LoRA-GA: Low-Rank Adaptation with Gradient Approximation
Introduction
LoRA-GA improves upon standard LoRA by using gradient information during initialization instead of random initialization. By performing SVD on estimated gradients, LoRA-GA initializes adapter weights in a direction that aligns with full fine-tuning, achieving 2-4x faster convergence while maintaining the same final performance. The method is orthogonal to existing LoRA variants and can be easily integrated with techniques like DoRA and LoRA+.
Quick start
This example script demonstrates how to fine-tune a language model using LoRA-GA on the WikiText-2 dataset. The script performs gradient estimation on a small number of batches, uses those gradients to initialize LoRA adapters, and then trains the model with the Hugging Face Trainer.
import torch
from datasets import load_dataset
from transformers import AutoTokenizer, AutoModelForCausalLM, Trainer, TrainingArguments
from torch.utils.data import DataLoader
from peft import LoraConfig, get_peft_model
from peft.tuners.lora import LoraGAConfig, preprocess_loraga
# Load model and tokenizer
model = AutoModelForCausalLM.from_pretrained("gpt2")
tokenizer = AutoTokenizer.from_pretrained("gpt2")
dataset = load_dataset("wikitext", "wikitext-2-raw-v1")
# Prepare dataloader for gradient estimation
train_dataloader = DataLoader(dataset["train"], batch_size=2, shuffle=True)
# Define train_step callback for gradient estimation
def train_step():
"""Run forward and backward passes for gradient estimation."""
data_iter = iter(train_dataloader)
for _ in range(64): # 64 iterations
batch = next(data_iter)
outputs = model(**batch)
loss = outputs.loss
loss.backward()
# Step 1: Create LoRA-GA config
lora_ga_config = LoraGAConfig(
direction="ArB2r",
scale="stable",
stable_gamma=16,
)
lora_config = LoraConfig(
r=8,
lora_alpha=16,
target_modules=["c_attn"],
init_lora_weights="lora_ga",
lora_ga_config=lora_ga_config,
task_type="CAUSAL_LM",
)
# Step 2: Preprocess with LoRA-GA to estimate gradients
preprocess_loraga(model, lora_config, train_step)
# Step 3: Create PEFT model with LoRA-GA initialization
peft_model = get_peft_model(model, lora_config)
# Step 4: Train normally
trainer = Trainer(
model=peft_model,
train_dataset=dataset["train"],
args=TrainingArguments(output_dir="./output", num_train_epochs=3),
)
trainer.train()
# Step 5: Save the trained adapter
peft_model.save_pretrained("./output")
Saving with Modified Base Weights
Important: LoRA-GA modifies the base model weights during initialization (unlike standard LoRA). This means you need to handle saving carefully if you want to restore the original base weights.
Option 1: Save adapter only (default)
The standard save_pretrained() saves the adapter with the modified base weights embedded:
# This saves the adapter - base weights remain modified
peft_model.save_pretrained("./output")
Option 2: Restore original base weights
If you need to restore the original base weights (e.g., for model merging or sharing), use path_initial_model_for_weight_conversion:
# Save the original model BEFORE LoRA-GA preprocessing
model.save_pretrained("./original_model")
# ... do preprocessing and training ...
# Save adapter and convert back to original base weights
peft_model.save_pretrained(
"./output",
path_initial_model_for_weight_conversion="./original_model"
)
This is useful when:
- You want to merge the adapter with the original base weights later
- You're sharing the adapter and want users to apply it to the unmodified base model
- You need the base model weights in their original state for other purposes
Run the finetuning script
Simply run:
python examples/lora_ga_finetuning/lora_ga_finetuning.py \
--base_model gpt2 \
--dataset_name wikitext \
--dataset_config wikitext-2-raw-v1 \
--output_dir ./lora_ga_output
Customize LoRA-GA parameters
You can customize the direction and scaling strategies:
python examples/lora_ga_finetuning/lora_ga_finetuning.py \
--base_model gpt2 \
--direction ArB2r \
--scale stable \
--stable_gamma 16 \
--grad_estimate_iters 64
Full example with all parameters
python lora_ga_finetuning.py \
--base_model "gpt2" \
--dataset_name "wikitext" \
--dataset_config "wikitext-2-raw-v1" \
--output_dir "./lora_ga_output" \
--r 8 \
--lora_alpha 16 \
--lora_dropout 0.1 \
--direction "ArB2r" \
--scale "stable" \
--stable_gamma 16 \
--grad_estimate_iters 64 \
--grad_estimate_batch_size 2 \
--num_epochs 3 \
--batch_size 8 \
--learning_rate 3e-5
Configuration Options
Direction Strategies
Controls how SVD components are distributed to lora_A and lora_B:
ArBr: Alternating distribution - A takes odd indices, B takes even indicesA2rBr: A takes second half, B takes first halfArB2r(default): A takes first half, B takes second half - typically performs bestrandom: Random selection of singular vectors
Scaling Strategies
Controls initialization magnitude:
stable(default): Conservative scaling using stable_gamma parameter for stable trainingweight_svd: Scales based on SVD of original weights for better alignmentgd_scale: Scales based on gradient descent step sizeunit: Unit scaling (no adjustment)
Use the model on 🤗
You can load and use the model as any other 🤗 models:
from transformers import AutoModelForCausalLM
from peft import PeftModel
model = AutoModelForCausalLM.from_pretrained("gpt2")
model = PeftModel.from_pretrained(model, "path/to/lora_ga_output")
LoRA-GA vs. LoRA
Key differences and advantages:
-
Faster Convergence: LoRA-GA achieves 2-4x faster convergence compared to standard LoRA due to gradient-aligned initialization.
-
Same Final Performance: LoRA-GA maintains the same or better final performance as standard LoRA.
-
Initialization Overhead: LoRA-GA requires a gradient estimation phase (typically 1-2 minutes for 64 iterations), but this is quickly amortized during training.
-
Orthogonal to Other Methods: LoRA-GA can be combined with DoRA, LoRA+, quantization, and other LoRA enhancements.
API Design
LoRA-GA follows the same pattern as PiSSA, OLoRA, and CorDA:
- Preprocessing: Use
preprocess_loraga(model, lora_config, train_step)to estimate gradients and attach them to model layers - Configuration: Use
LoraGAConfigas a sub-config withinLoraConfigwithinit_lora_weights="lora_ga" - Initialization: Call
get_peft_model()after preprocessing to create the PEFT model with LoRA-GA initialization - Training: Train normally using Hugging Face Trainer or your own training loop
- Saving: Use standard
save_pretrained()to save the trained adapter
Using LoRA-GA with Quantized Models
LoRA-GA requires full-precision gradients during preprocessing. For quantized models (e.g., BitsAndBytes 4-bit/8-bit), use a two-stage workflow:
Step 1: Estimate gradients with full-precision model
import torch
from transformers import AutoModelForCausalLM, BitsAndBytesConfig
from peft import LoraConfig, get_peft_model
from peft.tuners.lora import LoraGAConfig, preprocess_loraga
# Load model in full precision for gradient estimation
model = AutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-2-7b-hf",
torch_dtype=torch.bfloat16,
device_map="auto"
)
# Configure LoRA-GA
lora_config = LoraConfig(
r=8,
target_modules=["q_proj", "v_proj"],
init_lora_weights="lora_ga",
lora_ga_config=LoraGAConfig(direction="ArB2r", scale="stable"),
)
# Define your train_step (same as before)
def train_step():
for _ in range(64):
# Your training logic here
outputs = model(**batch)
loss = outputs.loss
loss.backward()
# Estimate and cache gradients
preprocess_loraga(model, lora_config, train_step, cache_file="loraga_gradients.pt")
# Clean up full-precision model
del model
torch.cuda.empty_cache()
Step 2: Load quantized model and apply LoRA-GA
# Load model with quantization
quantization_config = BitsAndBytesConfig(load_in_4bit=True)
model = AutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-2-7b-hf",
quantization_config=quantization_config,
device_map="auto"
)
# Apply LoRA-GA - gradients will be loaded from cache automatically
peft_model = get_peft_model(model, lora_config)
# Train normally
trainer.train()
Key points:
- Gradient estimation must use a non-quantized model (full precision or bfloat16/float16)
- Cache gradients with
cache_fileparameter to avoid re-computation - Cached gradients are automatically loaded when applying LoRA to the quantized model
- This workflow allows memory-efficient training with quantized models while benefiting from LoRA-GA's faster convergence
Tips
-
Gradient Estimation: 64-128 iterations is typically sufficient. More iterations provide more accurate estimation but increase initialization time.
-
Batch Size: Use smaller batch sizes (2-4) for gradient estimation to maximize gradient diversity.
-
Direction and Scale: The default
direction="ArB2r"andscale="stable"work well in most cases. -
User-Defined Callback: The
train_stepcallback gives you full control over the gradient estimation process. You can customize batching, loss functions, and more. -
Gradient Accumulation: Do NOT call
model.zero_grad()oroptimizer.zero_grad()inside yourtrain_stepcallback. LoRA-GA relies on PyTorch's natural gradient accumulation across iterations.
Citation
@article{wang2024loraga,
title={LoRA-GA: Low-Rank Adaptation with Gradient Approximation},
author={Wang, Shaowen and Zhu, Linxi and Ding, Hengyuan and Liu, Jiaqi and Chen, Jiaming and Zhu, Kaikai and Pang, Wei and Zhu, Jun and You, Yang},
journal={arXiv preprint arXiv:2407.05000},
year={2024}
}