app.py

######### pull files
import os
from huggingface_hub import hf_hub_download
config_path=hf_hub_download(repo_id="ibm-nasa-geospatial/Prithvi-100M-multi-temporal-crop-classification", 
                            filename="multi_temporal_crop_classification_Prithvi_100M.py", 
                            token=os.environ.get("token"))
ckpt=hf_hub_download(repo_id="ibm-nasa-geospatial/Prithvi-100M-multi-temporal-crop-classification", 
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                     filename='multi_temporal_crop_classification_Prithvi_100M.pth', 
=======
                     filename='multi_temporal_crop_classification_best_mIoU_epoch_66.pth', 
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                     token=os.environ.get("token"))
##########
import argparse
from mmcv import Config

from mmseg.models import build_segmentor

from mmseg.datasets.pipelines import Compose, LoadImageFromFile

import rasterio
import torch

from mmseg.apis import init_segmentor

from mmcv.parallel import collate, scatter

import numpy as np
import glob
import os

import time

import numpy as np
import gradio as gr
from functools import partial

import pdb

import matplotlib.pyplot as plt


def open_tiff(fname):
    
    with rasterio.open(fname, "r") as src:
        
        data = src.read()
        
    return data

def write_tiff(img_wrt, filename, metadata):

    """
    It writes a raster image to file.

    :param img_wrt: numpy array containing the data (can be 2D for single band or 3D for multiple bands)
    :param filename: file path to the output file
    :param metadata: metadata to use to write the raster to disk
    :return:
    """

    with rasterio.open(filename, "w", **metadata) as dest:

        if len(img_wrt.shape) == 2:
            
            img_wrt = img_wrt[None]

        for i in range(img_wrt.shape[0]):
            dest.write(img_wrt[i, :, :], i + 1)
    
    return filename
            

def get_meta(fname):
    
    with rasterio.open(fname, "r") as src:
        
        meta = src.meta
        
    return meta

def preprocess_example(example_list):
    
    example_list = [os.path.join(os.path.abspath(''), x) for x in example_list]
    
    return example_list


def inference_segmentor(model, imgs, custom_test_pipeline=None):
    """Inference image(s) with the segmentor.

    Args:
        model (nn.Module): The loaded segmentor.
        imgs (str/ndarray or list[str/ndarray]): Either image files or loaded
            images.

    Returns:
        (list[Tensor]): The segmentation result.
    """
    cfg = model.cfg
    device = next(model.parameters()).device  # model device
    # build the data pipeline
    test_pipeline = [LoadImageFromFile()] + cfg.data.test.pipeline[1:] if custom_test_pipeline == None else custom_test_pipeline
    test_pipeline = Compose(test_pipeline)
    # prepare data
    data = []
    imgs = imgs if isinstance(imgs, list) else [imgs]
    for img in imgs:
        img_data = {'img_info': {'filename': img}}
        img_data = test_pipeline(img_data)
        data.append(img_data)
    # print(data.shape)
    
    data = collate(data, samples_per_gpu=len(imgs))
    if next(model.parameters()).is_cuda:
        # data = collate(data, samples_per_gpu=len(imgs))
        # scatter to specified GPU
        data = scatter(data, [device])[0]
    else:
        # img_metas = scatter(data['img_metas'],'cpu')
        # data['img_metas'] = [i.data[0] for i in data['img_metas']]
        
        img_metas = data['img_metas'].data[0]
        img = data['img']
        data = {'img': img, 'img_metas':img_metas}
    
    with torch.no_grad():
        result = model(return_loss=False, rescale=True, **data)
    return result


def inference_on_file(target_image, model, custom_test_pipeline):

    target_image = target_image.name
    # print(type(target_image))

    # output_image = target_image.replace('.tif', '_pred.tif')
    time_taken=-1
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    st = time.time()
    print('Running inference...')
    result = inference_segmentor(model, target_image, custom_test_pipeline)
    print("Output has shape: " + str(result[0].shape))

    ##### get metadata mask
    mask = open_tiff(target_image)
    # rgb = mask[[2, 1, 0], :, :].transpose((1,2,0))
    rgb1 = mask[[2, 1, 0], :, :].transpose((1,2,0))
    rgb2 = mask[[8, 7, 6], :, :].transpose((1,2,0))
    rgb3 = mask[[14, 13, 12], :, :].transpose((1,2,0))
    meta = get_meta(target_image)
    mask = np.where(mask == meta['nodata'], 1, 0)
    mask = np.max(mask, axis=0)[None]

    result[0] = np.where(mask == 1, -1, result[0])

    ##### Save file to disk
    meta["count"] = 1
    meta["dtype"] = "int16"
    meta["compress"] = "lzw"
    meta["nodata"] = -1
    print('Saving output...')
    # write_tiff(result[0], output_image, meta)
    et = time.time()
    time_taken = np.round(et - st, 1)
    print(f'Inference completed in {str(time_taken)} seconds')
        
    return rgb1,rgb2,rgb3, result[0][0]
=======
    try:
        st = time.time()
        print('Running inference...')
        result = inference_segmentor(model, target_image, custom_test_pipeline)
        print("Output has shape: " + str(result[0].shape))
        
        ##### get metadata mask
        mask = open_tiff(target_image)
        # rgb = mask[[2, 1, 0], :, :].transpose((1,2,0))
        rgb1 = mask[[2, 1, 0], :, :].transpose((1,2,0))
        rgb2 = mask[[8, 7, 6], :, :].transpose((1,2,0))
        rgb3 = mask[[14, 13, 12], :, :].transpose((1,2,0))
        meta = get_meta(target_image)
        mask = np.where(mask == meta['nodata'], 1, 0)
        mask = np.max(mask, axis=0)[None]
        
        result[0] = np.where(mask == 1, -1, result[0])
        
        ##### Save file to disk
        meta["count"] = 1
        meta["dtype"] = "int16"
        meta["compress"] = "lzw"
        meta["nodata"] = -1
        print('Saving output...')
        # write_tiff(result[0], output_image, meta)
        et = time.time()
        time_taken = np.round(et - st, 1)
        print(f'Inference completed in {str(time_taken)} seconds')
        
    except:
        print(f'Error on image {target_image} \nContinue to next input')
        
    return rgb, result[0][0]*255
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def process_test_pipeline(custom_test_pipeline, bands=None):
    
    # change extracted bands if necessary
    if bands is not None:
        
        extract_index = [i for i, x in enumerate(custom_test_pipeline) if x['type'] == 'BandsExtract' ]
        
        if len(extract_index) > 0:
            
            custom_test_pipeline[extract_index[0]]['bands'] = eval(bands)
            
    collect_index = [i for i, x in enumerate(custom_test_pipeline) if x['type'].find('Collect') > -1]
    
    # adapt collected keys if necessary
    if len(collect_index) > 0:
        
        keys = ['img_info', 'filename', 'ori_filename', 'img', 'img_shape', 'ori_shape', 'pad_shape', 'scale_factor', 'img_norm_cfg']
        custom_test_pipeline[collect_index[0]]['meta_keys'] = keys
    
    return custom_test_pipeline

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=======
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config = Config.fromfile(config_path)
config.model.backbone.pretrained=None
model = init_segmentor(config, ckpt, device='cpu')
custom_test_pipeline=process_test_pipeline(model.cfg.data.test.pipeline, None)

func = partial(inference_on_file, model=model, custom_test_pipeline=custom_test_pipeline)

with gr.Blocks() as demo:
   
    gr.Markdown(value='# Prithvi multi temporal crop classification')
    gr.Markdown(value='''Prithvi is a first-of-its-kind temporal Vision transformer pretrained by the IBM and NASA team on continental US Harmonised Landsat Sentinel 2 (HLS) data. This demo showcases how the model was finetuned to classify crop and other land use categories using multi temporal data. More detailes can be found [here](https://huggingface.co/ibm-nasa-geospatial/Prithvi-100M-multi-temporal-crop-classification).\n
    The user needs to provide an HLS geotiff image, including 18 bands for 3 time-step, and each time-step includes the channels described above (Blue, Green, Red, Narrow NIR, SWIR, SWIR 2) in order.
    ''')
    with gr.Row():
        with gr.Column():
            inp = gr.File()
            btn = gr.Button("Submit")
    
    with gr.Row():
        gr.Markdown(value='### T1')
        gr.Markdown(value='### T2')
        gr.Markdown(value='### T3')
        gr.Markdown(value='### Model prediction')
        
    with gr.Row():
        inp1=gr.Image(image_mode='RGB')
        inp2=gr.Image(image_mode='RGB')
        inp3=gr.Image(image_mode='RGB')
        out = gr.Image(image_mode='L')
    
    btn.click(fn=func, inputs=inp, outputs=[inp1, inp2, inp3, out])
    
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    # with gr.Row():
    #     gr.Examples(examples=["chip_102_345_merged.tif", "chip_104_104_merged.tif", "chip_109_421_merged.tif"],
    #                 inputs=inp,
    #                 outputs=[inp1, inp2, inp3, out],
    #                 preprocess=preprocess_example,
    #                 fn=func,
    #                 cache_examples=True,
    # )
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    with gr.Row():
        gr.Examples(examples=["chip_102_345_merged.tif",
                     "chip_104_104_merged.tif",
                     "chip_109_421_merged.tif"],
                    inputs=inp,
                    outputs=[inp1, inp2, inp3, out],
                    preprocess=preprocess_example,
                    fn=func,
                    cache_examples=True,
    )
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demo.launch()