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README.md

Tutel

Tutel MoE: An Optimized Mixture-of-Experts Implementation.

  • Supported Framework: Pytorch (recommend: >= 1.10)
  • Supported GPUs: CUDA(fp64/fp32/fp16/bfp16), ROCm(fp64/fp32/fp16)
  • Supported CPU: fp64/fp32

What's New:

  • Tutel v0.3.1: Add NCCL all_to_all_v and all_gather_v for arbitrary-length message transfers: ```py

    Example:

    All_to_All_v:

    python3 -m torch.distributed.run --nproc_per_node=2 --master_port=7340 -m tutel.examples.nccl_all_to_all_v

    All_Gather_v:

    python3 -m torch.distributed.run --nproc_per_node=2 --master_port=7340 -m tutel.examples.nccl_all_gather_v

How to:

net.batch_all_to_all_v([t_x_cuda, t_y_cuda, ..], common_send_counts)
net.batch_all_gather_v([t_x_cuda, t_y_cuda, ..])

- Tutel v0.3: Add Megablocks solution to improve decoder inference on single-GPU with num_local_expert >= 2:
```py
  >> Example (capacity_factor=0 for dropless-MoE):
    # Using BatchMatmul:
    python3 -m tutel.examples.helloworld --megablocks_size=0 --batch_size=1 --num_tokens=32 --top=1 --eval --num_local_experts=128 --capacity_factor=0
    # Using Megablocks with block_size = 1:
    python3 -m tutel.examples.helloworld --megablocks_size=1 --batch_size=1 --num_tokens=32 --top=1 --eval --num_local_experts=128 --capacity_factor=0
    # Using Megablocks with block_size = 2:
    python3 -m tutel.examples.helloworld --megablocks_size=2 --batch_size=1 --num_tokens=32 --top=1 --eval --num_local_experts=128 --capacity_factor=0

  >> How to:
    self._moe_layer.forward(x, .., megablocks_size=1)         # Control the switch of megablocks_size (0 for disabled)
  • Tutel v0.2: Allow most configurations to be dynamic switchable with free cost: ```py >> Example: python3 -m torch.distributed.run --nproc_per_node=8 -m tutel.examples.helloworld_switch --batch_size=16

How to:

self._moe_layer.forward(x, .., a2a_ffn_overlap_degree=2)  # Control the switch of overlap granularity (1 for no overlapping)
self._moe_layer.forward(x, .., adaptive_r=1)              # Control the switch of parallelism (0 for DP, 1 for DP + EP, W / E for MP + EP, else for DP + MP + EP)
self._moe_layer.forward(x, .., capacity_factor=1)         # Control the switch of capacity_volume (positive for padding, negative for no-padding, 0 for dropless)
self._moe_layer.forward(x, .., top_k=1)                   # Control the switch of top_k sparsity

- Tutel v0.1: Optimize the Einsum Complexity of Data Dispatch Encoding and Decoding, add 2DH option to deal with All-to-All at scale:
```py
  >> Example (suggest enabling 2DH only at scale, note that the value of --nproc_per_node MUST equal to total physical GPU counts per node, e.g. 8 for A100x8):
    python3 -m torch.distributed.run --nproc_per_node=8 -m tutel.examples.helloworld --batch_size=16 --use_2dh

How to setup Tutel MoE for Pytorch 2 and run examples, or enable fairseq with MoE:

* Prepare Recommended Pytorch >= 2.0.0 (minimal version == 1.8.0):
        #  Windows/Linux Pytorch for NVIDIA CUDA >= 11.7:
        python3 -m pip install torch torchvision torchaudio --index-url https://download.pytorch.org/whl/cu118
        #  Linux Pytorch for AMD ROCm == 5.4.2:
        python3 -m pip install torch torchvision torchaudio --index-url https://download.pytorch.org/whl/rocm5.4.2
        #  Windows/Linux Pytorch for CPU:
        python3 -m pip install torch torchvision torchaudio --index-url https://download.pytorch.org/whl/cpu

* Install Tutel Online:

        $ python3 -m pip uninstall tutel -y
        $ python3 -m pip install setuptools wheel
        $ python3 -m pip install -v -U --no-build-isolation git+https://github.com/microsoft/tutel@main

* Build Tutel from Source:

        $ git clone https://github.com/microsoft/tutel --branch main

        $ python3 -m pip uninstall tutel -y
        $ python3 ./tutel/setup.py install --user

* Quick Test on Single-GPU:

        $ python3 -m tutel.examples.helloworld --batch_size=16               # Test Tutel-optimized MoE + manual distribution
        $ python3 -m tutel.examples.helloworld_ddp --batch_size=16           # Test Tutel-optimized MoE + Pytorch DDP distribution (requires: Pytorch >= 1.8.0)
        $ python3 -m tutel.examples.helloworld_ddp_tutel --batch_size=16     # Test Tutel-optimized MoE + Tutel DDP distribution (ZeRO on optimizors)
        $ python3 -m tutel.examples.helloworld_amp --batch_size=16           # Test Tutel-optimized MoE with AMP data type + manual distribution
        $ python3 -m tutel.examples.helloworld_demo --batch_size=16          # Test Tutel-optimized MoE + custom defined expert layer
        $ python3 -m tutel.examples.helloworld_from_scratch                  # Test Custom MoE implementation from scratch
        $ python3 -m tutel.examples.moe_mnist                                # Test MoE layer in end-to-end MNIST dataset
        $ python3 -m tutel.examples.moe_cifar10                              # Test MoE layer in end-to-end CIFAR10 dataset

        (If building from source, the following method also works:)
        $ python3 ./tutel/examples/helloworld.py --batch_size=16
        ..

* Run Tutel MoE in Distributed Mode:

        (Method A - Torch launcher for `Multi-Node x Multi-GPU`:)
        $ ssh <node-ip-0> python3 -m torch.distributed.run --nproc_per_node=8 --nnodes=2 --node_rank=0 --master_addr=<node-ip-0> -m tutel.examples.helloworld --batch_size=16
        $ ssh <node-ip-1> python3 -m torch.distributed.run --nproc_per_node=8 --nnodes=2 --node_rank=1 --master_addr=<node-ip-0> -m tutel.examples.helloworld --batch_size=16

        (Method B - Tutel launcher for `Multi-Node x Multi-GPU`, requiring package `openmpi-bin`:)
        # << Single Node >>
        $ mpiexec -bind-to none -host localhost -x LOCAL_SIZE=8 python3 -m tutel.launcher.run -m tutel.examples.helloworld_ddp_tutel --batch_size=16
        $ mpiexec -bind-to none -host localhost -x LOCAL_SIZE=8 python3 -m tutel.launcher.run -m tutel.examples.moe_mnist
        $ mpiexec -bind-to none -host localhost -x LOCAL_SIZE=8 python3 -m tutel.launcher.run -m tutel.examples.moe_cifar10
        ...

        # << Cross Nodes >>
        $ mpiexec -bind-to none -host <node-ip-0>,<node-ip-1>,.. -x MASTER_ADDR=<node-ip-0> -x LOCAL_SIZE=8 python3 -m tutel.launcher.run -m tutel.examples.helloworld --batch_size=16

        # << For CPU-based Launch>>
        $ mpiexec -bind-to none -host localhost -x LOCAL_SIZE=1 -x OMP_NUM_THREADS=1024 python3 -m tutel.launcher.run -m tutel.examples.helloworld --batch_size=16 --device cpu

How to convert checkpoint files that adapt to different distributed world sizes:

# Firstly, using 2 GPUs to train a model with 16 global experts (each GPU holds 8 local experts), saving checkpoint files in the end:
mpiexec -bind-to none -host localhost -x LOCAL_SIZE=2 python3 -m tutel.launcher.run -m tutel.examples.helloworld --num_local_experts=8 --checkpoint=./states/{rank}-of-{size}.ckpt --device=cuda

# Secondly, convert the checkpoint files (based on 2 GPUs) into a single checkpoint file containing all parameters:
python3 -m tutel.checkpoint.gather --inputs=./states/{rank}-of-{size}.ckpt --input_size=2 --output ./model-synthetis.ckpt

# Optionally, you can test the synthetis checkpoint using single CPU device, note that there will be 16 experts locally:
python3 -m tutel.examples.helloworld --num_local_experts=16 --checkpoint=./model-synthetis.ckpt --device=cpu --eval

# Next, convert the synthetis checkpoint file that adapts to distributed training using 8 GPUs:
python3 -m tutel.checkpoint.scatter --input=./model-synthetis.ckpt --output_size=8 --outputs=./adapted-for-8-gpus/{rank}-of-{size}.ckpt

# Then, using generated checkpoint files to train/eval using 8 GPUs, note that there will be 2 local experts this time:
mpiexec -bind-to none -host localhost -x LOCAL_SIZE=8 python3 -m tutel.launcher.run -m tutel.examples.helloworld --num_local_experts=2 --checkpoint=./adapted-for-8-gpus/{rank}-of-{size}.ckpt --device=cuda

# Similarly, the convertion tool also supports X global experts adapting to Y GPUs, where Y % X == 0, making num_local_experts to be -Y / X.
python3 -m tutel.checkpoint.scatter --input=./model-synthetis.ckpt --output_size=32 --outputs=./adapted-for-32-gpus/{rank}-of-{size}.ckpt
mpiexec -bind-to none -host localhost -x LOCAL_SIZE=32 python3 -m tutel.launcher.run -m tutel.examples.helloworld --num_local_experts=-2 --checkpoint=./adapted-for-32-gpus/{rank}-of-{size}.ckpt --device=cuda

How to import Tutel-optimized MoE in Pytorch:

# Input Example:
import torch
x = torch.ones([6, 1024], device='cuda:0')

# Create MoE:
from tutel import moe as tutel_moe
moe_layer = tutel_moe.moe_layer(
    gate_type={'type': 'top', 'k': 2},
    model_dim=x.shape[-1],
    experts={
        'count_per_node': 2,
        'type': 'ffn', 'hidden_size_per_expert': 2048, 'activation_fn': lambda x: torch.nn.functional.relu(x)
    },
    scan_expert_func = lambda name, param: setattr(param, 'skip_allreduce', True),
)

# Cast to GPU
moe_layer = moe_layer.to('cuda:0')

# In distributed model, you need further skip doing allreduce on global parameters that have `skip_allreduce` mask, 
# e.g.
#    for p in moe_layer.parameters():
#        if hasattr(p, 'skip_allreduce'):
#            continue
#        dist.all_reduce(p.grad)


# Forward MoE:
y = moe_layer(x)

print(y)

Usage of MOELayer:

* Usage of MOELayer Args:

        gate_type        : dict-type gate description, e.g. {'type': 'top', 'k': 2, 'capacity_factor': -1.5, ..},
                              or a list of dict-type gate descriptions, e.g. [{'type': 'top', 'k', 2}, {'type': 'top', 'k', 2}],
                              the value of k in top-gating can be also negative, like -2, which indicates one GPU will hold 1/(-k) parameters of an expert
                              capacity_factor X can be positive (factor = X), zero (factor = max(needed_volumes)) or negative (factor = min(-X, max(needed_volumes))).
        model_dim        : the number of channels for MOE's input tensor
        experts          : a dict-type config for builtin expert network
        scan_expert_func : allow users to specify a lambda function to iterate each experts param, e.g. `scan_expert_func = lambda name, param: setattr(param, 'expert', True)`
        result_func      : allow users to specify a lambda function to format the MoE output and aux_loss, e.g. `result_func = lambda output: (output, output.l_aux)`
        group            : specify the explicit communication group of all_to_all
        seeds            : a tuple containing a tripple of int to specify manual seed of (shared params, local params, others params after MoE's)
        a2a_ffn_overlap_degree : the value to control a2a overlap depth, 1 by default for no overlap, 2 for overlap a2a with half gemm, ..
        parallel_type    : the parallel method to compute MoE, valid types: 'auto', 'data', 'model'
        pad_samples      : whether do auto padding on newly-coming input data to maximum data size in history

* Usage of dict-type Experts Config:

        count_per_node   : the number of local experts per device (by default, the value is 1 if not specified)
        type             : available built-in experts implementation, e.g: ffn
        hidden_size_per_expert : the hidden size between two linear layers for each expert (used for type == 'ffn' only)
        activation_fn    : the custom-defined activation function between two linear layers (used for type == 'ffn' only)
        has_fc1_bias     : If set to False, the expert bias parameters `batched_fc1_bias` is disabled. Default: True
        has_fc2_bias     : If set to False, the expert bias parameters `batched_fc2_bias` is disabled. Default: True

Reference

You can consult this paper below to get to know more technical details about Tutel:

@article {tutel,
author = {Changho Hwang and Wei Cui and Yifan Xiong and Ziyue Yang and Ze Liu and Han Hu and Zilong Wang and Rafael Salas and Jithin Jose and Prabhat Ram and Joe Chau and Peng Cheng and Fan Yang and Mao Yang and Yongqiang Xiong},
title = {Tutel: Adaptive Mixture-of-Experts at Scale},
year = {2022},
month = jun,
journal = {CoRR},
volume= {abs/2206.03382},
url = {https://arxiv.org/pdf/2206.03382.pdf},
}

Contributing

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