demo_dense_visualize.py

import os
import random
import torch
import sys
import torch.nn.functional as F
import numpy as np

import utils.loss
import utils.samp
import utils.data
import utils.improc
import utils.misc
import utils.saveload
import cv2
import imageio
from nets.blocks import InputPadder
from utils.visualizer import Visualizer

import torch
import requests
from PIL import Image, ImageDraw
from transformers import AutoProcessor, AutoModelForCausalLM
import numpy as np


torch.set_float32_matmul_precision('medium')

def run_example(processor, model, task_prompt, image, text_input=None):
    if text_input is None:
        prompt = task_prompt
    else:
        prompt = task_prompt + text_input
    inputs = processor(text=prompt, images=image, return_tensors="pt").to('cuda', torch.float32)
    generated_ids = model.generate(
      input_ids=inputs["input_ids"],
      pixel_values=inputs["pixel_values"],
      max_new_tokens=1024,
      num_beams=3
    )
    generated_text = processor.batch_decode(generated_ids, skip_special_tokens=False)[0]

    parsed_answer = processor.post_process_generation(generated_text, task=task_prompt, image_size=(image.width, image.height))

    return parsed_answer

class Tracker:
    def __init__(self, model, mean, std, S, stride, inference_iters, target_res, device='cuda'):
        """
        Initializes the Tracker.

        Args:
            model: The model used to compute feature maps and forward window flow.
            mean: Tensor or value used for normalizing the input.
            std: Tensor or value used for normalizing the input.
            S: Window size for the tracker.
            stride: The stride used when updating the window.
            inference_iters: Number of inference iterations.
            device: Torch device, defaults to 'cuda'.
        """
        self.model = model
        self.mean = mean
        self.std = std
        self.S = S
        self.stride = stride
        self.inference_iters = inference_iters
        self.device = device
        self.target_res = target_res

        self.padder = None
        self.cnt = 0
        self.fmap_anchor = None
        self.fmaps2 = None
        self.flows8 = None
        self.visconfs8 = None
        self.flows = []  # List to store computed flows
        self.visibs = []  # List to store visibility confidences
        self.rgbs = []  # List to store RGB frames

    def reset(self):
        """Reset the tracker state."""
        self.padder = None
        self.cnt = 0
        self.fmap_anchor = None
        self.fmaps2 = None
        self.flows8 = None
        self.visconfs8 = None
        self.flows = []
        self.visibs = []
        self.rgbs = []
        
    def preprocess(self, rgb_frame):
        # Resize frame (scale to keep maximum dimension ~1024)
        scale = min(self.target_res / rgb_frame.shape[0], self.target_res / rgb_frame.shape[1])
        rgb_resized = cv2.resize(rgb_frame, None, fx=scale, fy=scale, interpolation=cv2.INTER_LINEAR)
        
        # Convert to tensor, normalize and move to device.
        rgb_tensor = torch.from_numpy(rgb_resized).permute(2, 0, 1).float().unsqueeze(0).to(self.device)
        rgb_tensor = rgb_tensor / 255.0
        
        self.rgbs.append(rgb_tensor.cpu())
            
        # import pdb; pdb.set_trace()
        rgb_tensor = (rgb_tensor - self.mean) / self.std
        return rgb_tensor

    @torch.no_grad()
    def track(self, rgb_frame):
        """
        Process a single RGB frame and return the computed flow when available.

        Args:
            rgb_frame: A NumPy array containing the RGB frame.
                       (Assumed to be in RGB; if coming from OpenCV, convert it before passing.)
        
        Returns:
            flow_predictions: The predicted flow for the current frame (or None if not enough frames have been processed).
        """
        torch.cuda.empty_cache()

        rgb_tensor = self.preprocess(rgb_frame)
        
        # Initialize padder on the first frame.
        if self.cnt == 0:
            self.padder = InputPadder(rgb_tensor.shape)
        rgb_padded = self.padder.pad(rgb_tensor)[0]
        _, _, H_pad, W_pad = rgb_padded.shape
        C = 256  # Feature map channel dimension (could be parameterized if needed)
        H8, W8 = H_pad // 8, W_pad // 8

        # Accumulate feature maps until the window is full.
        if self.cnt == 0:
            self.fmap_anchor = self.model.get_fmaps(rgb_padded, 1, 1, None, False, False).reshape(1, C, H8, W8)
            self.fmaps2 = self.fmap_anchor[:, None]
            self.cnt += 1
            return None
            
        new_fmap = self.model.get_fmaps(rgb_padded, 1, 1, None, False, False).reshape(1, 1, C, H8, W8)
        self.fmaps2 = torch.cat([self.fmaps2[:, (1 if self.fmaps2.shape[1] >= self.S else 0):].detach().clone(), new_fmap], dim=1)
        
        # need to track
        if self.cnt - self.S + 1 >= 0 and (self.cnt - self.S + 1) % self.stride == 0:
            # Initialize or update temporary flow buffers.
            iter_num = self.inference_iters
            if self.flows8 is None:
                self.flows8 = torch.zeros((self.S, 2, H_pad // 8, W_pad // 8), device=self.device)
                self.visconfs8 = torch.zeros((self.S, 2, H_pad // 8, W_pad // 8), device=self.device)
                # iter_num = self.inference_iters
            else:
                self.flows8 = torch.cat([
                    self.flows8[self.stride:self.stride + self.S // 2].detach().clone(),
                    self.flows8[self.stride + self.S // 2 - 1:self.stride + self.S // 2].detach().clone().repeat(self.S // 2, 1, 1, 1)
                ])
                self.visconfs8 = torch.cat([
                    self.visconfs8[self.stride:self.stride + self.S // 2].detach().clone(),
                    self.visconfs8[self.stride + self.S // 2 - 1:self.stride + self.S // 2].detach().clone().repeat(self.S // 2, 1, 1, 1)
                ])

            # import pdb; pdb.set_trace()
            # Compute flow predictions using the model's forward window.
            flow_predictions, visconf_predictions, self.flows8, self.visconfs8, _ = self.model.forward_window(
                self.fmap_anchor,
                self.fmaps2,
                self.visconfs8,
                iters=iter_num,
                flowfeat=None,
                flows8=self.flows8,
                is_training=False
            )
            flow_predictions = self.padder.unpad(flow_predictions[-1][0 if self.cnt == self.S - 1 else -self.stride:])
            visconf_predictions = self.padder.unpad(torch.sigmoid(visconf_predictions[-1][0 if self.cnt == self.S - 1 else -self.stride:]))

            self.cnt += 1
            self.flows.append(flow_predictions.cpu())
            self.visibs.append(visconf_predictions.cpu())

            return flow_predictions, visconf_predictions
        
        self.cnt += 1
        return None