# coding=utf-8 # Copyright 2025 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 os import socket import pytest import torch import torch.distributed as dist import torch.multiprocessing as mp from diffusers.models._modeling_parallel import ContextParallelConfig from diffusers.models.attention_dispatch import AttentionBackendName, _AttentionBackendRegistry from ...testing_utils import ( is_attention, is_context_parallel, is_kernels_available, require_torch_multi_accelerator, torch_device, ) from .utils import _maybe_cast_to_bf16 # Device configuration mapping DEVICE_CONFIG = { "cuda": {"backend": "nccl", "module": torch.cuda}, "xpu": {"backend": "xccl", "module": torch.xpu}, } def _find_free_port(): """Find a free port on localhost.""" with socket.socket(socket.AF_INET, socket.SOCK_STREAM) as s: s.bind(("", 0)) s.listen(1) port = s.getsockname()[1] return port def _context_parallel_worker( rank, world_size, master_port, model_class, init_dict, cp_dict, inputs_dict, return_dict, attention_backend=None ): """Worker function for context parallel testing.""" try: # Set up distributed environment os.environ["MASTER_ADDR"] = "localhost" os.environ["MASTER_PORT"] = str(master_port) os.environ["RANK"] = str(rank) os.environ["WORLD_SIZE"] = str(world_size) # Get device configuration device_config = DEVICE_CONFIG.get(torch_device, DEVICE_CONFIG["cuda"]) backend = device_config["backend"] device_module = device_config["module"] # Initialize process group dist.init_process_group(backend=backend, rank=rank, world_size=world_size) # Set device for this process device_module.set_device(rank) device = torch.device(f"{torch_device}:{rank}") # Create model model = model_class(**init_dict) model.to(device) model.eval() # Cast as needed. model, inputs_dict = _maybe_cast_to_bf16(attention_backend, model, inputs_dict) # Move inputs to device inputs_on_device = {k: v.to(device) if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} # Enable attention backend if attention_backend: model.set_attention_backend(attention_backend) # Enable context parallelism cp_config = ContextParallelConfig(**cp_dict) model.enable_parallelism(config=cp_config) # Run forward pass with torch.no_grad(): output = model(**inputs_on_device, return_dict=False)[0] # Only rank 0 reports results if rank == 0: return_dict["status"] = "success" return_dict["output_shape"] = list(output.shape) except Exception as e: if rank == 0: return_dict["status"] = "error" return_dict["error"] = str(e) finally: if dist.is_initialized(): dist.destroy_process_group() def _context_parallel_backward_worker( rank, world_size, master_port, model_class, init_dict, cp_dict, inputs_dict, return_dict ): """Worker function for context parallel backward pass testing.""" try: # Set up distributed environment os.environ["MASTER_ADDR"] = "localhost" os.environ["MASTER_PORT"] = str(master_port) os.environ["RANK"] = str(rank) os.environ["WORLD_SIZE"] = str(world_size) # Get device configuration device_config = DEVICE_CONFIG.get(torch_device, DEVICE_CONFIG["cuda"]) backend = device_config["backend"] device_module = device_config["module"] # Initialize process group dist.init_process_group(backend=backend, rank=rank, world_size=world_size) # Set device for this process device_module.set_device(rank) device = torch.device(f"{torch_device}:{rank}") # Create model in training mode model = model_class(**init_dict) model.to(device) model.train() # Move inputs to device inputs_on_device = {k: v.to(device) if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} # Enable context parallelism cp_config = ContextParallelConfig(**cp_dict) model.enable_parallelism(config=cp_config) # Run forward and backward pass output = model(**inputs_on_device, return_dict=False)[0] loss = output.sum() loss.backward() # Check that backward actually produced at least one valid gradient grads = [p.grad for p in model.parameters() if p.requires_grad and p.grad is not None] has_valid_grads = len(grads) > 0 and all(torch.isfinite(g).all() for g in grads) # Only rank 0 reports results if rank == 0: return_dict["status"] = "success" return_dict["has_valid_grads"] = bool(has_valid_grads) except Exception as e: if rank == 0: return_dict["status"] = "error" return_dict["error"] = str(e) finally: if dist.is_initialized(): dist.destroy_process_group() def _custom_mesh_worker( rank, world_size, master_port, model_class, init_dict, cp_dict, mesh_shape, mesh_dim_names, inputs_dict, return_dict, ): """Worker function for context parallel testing with a user-provided custom DeviceMesh.""" try: os.environ["MASTER_ADDR"] = "localhost" os.environ["MASTER_PORT"] = str(master_port) os.environ["RANK"] = str(rank) os.environ["WORLD_SIZE"] = str(world_size) # Get device configuration device_config = DEVICE_CONFIG.get(torch_device, DEVICE_CONFIG["cuda"]) backend = device_config["backend"] device_module = device_config["module"] dist.init_process_group(backend=backend, rank=rank, world_size=world_size) # Set device for this process device_module.set_device(rank) device = torch.device(f"{torch_device}:{rank}") model = model_class(**init_dict) model.to(device) model.eval() inputs_on_device = {k: v.to(device) if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} # DeviceMesh must be created after init_process_group, inside each worker process. mesh = torch.distributed.device_mesh.init_device_mesh( torch_device, mesh_shape=mesh_shape, mesh_dim_names=mesh_dim_names ) cp_config = ContextParallelConfig(**cp_dict, mesh=mesh) model.enable_parallelism(config=cp_config) with torch.no_grad(): output = model(**inputs_on_device, return_dict=False)[0] if rank == 0: return_dict["status"] = "success" return_dict["output_shape"] = list(output.shape) except Exception as e: if rank == 0: return_dict["status"] = "error" return_dict["error"] = str(e) finally: if dist.is_initialized(): dist.destroy_process_group() @is_context_parallel @require_torch_multi_accelerator class ContextParallelTesterMixin: @pytest.mark.parametrize("cp_type", ["ulysses_degree", "ring_degree"], ids=["ulysses", "ring"]) def test_context_parallel_inference(self, cp_type, batch_size: int = 1): if not torch.distributed.is_available(): pytest.skip("torch.distributed is not available.") if not hasattr(self.model_class, "_cp_plan") or self.model_class._cp_plan is None: pytest.skip("Model does not have a _cp_plan defined for context parallel inference.") if cp_type == "ring_degree": active_backend, _ = _AttentionBackendRegistry.get_active_backend() if active_backend == AttentionBackendName.NATIVE: pytest.skip("Ring attention is not supported with the native attention backend.") world_size = 2 init_dict = self.get_init_dict() inputs_dict = self.get_dummy_inputs(batch_size=batch_size) # Move all tensors to CPU for multiprocessing inputs_dict = {k: v.cpu() if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} cp_dict = {cp_type: world_size} # Find a free port for distributed communication master_port = _find_free_port() # Use multiprocessing manager for cross-process communication manager = mp.Manager() return_dict = manager.dict() # Spawn worker processes mp.spawn( _context_parallel_worker, args=(world_size, master_port, self.model_class, init_dict, cp_dict, inputs_dict, return_dict), nprocs=world_size, join=True, ) assert return_dict.get("status") == "success", ( f"Context parallel inference failed: {return_dict.get('error', 'Unknown error')}" ) @pytest.mark.parametrize("cp_type", ["ulysses_degree", "ring_degree"], ids=["ulysses", "ring"]) def test_context_parallel_batch_inputs(self, cp_type): self.test_context_parallel_inference(cp_type, batch_size=2) @pytest.mark.parametrize("cp_type", ["ulysses_degree", "ring_degree"], ids=["ulysses", "ring"]) def test_context_parallel_backward(self, cp_type, batch_size: int = 1): if not torch.distributed.is_available(): pytest.skip("torch.distributed is not available.") if not hasattr(self.model_class, "_cp_plan") or self.model_class._cp_plan is None: pytest.skip("Model does not have a _cp_plan defined for context parallel inference.") if cp_type == "ring_degree": active_backend, _ = _AttentionBackendRegistry.get_active_backend() if active_backend == AttentionBackendName.NATIVE: pytest.skip("Ring attention is not supported with the native attention backend.") world_size = 2 init_dict = self.get_init_dict() inputs_dict = self.get_dummy_inputs(batch_size=batch_size) # Move all tensors to CPU for multiprocessing inputs_dict = {k: v.cpu() if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} cp_dict = {cp_type: world_size} # Find a free port for distributed communication master_port = _find_free_port() # Use multiprocessing manager for cross-process communication manager = mp.Manager() return_dict = manager.dict() # Spawn worker processes mp.spawn( _context_parallel_backward_worker, args=(world_size, master_port, self.model_class, init_dict, cp_dict, inputs_dict, return_dict), nprocs=world_size, join=True, ) assert return_dict.get("status") == "success", ( f"Context parallel backward pass failed: {return_dict.get('error', 'Unknown error')}" ) assert return_dict.get("has_valid_grads"), "Context parallel backward pass did not produce valid gradients." @pytest.mark.parametrize("cp_type", ["ulysses_degree", "ring_degree"], ids=["ulysses", "ring"]) def test_context_parallel_backward_batch_inputs(self, cp_type): self.test_context_parallel_backward(cp_type, batch_size=2) @pytest.mark.parametrize( "cp_type,mesh_shape,mesh_dim_names", [ ("ring_degree", (2, 1, 1), ("ring", "ulysses", "fsdp")), ("ulysses_degree", (1, 2, 1), ("ring", "ulysses", "fsdp")), ], ids=["ring-3d-fsdp", "ulysses-3d-fsdp"], ) def test_context_parallel_custom_mesh(self, cp_type, mesh_shape, mesh_dim_names): if not torch.distributed.is_available(): pytest.skip("torch.distributed is not available.") if not hasattr(self.model_class, "_cp_plan") or self.model_class._cp_plan is None: pytest.skip("Model does not have a _cp_plan defined for context parallel inference.") if cp_type == "ring_degree": active_backend, _ = _AttentionBackendRegistry.get_active_backend() if active_backend == AttentionBackendName.NATIVE: pytest.skip("Ring attention is not supported with the native attention backend.") world_size = 2 init_dict = self.get_init_dict() inputs_dict = {k: v.cpu() if isinstance(v, torch.Tensor) else v for k, v in self.get_dummy_inputs().items()} cp_dict = {cp_type: world_size} master_port = _find_free_port() manager = mp.Manager() return_dict = manager.dict() mp.spawn( _custom_mesh_worker, args=( world_size, master_port, self.model_class, init_dict, cp_dict, mesh_shape, mesh_dim_names, inputs_dict, return_dict, ), nprocs=world_size, join=True, ) assert return_dict.get("status") == "success", ( f"Custom mesh context parallel inference failed: {return_dict.get('error', 'Unknown error')}" ) @is_attention @is_context_parallel @require_torch_multi_accelerator class ContextParallelAttentionBackendsTesterMixin: unsupported_attn_backends: list[str] = [] @pytest.mark.parametrize("cp_type", ["ulysses_degree", "ring_degree"]) @pytest.mark.parametrize( "attention_backend", [ "native", pytest.param( "flash_hub", marks=pytest.mark.skipif(not is_kernels_available(), reason="`kernels` is not available."), ), pytest.param( "flash_varlen_hub", marks=pytest.mark.skipif(not is_kernels_available(), reason="`kernels` is not available."), ), pytest.param( "_flash_3_hub", marks=pytest.mark.skipif(not is_kernels_available(), reason="`kernels` is not available."), ), ], ) @pytest.mark.parametrize("ulysses_anything", [True, False]) @torch.no_grad() def test_context_parallel_attn_backend_inference(self, cp_type, attention_backend, ulysses_anything): if not torch.distributed.is_available(): pytest.skip("torch.distributed is not available.") if getattr(self.model_class, "_cp_plan", None) is None: pytest.skip("Model does not have a _cp_plan defined for context parallel inference.") if attention_backend in self.unsupported_attn_backends: pytest.skip(f"{attention_backend} is not supported for this model.") if cp_type == "ring_degree": if attention_backend == AttentionBackendName.NATIVE: pytest.skip("Skipping test because ring isn't supported with native attention backend.") elif attention_backend in ("flash_varlen_hub"): pytest.skip("`ring_degree` is not yet supported for varlen attention hub kernels.") if ulysses_anything and "ulysses" not in cp_type: pytest.skip("Skipping test as ulysses anything needs the ulysses degree set.") world_size = 2 init_dict = self.get_init_dict() inputs_dict = self.get_dummy_inputs() # Move all tensors to CPU for multiprocessing inputs_dict = {k: v.cpu() if isinstance(v, torch.Tensor) else v for k, v in inputs_dict.items()} cp_dict = {cp_type: world_size} if ulysses_anything: cp_dict.update({"ulysses_anything": ulysses_anything}) # Find a free port for distributed communication master_port = _find_free_port() # Use multiprocessing manager for cross-process communication manager = mp.Manager() return_dict = manager.dict() # Spawn worker processes mp.spawn( _context_parallel_worker, args=( world_size, master_port, self.model_class, init_dict, cp_dict, inputs_dict, return_dict, attention_backend, ), nprocs=world_size, join=True, ) assert return_dict.get("status") == "success", ( f"Context parallel inference failed: {return_dict.get('error', 'Unknown error')}" )