conf_threshold 0.25→0.55: composite +30% (FP/img 6.26→1.09, mAP50 71.8→66.5%)

3383aee verified about 2 months ago

12.7 kB

	"""
	Score Vision SN44 — VehicleDetect miner endpoint.

	Class mapping (output indices):
	0 = car (COCO class 2)
	1 = bus (COCO class 5)
	2 = truck (COCO class 7)
	3 = motorcycle (COCO class 3)

	Accepts: base64-encoded image or raw image bytes via chutes cord.
	Returns: list of {bbox: [x1,y1,x2,y2], score: float, class_id: int, class_name: str}

	CUDA fix: onnxruntime-gpu finds cuDNN via ldconfig (registered during image build),
	with ctypes preload as belt-and-suspenders fallback.
	"""

	from __future__ import annotations

	import base64
	import io
	import os
	import time
	from pathlib import Path
	from typing import Any

	import ctypes
	import cv2
	import numpy as np
	from PIL import Image

	# ── cuDNN preload (belt-and-suspenders fallback) ──────────────────────────────
	# Primary fix is ldconfig at image build time (see Image builder below).
	# This ctypes preload catches any edge cases where ld.so.cache isn't used.
	def _preload_cuda_libs() -> None:
	_NVIDIA = "/usr/local/lib/python3.12/dist-packages/nvidia"
	_LIBS = [
	"/usr/lib/x86_64-linux-gnu/libcuda.so.1", # driver stub — must be first
	f"{_NVIDIA}/cublas/lib/libcublasLt.so.12",
	f"{_NVIDIA}/cublas/lib/libcublas.so.12",
	f"{_NVIDIA}/cudnn/lib/libcudnn.so.9",
	]
	for path in _LIBS:
	if os.path.exists(path):
	try:
	ctypes.CDLL(path, mode=ctypes.RTLD_GLOBAL)
	except OSError:
	pass

	_preload_cuda_libs()

	import onnxruntime as ort # noqa: E402 — must come after preload

	# ── Constants ────────────────────────────────────────────────────────────────
	MODEL_DIR = Path(__file__).parent
	WEIGHTS = MODEL_DIR / "weights.onnx"
	IMG_SIZE = 640
	CONF_THRESH = 0.55 # sweep: max composite score (0.60×mAP + 0.40×FP_score) at conf=0.55
	IOU_THRESH = 0.45

	# COCO class index → submission class index
	COCO_TO_OUT: dict[int, int] = {2: 0, 5: 1, 7: 2, 3: 3}
	COCO_VEHICLE_IDX = list(COCO_TO_OUT.keys())
	OUT_NAMES = ["car", "bus", "truck", "motorcycle"]

	# ── Model loader (singleton) ─────────────────────────────────────────────────
	_SESSION: ort.InferenceSession \| None = None


	def get_session() -> ort.InferenceSession:
	global _SESSION
	if _SESSION is None:
	opts = ort.SessionOptions()
	opts.graph_optimization_level = ort.GraphOptimizationLevel.ORT_ENABLE_ALL
	opts.enable_mem_pattern = True
	opts.enable_mem_reuse = True
	cuda_opts = {
	"device_id": 0,
	"arena_extend_strategy": "kNextPowerOfTwo",
	"gpu_mem_limit": 2 * 1024 ** 3,
	"cudnn_conv_algo_search": "EXHAUSTIVE",
	"do_copy_in_default_stream": True,
	}
	_SESSION = ort.InferenceSession(
	str(WEIGHTS),
	sess_options=opts,
	providers=[
	("CUDAExecutionProvider", cuda_opts),
	"CPUExecutionProvider",
	],
	)
	provider = _SESSION.get_providers()[0]
	print(f"[miner] Model loaded. Provider: {provider}", flush=True)
	return _SESSION


	# ── Preprocessing ────────────────────────────────────────────────────────────

	def letterbox(img: np.ndarray, size: int = IMG_SIZE) -> tuple[np.ndarray, float, int, int]:
	h, w = img.shape[:2]
	r = min(size / h, size / w)
	new_w, new_h = int(round(w * r)), int(round(h * r))
	img_r = cv2.resize(img, (new_w, new_h), interpolation=cv2.INTER_LINEAR)
	dw, dh = size - new_w, size - new_h
	pad_l, pad_t = dw // 2, dh // 2
	img_p = cv2.copyMakeBorder(
	img_r, pad_t, dh - pad_t, pad_l, dw - pad_l,
	cv2.BORDER_CONSTANT, value=(114, 114, 114),
	)
	return img_p, r, pad_l, pad_t


	def preprocess(img_bgr: np.ndarray) -> tuple[np.ndarray, float, int, int]:
	img_p, ratio, pad_l, pad_t = letterbox(img_bgr)
	img_rgb = cv2.cvtColor(img_p, cv2.COLOR_BGR2RGB)
	inp = img_rgb.transpose(2, 0, 1).astype(np.float32) * (1.0 / 255.0)
	return np.ascontiguousarray(inp[np.newaxis]), ratio, pad_l, pad_t


	# ── NMS ──────────────────────────────────────────────────────────────────────

	def nms(boxes: np.ndarray, scores: np.ndarray, iou_thresh: float = IOU_THRESH) -> list[int]:
	if not len(boxes):
	return []
	x1, y1, x2, y2 = boxes[:, 0], boxes[:, 1], boxes[:, 2], boxes[:, 3]
	areas = (x2 - x1) * (y2 - y1)
	order = scores.argsort()[::-1]
	keep: list[int] = []
	while len(order):
	i = order[0]
	keep.append(int(i))
	xx1 = np.maximum(x1[i], x1[order[1:]])
	yy1 = np.maximum(y1[i], y1[order[1:]])
	xx2 = np.minimum(x2[i], x2[order[1:]])
	yy2 = np.minimum(y2[i], y2[order[1:]])
	inter = np.maximum(0, xx2 - xx1) * np.maximum(0, yy2 - yy1)
	iou = inter / (areas[i] + areas[order[1:]] - inter + 1e-7)
	order = order[1:][iou <= iou_thresh]
	return keep


	# ── Postprocessing ───────────────────────────────────────────────────────────

	def postprocess(
	raw: np.ndarray,
	ratio: float,
	pad_l: int,
	pad_t: int,
	orig_w: int,
	orig_h: int,
	) -> list[dict[str, Any]]:
	pred = raw # [84, 8400]
	veh_row_idx = np.array([4 + c for c in COCO_VEHICLE_IDX])
	max_veh_score = pred[veh_row_idx].max(axis=0)
	mask = max_veh_score > CONF_THRESH
	if not mask.any():
	return []

	pred_f = pred[:, mask]
	cx, cy, bw, bh = pred_f[0], pred_f[1], pred_f[2], pred_f[3]

	x1 = np.clip((cx - bw / 2 - pad_l) / ratio, 0, orig_w)
	y1 = np.clip((cy - bh / 2 - pad_t) / ratio, 0, orig_h)
	x2 = np.clip((cx + bw / 2 - pad_l) / ratio, 0, orig_w)
	y2 = np.clip((cy + bh / 2 - pad_t) / ratio, 0, orig_h)
	boxes = np.stack([x1, y1, x2, y2], axis=1)

	results: list[dict[str, Any]] = []
	for coco_cls in COCO_VEHICLE_IDX:
	scores = pred_f[4 + coco_cls]
	cls_mask = scores > CONF_THRESH
	if not cls_mask.any():
	continue
	keep = nms(boxes[cls_mask], scores[cls_mask])
	out_cls = COCO_TO_OUT[coco_cls]
	for k in keep:
	box = boxes[cls_mask][k]
	results.append({
	"bbox": [
	float(box[0]), float(box[1]),
	float(box[2]), float(box[3]),
	],
	"score": float(scores[cls_mask][k]),
	"class_id": out_cls,
	"class_name": OUT_NAMES[out_cls],
	})
	return results


	# ── Image decoding helpers ───────────────────────────────────────────────────

	def decode_image(data: bytes \| str) -> np.ndarray:
	if isinstance(data, str):
	data = base64.b64decode(data)
	elif isinstance(data, (bytes, bytearray)):
	try:
	data = base64.b64decode(data)
	except Exception:
	pass
	arr = np.frombuffer(data, dtype=np.uint8)
	img = cv2.imdecode(arr, cv2.IMREAD_COLOR)
	if img is None:
	pil = Image.open(io.BytesIO(data)).convert("RGB")
	img = cv2.cvtColor(np.array(pil), cv2.COLOR_RGB2BGR)
	return img


	# ── Core predict function ────────────────────────────────────────────────────

	def predict(image_data: bytes \| str \| np.ndarray) -> dict[str, Any]:
	sess = get_session()

	if isinstance(image_data, np.ndarray):
	img_bgr = image_data
	else:
	img_bgr = decode_image(image_data)

	orig_h, orig_w = img_bgr.shape[:2]
	inp, ratio, pad_l, pad_t = preprocess(img_bgr)

	t0 = time.perf_counter()
	outputs = sess.run(None, {"images": inp})
	infer_ms = (time.perf_counter() - t0) * 1000.0

	raw = outputs[0][0] # [84, 8400]
	detections = postprocess(raw, ratio, pad_l, pad_t, orig_w, orig_h)

	return {
	"detections": detections,
	"inference_ms": round(infer_ms, 3),
	"provider": sess.get_providers()[0],
	}


	# ── Chutes cord wrapper ──────────────────────────────────────────────────────

	try:
	from chutes.chute import Chute
	from chutes.chute.node_selector import NodeSelector
	from chutes.image import Image as ChuteImage

	chute_image = (
	ChuteImage(
	username="lculpitt",
	name="vehicle-detect-sn44",
	tag="v4-cuda",
	readme=(Path(__file__).parent / "README.md").read_text(),
	)
	.from_base("parachutes/python:3.12")
	.run_command("pip install --upgrade setuptools wheel")
	.run_command(
	"pip install 'numpy>=1.23' 'onnxruntime-gpu>=1.16' "
	"'opencv-python-headless>=4.7' 'pillow>=9.5' "
	"'huggingface_hub>=0.19.4' 'pydantic>=2.0' "
	"'pyyaml>=6.0' 'aiohttp>=3.9'"
	)
	# Bake cuDNN/cuBLAS paths into the image as Docker ENV so onnxruntime
	# CUDAExecutionProvider finds libcudnn.so.9 on every node at container start.
	.with_env(
	"LD_LIBRARY_PATH",
	"/usr/local/lib/python3.12/dist-packages/nvidia/cudnn/lib"
	":/usr/local/lib/python3.12/dist-packages/nvidia/cublas/lib",
	)
	)

	chute = Chute(
	username="lculpitt",
	name="vehicle-detect-sn44",
	tagline="YOLO11n vehicle detector — car, bus, truck, motorcycle",
	readme=(Path(__file__).parent / "README.md").read_text(),
	image=chute_image,
	concurrency=4,
	max_instances=5,
	shutdown_after_seconds=300,
	scaling_threshold=0.5,
	node_selector=NodeSelector(
	gpu_count=1,
	min_vram_gb_per_gpu=16,
	# All CUDA 12.x, all $0.40–$0.85/hr (within 2.5× spread from cheapest)
	include=["4090", "a40", "a6000", "l40", "l40s"],
	),
	)

	@chute.cord(path="/predict", method="POST")
	async def predict_cord(image_b64: str) -> dict:
	"""
	POST /predict
	Body: {"image_b64": "<base64-encoded image>"}
	Returns detection JSON.
	"""
	return predict(image_b64)

	except ImportError:
	pass


	# ── Local test ───────────────────────────────────────────────────────────────

	if __name__ == "__main__":
	import sys

	print("=" * 55)
	print(" miner.py — local smoke test")
	print("=" * 55)

	dummy_bgr = np.full((720, 1280, 3), 128, dtype=np.uint8)
	cv2.rectangle(dummy_bgr, (100, 100), (400, 300), (0, 255, 0), 3)

	if len(sys.argv) > 1:
	loaded = cv2.imread(sys.argv[1])
	if loaded is not None:
	dummy_bgr = loaded
	print(f" Using image: {sys.argv[1]} ({loaded.shape[1]}x{loaded.shape[0]})")
	else:
	print(f" Could not load {sys.argv[1]}, using dummy.")
	else:
	print(" Using synthetic 1280x720 dummy image.")

	result = predict(dummy_bgr)
	print(f"\n Provider : {result['provider']}")
	print(f" Inference : {result['inference_ms']:.2f} ms")
	print(f" Detections : {len(result['detections'])}")
	for d in result["detections"]:
	x1, y1, x2, y2 = [round(v, 1) for v in d["bbox"]]
	print(f" [{d['class_id']}] {d['class_name']:12s} score={d['score']:.3f} "
	f"bbox=[{x1},{y1},{x2},{y2}]")

	print("\n Latency benchmark (50 runs)...")
	times = []
	for _ in range(50):
	t0 = time.perf_counter()
	predict(dummy_bgr)
	times.append((time.perf_counter() - t0) * 1000)
	times.sort()
	p50, p95 = times[25], times[47]
	fps = 1000.0 / p50
	print(f" P50={p50:.2f}ms P95={p95:.2f}ms FPS={fps:.1f}")
	print(f" Target >=30 FPS : {'PASS' if fps >= 30 else 'FAIL'}")
	print(f" Target P95<50ms : {'PASS' if p95 < 50 else 'FAIL'}")
	print("=" * 55)