instructlab-training 0.0.2

Training Library

InstructLab Training Library

In order to simplify the process of fine-tuning models through the LAB method, this library provides a simple training interface.

Installation

To get started with the library, you must clone this repo and install it from source via pip:

# clone the repo and switch to the directory
git clone https://github.com/instructlab/training
cd training

# install the library
pip install .

For development, install it instead with pip install -e . instead to make local changes while using this library elsewhere.

Installing Additional NVIDIA packages

We make use of flash-attn and other packages which rely on NVIDIA-specific CUDA tooling to be installed.

If you are using NVIDIA hardware with CUDA, please install the additional dependencies via:

# for a regular install
pip install .[cuda]

# or, for an editable install (development)
pip install -e .[cuda]

Usage

Using the library is fairly straightforward, import the necessary items,

from instructlab.training import (
    run_training,
    TorchrunArgs,
    TrainingArgs,
    DeepSpeedOptions
)

Then, define the training arguments which will serve as the parameters for our training run:

# define training-specific arguments
training_args = TrainingArgs(
    # define data-specific arguments
    model_path = "ibm-granite/granite-7b-base",
    data_path = "path/to/dataset.jsonl",
    ckpt_output_dir = "data/saved_checkpoints",
    data_output_dir = "data/outputs",

    # define model-trianing parameters
    max_seq_len = 4096,
    max_batch_len = 60000,
    num_epochs = 10,
    effective_batch_size = 3840,
    save_samples = 250000,
    learning_rate = 2e-6,
    warmup_steps = 800,
    is_padding_free = True, # set this to true when using Granite-based models
    random_seed = 42,
)

We'll also need to define the settings for running a multi-process job via torchrun. To do this, create a TorchrunArgs object.

[!TIP] Note, for single-GPU jobs, you can simply set nnodes = 1 and nproc_per_node=1.

torchrun_args = TorchrunArgs(
    nnodes = 1, # number of machines 
    nproc_per_node = 8, # num GPUs per machine
    node_rank = 0, # node rank for this machine
    rdzv_id = 123,
    rdzv_endpoint = '127.0.0.1:12345'
)

Finally, you can just call run_training and this library will handle the rest 🙂.

run_training(
    torchrun_args=torchrun_args,
    training_args=training_args,
)

Customizing TrainingArgs

The TrainingArgs class provides most of the customization options for the training job itself. There are a number of options you can specify, such as setting DeepSpeed config values or running a LoRA training job instead of a full fine-tune.

Here is a breakdown of the general options:

Field	Description
model_path	Either a reference to a HuggingFace repo or a path to a model saved in the HuggingFace format.
data_path	A path to the .jsonl training dataset. This is expected to be in the messages format.
ckpt_output_dir	Directory where trained model checkpoints will be saved.
data_output_dir	Directory where we'll store all other intermediary data such as log files, the processed dataset, etc.
max_seq_len	The maximum sequence length to be included in the training set. Samples exceeding this length will be dropped.
max_batch_len	The maximum length of all training batches that we intend to handle in a single step. Used as part of the multipack calculation. If running into out-of-memory errors, try to lower this value, but not below the max_seq_len.
num_epochs	Number of epochs to run through before stopping.
effective_batch_size	The amount of samples in a batch to see before we update the model parameters. Higher values lead to better learning performance.
save_samples	Number of samples the model should see before saving a checkpoint. Consider this to be the checkpoint save frequency. The amount of storage used for a single training run will usually be 4GB * len(dataset) / save_samples
learning_rate	How fast we optimize the weights during gradient descent. Higher values may lead to unstable learning performance. It's generally recommended to have a low learning rate with a high effective batch size.
warmup_steps	The number of steps a model should go through before reaching the full learning rate. We start at 0 and linearly climb up to learning_rate.
is_padding_free	Boolean value to indicate whether or not we're training a padding-free transformer model such as Granite.
random_seed	The random seed PyTorch will use.
mock_data	Whether or not to use mock, randomly generated, data during training. For debug purposes
mock_data_len	Max length of a single mock data sample. Equivalent to max_seq_len but for mock data.
deepspeed_options	Config options to specify for the DeepSpeed optimizer.
lora	Options to specify if you intend to perform a LoRA train instead of a full fine-tune.

DeepSpeedOptions

We only currently support a few options in DeepSpeedOptions: The default is to run with DeepSpeed, so these options only currently allow you to customize aspects of the ZeRO stage 2 optimizer.

Field	Description
cpu_offload_optimizer	Whether or not to do CPU offloading in DeepSpeed stage 2.

loraOptions

If you'd like to do a LoRA train, you can specify a LoRA option to TrainingArgs via the LoraOptions object.

from instructlab.training import LoraOptions, TrainingArgs

training_args = TrainingArgs(
    lora = LoraOptions(
        rank = 4,
        alpha = 32,
        dropout = 0.1,
    ),
    # ...
)

Here is the definition for what we currently support today:

Field	Description
rank	The rank parameter for LoRA training.
alpha	The alpha parameter for LoRA training.
dropout	The dropout rate for LoRA training.
target_modules	The list of target modules for LoRA training.
quantize_data_type	The data type for quantization in LoRA training. Valid options are None and "nf4"

Customizing TorchrunArgs

When running the training script, we always invoke torchrun.

If you are running a single-GPU system or something that doesn't otherwise require distributed training configuration, you can just create a default object:

run_training(
    torchrun_args=TorchrunArgs(),
    training_args=TrainingArgs(
        # ...
    ),
)

However, if you want to specify a more complex configuration, we currently expose all of the options that torchrun accepts today.

![NOTE] For more information about the torchrun arguments, please consult the torchrun documentation.

For example, in a 8-GPU, 2-machine system, we would specify the following torchrun config:

MASTER_ADDR = os.getenv('MASTER_ADDR')
MASTER_PORT = os.getnev('MASTER_PORT')
RDZV_ENDPOINT = f'{MASTER_ADDR}:{MASTER_PORT}'

# on machine 1
torchrun_args = TorchrunArgs(
    nnodes = 2, # number of machines 
    nproc_per_node = 4, # num GPUs per machine
    node_rank = 0, # node rank for this machine
    rdzv_id = 123,
    rdzv_endpoint = RDZV_ENDPOINT
)

run_training(
    torchrun_args=torchrun_args,
    training_args=training_args
)

MASTER_ADDR = os.getenv('MASTER_ADDR')
MASTER_PORT = os.getnev('MASTER_PORT')
RDZV_ENDPOINT = f'{MASTER_ADDR}:{MASTER_PORT}'

# on machine 2
torchrun_args = TorchrunArgs(
    nnodes = 2, # number of machines 
    nproc_per_node = 4, # num GPUs per machine
    node_rank = 1, # node rank for this machine
    rdzv_id = 123,
    rdzv_endpoint = f'{MASTER_ADDR}:{MASTER_PORT}'
)

run_training(
    torch_args=torchrun_args,
    train_args=training_args
)