/lora_outputs/image_{seed}_top{i+1}.jpg")
text_list.append(text)
model_url_list.append(urls)
df = pd.DataFrame()
df["text"] = text_list
df["models"] = [",".join(i) for i in model_url_list]
df.to_csv("data/lora/lora_outputs/metadata.csv", index=False, encoding="utf-8-sig")

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from diffsynth import FluxImagePipeline, ModelManager
from diffsynth.models.lora import FluxLoRAConverter
from diffsynth.pipelines.flux_image import lets_dance_flux
from lora.dataset import LoraDataset
from lora.merger import LoraPatcher
from lora.utils import load_lora
import torch, os
from accelerate import Accelerator, DistributedDataParallelKwargs
from tqdm import tqdm
class LoRAMergerTrainingModel(torch.nn.Module):
def __init__(self):
super().__init__()
model_manager = ModelManager(torch_dtype=torch.bfloat16, device="cpu", model_id_list=["FLUX.1-dev"])
self.pipe = FluxImagePipeline.from_model_manager(model_manager)
self.lora_patcher = LoraPatcher()
self.pipe.enable_auto_lora()
self.freeze_parameters()
self.switch_to_training_mode()
self.use_gradient_checkpointing = True
self.state_dict_converter = FluxLoRAConverter.align_to_diffsynth_format
self.device = "cuda"
def to(self, *args, **kwargs):
device, dtype, non_blocking, convert_to_format = torch._C._nn._parse_to(*args, **kwargs)
if device is not None:
self.device = device
if dtype is not None:
self.torch_dtype = dtype
super().to(*args, **kwargs)
return self
def switch_to_training_mode(self):
self.pipe.scheduler.set_timesteps(1000, training=True)
def freeze_parameters(self):
self.pipe.requires_grad_(False)
self.pipe.eval()
self.pipe.denoising_model().train()
self.lora_patcher.requires_grad_(True)
def forward(self, batch):
# Data
text, image = batch[0]["text"], batch[0]["image"].unsqueeze(0)
num_lora = torch.randint(1, len(batch), (1,))[0]
lora_state_dicts = [
self.state_dict_converter(load_lora(batch[i]["model_file"], device=self.device)) for i in range(num_lora)
]
lora_alphas = None
# Prepare input parameters
self.pipe.device = self.device
prompt_emb = self.pipe.encode_prompt(text, positive=True)
latents = self.pipe.vae_encoder(image.to(dtype=self.pipe.torch_dtype, device=self.device))
noise = torch.randn_like(latents)
timestep_id = torch.randint(0, self.pipe.scheduler.num_train_timesteps, (1,))
timestep = self.pipe.scheduler.timesteps[timestep_id].to(self.device)
extra_input = self.pipe.prepare_extra_input(latents)
noisy_latents = self.pipe.scheduler.add_noise(latents, noise, timestep)
training_target = self.pipe.scheduler.training_target(latents, noise, timestep)
# Compute loss
noise_pred = lets_dance_flux(
self.pipe.dit,
hidden_states=noisy_latents, timestep=timestep, **prompt_emb, **extra_input,
lora_state_dicts=lora_state_dicts, lora_alphas=lora_alphas, lora_patcher=self.lora_patcher,
use_gradient_checkpointing=self.use_gradient_checkpointing
)
loss = torch.nn.functional.mse_loss(noise_pred.float(), training_target.float())
loss = loss * self.pipe.scheduler.training_weight(timestep)
return loss
def trainable_modules(self):
return self.lora_patcher.parameters()
class ModelLogger:
def __init__(self, output_path, remove_prefix_in_ckpt=None):
self.output_path = output_path
self.remove_prefix_in_ckpt = remove_prefix_in_ckpt
def on_step_end(self, loss):
pass
def on_epoch_end(self, accelerator, model, epoch_id):
accelerator.wait_for_everyone()
if accelerator.is_main_process:
state_dict = accelerator.unwrap_model(model).lora_patcher.state_dict()
os.makedirs(self.output_path, exist_ok=True)
path = os.path.join(self.output_path, f"epoch-{epoch_id}.safetensors")
accelerator.save(state_dict, path, safe_serialization=True)
if __name__ == '__main__':
model = LoRAMergerTrainingModel()
dataset = LoraDataset("data/lora/models/", "data/lora/lora_dataset_1000.csv", steps_per_epoch=800, loras_per_item=4)
dataloader = torch.utils.data.DataLoader(dataset, shuffle=True, batch_size=1, num_workers=1, collate_fn=lambda x: x[0])
optimizer = torch.optim.AdamW(model.trainable_modules(), lr=1e-4)
model_logger = ModelLogger("models/lora_merger")
accelerator = Accelerator(kwargs_handlers=[DistributedDataParallelKwargs(find_unused_parameters=True)])
model, optimizer, dataloader = accelerator.prepare(model, optimizer, dataloader)
for epoch_id in range(1000000):
for data in tqdm(dataloader):
with accelerator.accumulate(model):
optimizer.zero_grad()
loss = model(data)
accelerator.backward(loss)
optimizer.step()
model_logger.on_epoch_end(accelerator, model, epoch_id)

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from diffsynth import FluxImagePipeline, ModelManager, load_state_dict
from diffsynth.models.lora import FluxLoRAConverter
from diffsynth.pipelines.flux_image import lets_dance_flux
from lora.dataset import LoraDataset
from lora.retriever import TextEncoder, LoRAEncoder
from lora.utils import load_lora
import torch, os
from accelerate import Accelerator, DistributedDataParallelKwargs
from tqdm import tqdm
from transformers import CLIPTokenizer, CLIPModel
class LoRARetrieverTrainingModel(torch.nn.Module):
def __init__(self):
super().__init__()
self.text_encoder = TextEncoder().to(torch.bfloat16)
state_dict = load_state_dict("models/FLUX/FLUX.1-dev/text_encoder/model.safetensors")
self.text_encoder.load_state_dict(TextEncoder.state_dict_converter().from_civitai(state_dict))
self.text_encoder.requires_grad_(False)
self.text_encoder.eval()
self.lora_encoder = LoRAEncoder().to(torch.bfloat16)
self.tokenizer = CLIPTokenizer.from_pretrained("diffsynth/tokenizer_configs/stable_diffusion_3/tokenizer_1")
def to(self, *args, **kwargs):
device, dtype, non_blocking, convert_to_format = torch._C._nn._parse_to(*args, **kwargs)
if device is not None:
self.device = device
if dtype is not None:
self.torch_dtype = dtype
super().to(*args, **kwargs)
return self
def forward(self, batch):
text = [data["text"] for data in batch]
input_ids = self.tokenizer(
text,
return_tensors="pt",
padding="max_length",
max_length=77,
truncation=True
).input_ids.to(self.device)
text_emb = self.text_encoder(input_ids)
text_emb = text_emb / text_emb.norm()
lora_emb = []
for data in batch:
lora = FluxLoRAConverter.align_to_diffsynth_format(load_lora(data["model_file"], device=self.device))
lora_emb.append(self.lora_encoder(lora))
lora_emb = torch.concat(lora_emb)
lora_emb = lora_emb / lora_emb.norm()
similarity = text_emb @ lora_emb.T
print(similarity)
loss = -torch.log(torch.softmax(similarity, dim=0).diag()) - torch.log(torch.softmax(similarity, dim=1).diag())
loss = 10 * loss.mean()
return loss
def trainable_modules(self):
return self.lora_encoder.parameters()
class ModelLogger:
def __init__(self, output_path, remove_prefix_in_ckpt=None):
self.output_path = output_path
self.remove_prefix_in_ckpt = remove_prefix_in_ckpt
def on_step_end(self, loss):
pass
def on_epoch_end(self, accelerator, model, epoch_id):
accelerator.wait_for_everyone()
if accelerator.is_main_process:
state_dict = accelerator.unwrap_model(model).lora_encoder.state_dict()
os.makedirs(self.output_path, exist_ok=True)
path = os.path.join(self.output_path, f"epoch-{epoch_id}.safetensors")
accelerator.save(state_dict, path, safe_serialization=True)
if __name__ == '__main__':
model = LoRARetrieverTrainingModel()
dataset = LoraDataset("data/lora/models/", "data/lora/lora_dataset_1000.csv", steps_per_epoch=100, loras_per_item=32)
dataloader = torch.utils.data.DataLoader(dataset, shuffle=True, batch_size=1, num_workers=1, collate_fn=lambda x: x[0])
optimizer = torch.optim.AdamW(model.trainable_modules(), lr=1e-4)
model_logger = ModelLogger("models/lora_retriever")
accelerator = Accelerator(kwargs_handlers=[DistributedDataParallelKwargs(find_unused_parameters=True)])
model, optimizer, dataloader = accelerator.prepare(model, optimizer, dataloader)
for epoch_id in range(1000000):
for data in tqdm(dataloader):
with accelerator.accumulate(model):
optimizer.zero_grad()
loss = model(data)
accelerator.backward(loss)
optimizer.step()
print(loss)
model_logger.on_epoch_end(accelerator, model, epoch_id)

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lora/utils.py Normal file
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from diffsynth import load_state_dict
import math, torch
def load_lora(file_path, device):
sd = load_state_dict(file_path, torch_dtype=torch.bfloat16, device=device)
scale = math.sqrt(sd["lora_unet_single_blocks_9_modulation_lin.alpha"] / sd["lora_unet_single_blocks_9_modulation_lin.lora_down.weight"].shape[0])
if scale != 1:
sd = {i: sd[i] * scale for i in sd}
return sd