Refactor code predict imflammation
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import json
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import time
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from pathlib import Path
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import numpy as np
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from PIL import Image
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import requests
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# Server configuration
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TRITON_URL = "https://dtj-tran--triton-s3-service-unified-triton-server.modal.run"
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TARGET_MODEL = "workspace/sprint_1_2/CODEBASE/infra/tests/models/efficientnet_b0_ultrasound_2_class.pth" # Target a single sub-model directly
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IMFLAMMATION_CLASSES = ["Không viêm", "Có viêm"]
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BASE_DIR = Path(__file__).resolve().parent
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def load_image(path: Path) -> Image.Image:
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if not path.exists():
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raise FileNotFoundError(f"Test image not found at: {path}")
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return Image.open(path).convert("RGB")
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def preprocess_224(img: Image.Image) -> np.ndarray:
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"""Preprocesses image to NCHW FP32 [1, 3, 224, 224] matching ResNet50 input requirements"""
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img_resized = img.resize((224, 224), Image.Resampling.BILINEAR)
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arr = np.asarray(img_resized).astype(np.float32) / 255.0
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mean = np.array([0.485, 0.456, 0.406], dtype=np.float32)
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std = np.array([0.229, 0.224, 0.225], dtype=np.float32)
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arr = (arr - mean) / std
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arr = arr.transpose(2, 0, 1) # HWC -> CHW
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arr = np.expand_dims(arr, axis=0) # Add batch dim -> NCHW
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return arr
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def softmax(x: np.ndarray) -> np.ndarray:
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e = np.exp(x - np.max(x))
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return e / np.sum(e)
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def build_binary_request(input_tensor: np.ndarray, model_name: str) -> tuple[bytes, dict]:
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"""Constructs a strict KServe v2 binary payload for a single input tensor"""
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# NOTE: Check your individual model's config.pbtxt to verify if the
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# expected input name is 'input_image', 'input_0', etc.
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input_name = "input_image"
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inputs = [
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{
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"name": input_name,
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"shape": list(input_tensor.shape),
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"datatype": "FP32",
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"parameters": {"binary_data_size": input_tensor.nbytes},
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}
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]
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# We request the standard 'logits' output tensor from this model
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outputs = [{"name": "logits"}]
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metadata = {
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"model_name": model_name,
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"model_version": "",
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"inputs": inputs,
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"outputs": outputs
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}
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metadata_bytes = json.dumps(metadata).encode("utf-8")
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body = metadata_bytes + input_tensor.tobytes()
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headers = {
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"Inference-Header-Content-Length": str(len(metadata_bytes)),
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"Content-Type": "application/octet-stream"
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}
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return body, headers
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def parse_binary_response(resp: requests.Response) -> np.ndarray:
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"""Parses Triton's binary response stream for a single output tensor"""
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header_length = int(resp.headers.get("Inference-Header-Content-Length", "0"))
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response_bytes = resp.content
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metadata = json.loads(response_bytes[:header_length].decode("utf-8"))
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binary_data = response_bytes[header_length:]
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# Extract the first available output tensor
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output_desc = metadata["outputs"][0]
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shape = output_desc["shape"]
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# Unpack raw bytes back into numpy array
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arr = np.frombuffer(binary_data, dtype=np.float32).reshape(shape)
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return arr
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def main():
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# Define a path to a real local image to test with
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image_path = "test_images/sup-up-long_positive/58e7a7ef-de3e-11ee-97e2-0a580a5f5b60_11.png"
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print(f"Targeting Individual Model: {TARGET_MODEL}")
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print(f"Loading image from: {image_path}")
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try:
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# 1. Prepare image
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img = load_image(image_path)
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input_data = preprocess_224(img)
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# 2. Build the payload
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body, headers = build_binary_request(input_data, TARGET_MODEL)
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# 3. Fire request to the targeted model endpoint
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url = f"{TRITON_URL}/v2/models/{TARGET_MODEL}/infer"
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print("Sending request to Triton server...")
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t0 = time.time()
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resp = requests.post(url, data=body, headers=headers, timeout=30)
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resp.raise_for_status()
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latency = time.time() - t0
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# 4. Parse output logits
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logits = parse_binary_response(resp)
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logits = np.squeeze(logits) # Drop batch dimension
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# 5. Decode probabilities
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probs = softmax(logits)
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predicted_idx = int(np.argmax(probs))
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print("\n" + "=" * 40)
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print("🎉 SUCCESSFUL INFERENCE")
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print(f"Network Roundtrip Time: {latency:.4f}s")
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print("-" * 40)
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print("Class Probabilities:")
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for cls_name, prob in zip(IMFLAMMATION_CLASSES, probs):
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print(f" {cls_name:<15}: {prob * 100:.2f}%")
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print("-" * 40)
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print(f"Prediction: {IMFLAMMATION_CLASSES[predicted_idx]} ({probs[predicted_idx] * 100:.2f}%)")
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print("=" * 40)
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except Exception as e:
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print(f"\n❌ Inference Failed: {e}")
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if 'resp' in locals() and hasattr(resp, 'text'):
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print(f"Server Error Message: {resp.text}")
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if __name__ == "__main__":
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main()
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