# Copyright 2023-2024 SGLang Team # 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. # ============================================================================== """PyTorch hooks for layerwise NVTX profiling.""" import torch import torch.cuda.nvtx as nvtx class PytHooks(object): """This module contains all the code needed to enable forward hooks in a pytorch network. To register the hooks for a given network, the user needs to instantiate a PytHook object. Then call the register_hooks method. Example: my_hook = PytHook() my_hook.register_hooks(my_network_model) """ def __init__(self): """Initialize module variables Returns: None: Raises: None: """ super().__init__() self.module_to_name_map = {} @staticmethod def print_tensor(tensor_obj, prefix, tensor_list=None): """Descends iterators that contains Tensors and prints the Tensor Recursive function that descends iterator type arguments until it finds a Tensor object. Args: tensor_obj: Could be a Tensor or an iterator type that contains Tensors prefix: String name to assign to the Tensor tensor_list: List to accumulate tensor dimensions Returns: List of tensor dimensions Raises: None: """ if tensor_list is None: tensor_list = [] if isinstance(tensor_obj, list) or isinstance(tensor_obj, tuple): for ten in tensor_obj: tensor_list = PytHooks.print_tensor(ten, prefix, tensor_list) elif isinstance(tensor_obj, torch.Tensor): tensor_dims = list(tensor_obj.size()) tensor_list.append(tensor_dims) return tensor_list def process_layer_params(self, module_obj): """Extract the static parameters from LLM and VLM relevant layer types Args: module_obj(class): Module state data structure. Returns: param_info(dict): Parameter meta_data for the given op. Raises: None """ param_info = {} # Extract parameters for layers commonly used in LLMs and VLMs if ( isinstance(module_obj, torch.nn.Conv1d) or isinstance(module_obj, torch.nn.Conv2d) or isinstance(module_obj, torch.nn.Conv3d) ): conv_params = {} conv_params["in_chan"] = module_obj.in_channels conv_params["out_chan"] = module_obj.out_channels conv_params["filter_dim"] = module_obj.kernel_size conv_params["stride"] = module_obj.stride conv_params["padding"] = module_obj.padding conv_params["dilation"] = module_obj.dilation conv_params["transposed"] = module_obj.transposed conv_params["output_padding"] = module_obj.output_padding conv_params["groups"] = module_obj.groups conv_params["padding_mode"] = module_obj.padding_mode param_info = conv_params elif ( isinstance(module_obj, torch.nn.ConvTranspose1d) or isinstance(module_obj, torch.nn.ConvTranspose2d) or isinstance(module_obj, torch.nn.ConvTranspose3d) ): convtranspose_params = {} convtranspose_params["in_chan"] = module_obj.in_channels convtranspose_params["out_chan"] = module_obj.out_channels convtranspose_params["filter_dim"] = module_obj.kernel_size convtranspose_params["stride"] = module_obj.stride convtranspose_params["padding"] = module_obj.padding convtranspose_params["dilation"] = module_obj.dilation convtranspose_params["transposed"] = module_obj.transposed convtranspose_params["output_padding"] = module_obj.output_padding convtranspose_params["groups"] = module_obj.groups convtranspose_params["padding_mode"] = module_obj.padding_mode param_info = convtranspose_params elif ( isinstance(module_obj, torch.nn.MaxPool1d) or isinstance(module_obj, torch.nn.MaxPool2d) or isinstance(module_obj, torch.nn.MaxPool3d) ): def _handle_int_or_tuple(parameter): if isinstance(parameter, tuple): return list(parameter) elif isinstance(parameter, int): return [parameter, parameter] pooling_params = {} pooling_params["filter_dim"] = _handle_int_or_tuple(module_obj.kernel_size) pooling_params["stride"] = _handle_int_or_tuple(module_obj.stride) pooling_params["padding"] = _handle_int_or_tuple(module_obj.padding) pooling_params["dilation"] = _handle_int_or_tuple(module_obj.dilation) param_info = pooling_params elif ( isinstance(module_obj, torch.nn.AvgPool1d) or isinstance(module_obj, torch.nn.AvgPool2d) or isinstance(module_obj, torch.nn.AvgPool3d) ): pooling_params = {} pooling_params["filter_dim"] = [ module_obj.kernel_size, module_obj.kernel_size, ] pooling_params["stride"] = [module_obj.stride, module_obj.stride] pooling_params["padding"] = [module_obj.padding, module_obj.padding] pooling_params["ceil_mode"] = module_obj.ceil_mode pooling_params["count_include_pad"] = module_obj.count_include_pad param_info = pooling_params elif ( isinstance(module_obj, torch.nn.AdaptiveAvgPool1d) or isinstance(module_obj, torch.nn.AdaptiveAvgPool2d) or isinstance(module_obj, torch.nn.AdaptiveAvgPool3d) ): pooling_params = {} pooling_params["output_size"] = [ module_obj.output_size, module_obj.output_size, ] param_info = pooling_params elif isinstance(module_obj, torch.nn.Linear): param_info["in_features"] = module_obj.in_features param_info["out_features"] = module_obj.out_features elif ( isinstance(module_obj, torch.nn.BatchNorm1d) or isinstance(module_obj, torch.nn.BatchNorm2d) or isinstance(module_obj, torch.nn.BatchNorm3d) ): param_info["num_features"] = module_obj.num_features param_info["epsilon"] = module_obj.eps param_info["momentum"] = module_obj.momentum elif isinstance(module_obj, torch.nn.ReLU): param_info["in_place"] = module_obj.inplace elif isinstance(module_obj, torch.nn.Dropout): param_info["p"] = module_obj.p param_info["in_place"] = module_obj.inplace elif isinstance(module_obj, torch.nn.Embedding): param_info["num_embeddings"] = module_obj.num_embeddings param_info["embedding_dim"] = module_obj.embedding_dim elif isinstance( module_obj, ( torch.nn.Upsample, torch.nn.UpsamplingNearest2d, torch.nn.UpsamplingBilinear2d, ), ): param_info["scale_factor"] = module_obj.scale_factor return param_info def module_fwd_hook(self, module_obj, in_tensor, out_tensor): """Callback function that ends the NVTX marker Records the module name and tensor information Called after the module executes the forward method. Args: module_obj: Pointer to the module object in_tensor: Input tensor or list of tensors out_tensor: Output tensor of the resulting forward operator Returns: None: Raises: None: """ nvtx.range_pop() return def module_fwd_pre_hook(self, module_obj, in_tensor): """Creates an NVTX marker with the module name in it. This function is called before the module executes Args: module_obj: Module object data structure - used to get unique module name in_tensor: Input tensor data structure Returns: None Raises: None """ marker_dict = {} module_name = self.module_to_name_map.get(module_obj, "unknown") marker_dict["Module"] = module_name ## Get trainable parameters like weights and bias module_params = module_obj.named_parameters(recurse=False) for idx, (param_name, param_obj) in enumerate(module_params): if idx == 0: marker_dict["TrainableParams"] = {} marker_dict["TrainableParams"][param_name] = list(param_obj.size()) in_tensor_list = PytHooks.print_tensor(in_tensor, "Input") if in_tensor_list: marker_dict["Inputs"] = in_tensor_list param_info = self.process_layer_params(module_obj) if param_info: marker_dict["StaticParams"] = param_info nvtx.range_push("{}".format(marker_dict)) return def register_hooks(self, network_model, module_prefix="top"): """User level function that activates all the hooks The user needs to call this method from the network source code The code descends all the modules in the network and registers their respective hooks. Args: network_model: Model object for the network module_prefix: (default: top) Returns: None Raises: Exception if a module instance is reused """ # Module types to skip (simple operations that don't need detailed profiling) skip_types = ( torch.nn.Identity, torch.nn.Dropout, torch.nn.Dropout1d, torch.nn.Dropout2d, torch.nn.Dropout3d, ) for name, module in network_model.named_modules(prefix=module_prefix): # Skip certain module types to reduce profiling overhead if isinstance(module, skip_types): continue module.register_forward_pre_hook(self.module_fwd_pre_hook) module.register_forward_hook(self.module_fwd_hook) if module not in self.module_to_name_map: self.module_to_name_map[module] = name else: raise ValueError("Module instance {} is not unique ".format(module)) return