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peft-fine-tuning

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by firecrawl · part of firecrawl/ai-research-skills

Parameter-efficient fine-tuning for LLMs using LoRA, QLoRA, and 25+ methods. Use when fine-tuning large models (7B-70B) with limited GPU memory, when you need to train <1% of parameters with minimal accuracy loss, or for multi-adapter serving. HuggingFace's official library integrated with transformers ecosystem.

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🧩 One of 7 skills in the firecrawl/ai-research-skills package — works on its own, and pairs well with its siblings.

This is the playbook your agent receives when the skill activates — you don't need to read it to use the skill, but it's here to audit before installing.

PEFT (Parameter-Efficient Fine-Tuning)

Fine-tune LLMs by training <1% of parameters using LoRA, QLoRA, and 25+ adapter methods.

When to use PEFT

Use PEFT/LoRA when:

  • Fine-tuning 7B-70B models on consumer GPUs (RTX 4090, A100)
  • Need to train <1% parameters (6MB adapters vs 14GB full model)
  • Want fast iteration with multiple task-specific adapters
  • Deploying multiple fine-tuned variants from one base model

Use QLoRA (PEFT + quantization) when:

  • Fine-tuning 70B models on single 24GB GPU
  • Memory is the primary constraint
  • Can accept ~5% quality trade-off vs full fine-tuning

Use full fine-tuning instead when:

  • Training small models (<1B parameters)
  • Need maximum quality and have compute budget
  • Significant domain shift requires updating all weights

LoRA parameter selection

Rank (r) - capacity vs efficiency

RankTrainable ParamsMemoryQualityUse Case
4~3MMinimalLowerSimple tasks, prototyping
8~7MLowGoodRecommended starting point
16~14MMediumBetterGeneral fine-tuning
32~27MHigherHighComplex tasks
64~54MHighHighestDomain adaptation, 70B models

Alpha (lora_alpha) - scaling factor

# Rule of thumb: alpha = 2 * rank
LoraConfig(r=16, lora_alpha=32)  # Standard
LoraConfig(r=16, lora_alpha=16)  # Conservative (lower learning rate effect)
LoraConfig(r=16, lora_alpha=64)  # Aggressive (higher learning rate effect)

Target modules by architecture

# Llama / Mistral / Qwen
target_modules = ["q_proj", "v_proj", "k_proj", "o_proj", "gate_proj", "up_proj", "down_proj"]

# GPT-2 / GPT-Neo
target_modules = ["c_attn", "c_proj", "c_fc"]

# Falcon
target_modules = ["query_key_value", "dense", "dense_h_to_4h", "dense_4h_to_h"]

# BLOOM
target_modules = ["query_key_value", "dense", "dense_h_to_4h", "dense_4h_to_h"]

# Auto-detect all linear layers
target_modules = "all-linear"  # PEFT 0.6.0+

Loading and merging adapters

Load trained adapter

from peft import PeftModel, AutoPeftModelForCausalLM
from transformers import AutoModelForCausalLM

# Option 1: Load with PeftModel
base_model = AutoModelForCausalLM.from_pretrained("meta-llama/Llama-3.1-8B")
model = PeftModel.from_pretrained(base_model, "./lora-llama-adapter")

# Option 2: Load directly (recommended)
model = AutoPeftModelForCausalLM.from_pretrained(
    "./lora-llama-adapter",
    device_map="auto"
)

Merge adapter into base model

# Merge for deployment (no adapter overhead)
merged_model = model.merge_and_unload()

# Save merged model
merged_model.save_pretrained("./llama-merged")
tokenizer.save_pretrained("./llama-merged")

# Push to Hub
merged_model.push_to_hub("username/llama-finetuned")

Multi-adapter serving

from peft import PeftModel

# Load base with first adapter
model = AutoPeftModelForCausalLM.from_pretrained("./adapter-task1")

# Load additional adapters
model.load_adapter("./adapter-task2", adapter_name="task2")
model.load_adapter("./adapter-task3", adapter_name="task3")

# Switch between adapters at runtime
model.set_adapter("task1")  # Use task1 adapter
output1 = model.generate(**inputs)

model.set_adapter("task2")  # Switch to task2
output2 = model.generate(**inputs)

# Disable adapters (use base model)
with model.disable_adapter():
    base_output = model.generate(**inputs)

PEFT methods comparison

MethodTrainable %MemorySpeedBest For
LoRA0.1-1%LowFastGeneral fine-tuning
QLoRA0.1-1%Very LowMediumMemory-constrained
AdaLoRA0.1-1%LowMediumAutomatic rank selection
IA30.01%MinimalFastestFew-shot adaptation
Prefix Tuning0.1%LowMediumGeneration control
Prompt Tuning0.001%MinimalFastSimple task adaptation
P-Tuning v20.1%LowMediumNLU tasks

IA3 (minimal parameters)

from peft import IA3Config

ia3_config = IA3Config(
    target_modules=["q_proj", "v_proj", "k_proj", "down_proj"],
    feedforward_modules=["down_proj"]
)
model = get_peft_model(model, ia3_config)
# Trains only 0.01% of parameters!

Prefix Tuning

from peft import PrefixTuningConfig

prefix_config = PrefixTuningConfig(
    task_type="CAUSAL_LM",
    num_virtual_tokens=20,      # Prepended tokens
    prefix_projection=True       # Use MLP projection
)
model = get_peft_model(model, prefix_config)

Integration patterns

With TRL (SFTTrainer)

from trl import SFTTrainer, SFTConfig
from peft import LoraConfig

lora_config = LoraConfig(r=16, lora_alpha=32, target_modules="all-linear")

trainer = SFTTrainer(
    model=model,
    args=SFTConfig(output_dir="./output", max_seq_length=512),
    train_dataset=dataset,
    peft_config=lora_config,  # Pass LoRA config directly
)
trainer.train()

With Axolotl (YAML config)

# axolotl config.yaml
adapter: lora
lora_r: 16
lora_alpha: 32
lora_dropout: 0.05
lora_target_modules:
  - q_proj
  - v_proj
  - k_proj
  - o_proj
lora_target_linear: true  # Target all linear layers

With vLLM (inference)

from vllm import LLM
from vllm.lora.request import LoRARequest

# Load base model with LoRA support
llm = LLM(model="meta-llama/Llama-3.1-8B", enable_lora=True)

# Serve with adapter
outputs = llm.generate(
    prompts,
    lora_request=LoRARequest("adapter1", 1, "./lora-adapter")
)

Performance benchmarks

Memory usage (Llama 3.1 8B)

MethodGPU MemoryTrainable Params
Full fine-tuning60+ GB8B (100%)
LoRA r=1618 GB14M (0.17%)
QLoRA r=166 GB14M (0.17%)
IA316 GB800K (0.01%)

Training speed (A100 80GB)

MethodTokens/secvs Full FT
Full FT2,5001x
LoRA3,2001.3x
QLoRA2,1000.84x

Quality (MMLU benchmark)

ModelFull FTLoRAQLoRA
Llama 2-7B45.344.844.1
Llama 2-13B54.854.253.5

Best practices

  1. Start with r=8-16, increase if quality insufficient
  2. Use alpha = 2 * rank as starting point
  3. Target attention + MLP layers for best quality/efficiency
  4. Enable gradient checkpointing for memory savings
  5. Save adapters frequently (small files, easy rollback)
  6. Evaluate on held-out data before merging
  7. Use QLoRA for 70B+ models on consumer hardware

References

Resources