Open Notebook

Friday, December 26, 2025

*** miniforge3 build conda enviroments (yolo 11n run passed )

On wahab, need to switch to bash first.

source ~/miniforge3/etc/profile.d/conda.sh

conda create -n venv_yolo python=3.10 -y

With chatGPT and gemine it took a while to have workable slurm job with gpu request and miniforge environment.

It took about 14 conversation in chatGPT 5.2plus to get a functional slurm job that use miniforge to run yolo 11n inference.

==== the workable slurm job is below===
#!/bin/bash

#SBATCH --job-name=yolo11n_inf_gpu

#SBATCH --partition=timed-gpu

#SBATCH --time=00:10:00

#SBATCH --mem=8G

#SBATCH --cpus-per-task=4

#SBATCH --gres=gpu:1

#SBATCH -o test_yolo11n_gpu.%j.out

#SBATCH -e test_yolo11n_gpu.%j.err

set -euxo pipefail

enable_lmod

module purge

module load container_env

module load python3/2024.2-py310

crun bash -lc '

set -eo pipefail

set -x

# Ensure we run in the directory you submitted from (~/yolo_carla)

cd "$SLURM_SUBMIT_DIR"

echo "PWD=$(pwd)"

ls -lh bus.jpg || true

# Avoid inheriting container conda state

unset CONDA_SHLVL CONDA_PREFIX CONDA_DEFAULT_ENV CONDA_PROMPT_MODIFIER CONDA_PREFIX_1

source "$HOME/miniforge3/etc/profile.d/conda.sh"

set +u

conda activate venv_yolo

set -u

echo "=== GPU CHECK ==="

echo "CUDA_VISIBLE_DEVICES=$CUDA_VISIBLE_DEVICES"

nvidia-smi -L

nvidia-smi

echo "=== TORCH CUDA CHECK ==="

python - <<'"'"'PY'"'"'

import torch

print("torch:", torch.__version__)

print("cuda available:", torch.cuda.is_available())

print("device count:", torch.cuda.device_count())

if torch.cuda.is_available():

print("gpu0:", torch.cuda.get_device_name(0))

echo "=== YOLO11N INFERENCE (GPU) ==="

if [ ! -f yolo11n.pt ]; then

echo "ERROR: yolo11n.pt not found in $PWD"

exit 2

if [ ! -f bus.jpg ]; then

echo "ERROR: bus.jpg not found in $PWD"

exit 3

python - <<'"'"'PY'"'"'

from ultralytics import YOLO

import ultralytics

print("ultralytics:", ultralytics.__version__)

model = YOLO("yolo11n.pt")

# Run on GPU 0

res = model.predict(source="bus.jpg", device=0, imgsz=640, conf=0.25, verbose=False)

r0 = res[0]

n = 0 if r0.boxes is None else len(r0.boxes)

print("boxes:", n)

out_img = "yolo11n_bus_pred.jpg"

r0.save(filename=out_img)

print("saved:", out_img)

gpt use in academics

gpt use in academics, such as ChatGPT or claude.

* typo and format conversion, such as ' in different fonts, removal of special character

* reference format change

* collaborators with affiliations for NSF

* reviewer search

* funding opportunities match

* matching two lists of entries

Friday, December 19, 2025

multi GPU runs

Gemini:
your script is correctly configured for Single-Node, Multi-GPU (8 GPUs) training using PyTorch Distributed Data Parallel (DDP) and SLURM.

You have correctly implemented the "Gradient Coordination" concepts we discussed. Here is a breakdown of why this code works and a few small things to watch out for as you scale.

Why this script is correct:

Orchestration via SLURM: Using srun to launch the Python script is the best practice on clusters. It automatically assigns SLURM_PROCID and SLURM_LOCALID to each process, which you then use to initialize the process group.
The NCCL Backend: You used backend="nccl", which is the high-performance library designed by NVIDIA for the "All-Reduce" gradient synchronization we talked about.
Correct Device Pinning: torch.cuda.set_device(local_rank) ensures that Rank 0 uses GPU 0, Rank 1 uses GPU 1, and so on. Without this, all 8 processes might try to crowd onto GPU 0, leading to an "Out of Memory" (OOM) error.
Data Sharding: By using DistributedSampler, you ensure that each GPU receives a different subset of your 50 records. Without this, every GPU would train on the exact same data, wasting 7/8ths of your compute power.
DDP Wrapper: model = DistributedDataParallel(model, device_ids=[local_rank]) is the magic line. This wraps your model so that during the .backward() call, the GPUs automatically trigger the All-Reduce algorithm to average gradients across the 8 cards.
Clean Saving: You used model.module.state_dict(). This is important because DDP adds a .module. prefix to all parameter names; saving model.module ensures your weights can be loaded later into a normal, non-DDP model.

How the Gradients are Coordinated in this Code

While your code is running, the coordination follows this invisible "choreography":

Compute: Each of the 8 tasks calculates gradients for its local batch of data.
Trigger: As soon as the gradients are ready, torch.nn.parallel.DistributedDataParallel catches the signal.
All-Reduce: The 8 GPUs communicate over the NVLink (the internal high-speed bridge on the A100-8 node). They sum their gradients and divide by 8.
Update: Only after all 8 GPUs have the exact same averaged gradient does the optimizer.step() move the weights forward.

Small Suggestions for Improvement

The "Smoke Test" Math: You have 50 records and 8 GPUs. With a batch_size=8 per GPU, your "Global Batch Size" is 64. Since $50 < 64$ , your code will only run for one single step per epoch, and some GPUs might even receive empty batches depending on how the sampler divides the remainder. For a smoke test, this is fine, but for real training, ensure Total Records >> (Batch Size * Num GPUs).
Data Loading Efficiency: Currently, every one of the 8 processes reads the JSONL files from the disk:
Python
records = read_jsonl_records(paths) # Every process does this
For 50 records, this is instant. If you scale to 50 million records, 8 processes hitting the hard drive at once can cause a "bottleneck." Usually, you want to use a WebDataset or a library like HuggingFace Datasets that streams the data.
Multi-Node Scaling: If you ever move from 8 GPUs (1 node) to 16 GPUs (2 nodes), you will need to change #SBATCH --ntasks-per-node=8 and add #SBATCH --nodes=2. You will also need to ensure MASTER_ADDR is set to the hostname of the first node specifically, rather than just $(hostname) on every node.

Would you like me to show you how to modify the MASTER_ADDR logic so this script works across multiple physical servers (nodes)?