Prithvi-100M / Prithvi_run_inference.py
carlosgomes98's picture
fix inference
c2435ef
import argparse
import functools
import os
from typing import List, Union
import numpy as np
import rasterio
import torch
import yaml
from einops import rearrange
from Prithvi import MaskedAutoencoderViT
NO_DATA = -9999
NO_DATA_FLOAT = 0.0001
PERCENTILES = (0.1, 99.9)
def process_channel_group(orig_img, new_img, channels, data_mean, data_std):
"""Process *orig_img* and *new_img* for RGB visualization. Each band is rescaled back to the
original range using *data_mean* and *data_std* and then lowest and highest percentiles are
removed to enhance contrast. Data is rescaled to (0, 1) range and stacked channels_first.
Args:
orig_img: torch.Tensor representing original image (reference) with shape = (bands, H, W).
new_img: torch.Tensor representing image with shape = (bands, H, W).
channels: list of indices representing RGB channels.
data_mean: list of mean values for each band.
data_std: list of std values for each band.
Returns:
torch.Tensor with shape (num_channels, height, width) for original image
torch.Tensor with shape (num_channels, height, width) for the other image
"""
stack_c = [], []
for c in channels:
orig_ch = orig_img[c, ...]
valid_mask = torch.ones_like(orig_ch, dtype=torch.bool)
valid_mask[orig_ch == NO_DATA_FLOAT] = False
# Back to original data range
orig_ch = (orig_ch * data_std[c]) + data_mean[c]
new_ch = (new_img[c, ...] * data_std[c]) + data_mean[c]
# Rescale (enhancing contrast)
min_value, max_value = np.percentile(orig_ch[valid_mask], PERCENTILES)
orig_ch = torch.clamp((orig_ch - min_value) / (max_value - min_value), 0, 1)
new_ch = torch.clamp((new_ch - min_value) / (max_value - min_value), 0, 1)
# No data as zeros
orig_ch[~valid_mask] = 0
new_ch[~valid_mask] = 0
stack_c[0].append(orig_ch)
stack_c[1].append(new_ch)
# Channels first
stack_orig = torch.stack(stack_c[0], dim=0)
stack_rec = torch.stack(stack_c[1], dim=0)
return stack_orig, stack_rec
def read_geotiff(file_path: str):
"""Read all bands from *file_path* and return image + meta info.
Args:
file_path: path to image file.
Returns:
np.ndarray with shape (bands, height, width)
meta info dict
"""
with rasterio.open(file_path) as src:
img = src.read()
meta = src.meta
return img, meta
def save_geotiff(image, output_path: str, meta: dict):
"""Save multi-band image in Geotiff file.
Args:
image: np.ndarray with shape (bands, height, width)
output_path: path where to save the image
meta: dict with meta info.
"""
with rasterio.open(output_path, "w", **meta) as dest:
for i in range(image.shape[0]):
dest.write(image[i, :, :], i + 1)
return
def _convert_np_uint8(float_image: torch.Tensor):
image = float_image.numpy() * 255.0
image = image.astype(dtype=np.uint8)
return image
def load_example(
file_paths: List[str],
mean: List[float],
std: List[float],
indices: Union[list[int], None] = None,
):
"""Build an input example by loading images in *file_paths*.
Args:
file_paths: list of file paths .
mean: list containing mean values for each band in the images in *file_paths*.
std: list containing std values for each band in the images in *file_paths*.
Returns:
np.array containing created example
list of meta info for each image in *file_paths*
"""
imgs = []
metas = []
for file in file_paths:
img, meta = read_geotiff(file)
# Rescaling (don't normalize on nodata)
img = np.moveaxis(img, 0, -1) # channels last for rescaling
if indices is not None:
img = img[..., indices]
img = np.where(img == NO_DATA, NO_DATA_FLOAT, (img - mean) / std)
imgs.append(img)
metas.append(meta)
imgs = np.stack(imgs, axis=0) # num_frames, H, W, C
imgs = np.moveaxis(imgs, -1, 0).astype("float32") # C, num_frames, H, W
imgs = np.expand_dims(imgs, axis=0) # add batch dim
return imgs, metas
def run_model(
model: torch.nn.Module,
input_data: torch.Tensor,
mask_ratio: float,
device: torch.device,
):
"""Run *model* with *input_data* and create images from output tokens (mask, reconstructed + visible).
Args:
model: MAE model to run.
input_data: torch.Tensor with shape (B, C, T, H, W).
mask_ratio: mask ratio to use.
device: device where model should run.
Returns:
3 torch.Tensor with shape (B, C, T, H, W).
"""
with torch.no_grad():
x = input_data.to(device)
_, pred, mask = model(x, mask_ratio)
# Create mask and prediction images (un-patchify)
mask_img = (
model.unpatchify(mask.unsqueeze(-1).repeat(1, 1, pred.shape[-1])).detach().cpu()
)
pred_img = model.unpatchify(pred).detach().cpu()
# Mix visible and predicted patches
rec_img = input_data.clone()
rec_img[mask_img == 1] = pred_img[
mask_img == 1
] # binary mask: 0 is keep, 1 is remove
# Switch zeros/ones in mask images so masked patches appear darker in plots (better visualization)
mask_img = (~(mask_img.to(torch.bool))).to(torch.float)
return rec_img, mask_img
def save_rgb_imgs(
input_img, rec_img, mask_img, channels, mean, std, output_dir, meta_data
):
"""Wrapper function to save Geotiff images (original, reconstructed, masked) per timestamp.
Args:
input_img: input torch.Tensor with shape (C, T, H, W).
rec_img: reconstructed torch.Tensor with shape (C, T, H, W).
mask_img: mask torch.Tensor with shape (C, T, H, W).
channels: list of indices representing RGB channels.
mean: list of mean values for each band.
std: list of std values for each band.
output_dir: directory where to save outputs.
meta_data: list of dicts with geotiff meta info.
"""
for t in range(input_img.shape[1]):
rgb_orig, rgb_pred = process_channel_group(
orig_img=input_img[:, t, :, :],
new_img=rec_img[:, t, :, :],
channels=channels,
data_mean=mean,
data_std=std,
)
rgb_mask = mask_img[channels, t, :, :] * rgb_orig
# Saving images
save_geotiff(
image=_convert_np_uint8(rgb_orig),
output_path=os.path.join(output_dir, f"original_rgb_t{t}.tiff"),
meta=meta_data[t],
)
save_geotiff(
image=_convert_np_uint8(rgb_pred),
output_path=os.path.join(output_dir, f"predicted_rgb_t{t}.tiff"),
meta=meta_data[t],
)
save_geotiff(
image=_convert_np_uint8(rgb_mask),
output_path=os.path.join(output_dir, f"masked_rgb_t{t}.tiff"),
meta=meta_data[t],
)
def save_imgs(rec_img, mask_img, mean, std, output_dir, meta_data):
"""Wrapper function to save Geotiff images (reconstructed, mask) per timestamp.
Args:
rec_img: reconstructed torch.Tensor with shape (C, T, H, W).
mask_img: mask torch.Tensor with shape (C, T, H, W).
mean: list of mean values for each band.
std: list of std values for each band.
output_dir: directory where to save outputs.
meta_data: list of dicts with geotiff meta info.
"""
mean = torch.tensor(np.asarray(mean)[:, None, None]) # C H W
std = torch.tensor(np.asarray(std)[:, None, None])
for t in range(rec_img.shape[1]):
# Back to original data range
rec_img_t = ((rec_img[:, t, :, :] * std) + mean).to(torch.int16)
mask_img_t = mask_img[:, t, :, :].to(torch.int16)
# Saving images
save_geotiff(
image=rec_img_t,
output_path=os.path.join(output_dir, f"predicted_t{t}.tiff"),
meta=meta_data[t],
)
save_geotiff(
image=mask_img_t,
output_path=os.path.join(output_dir, f"mask_t{t}.tiff"),
meta=meta_data[t],
)
def main(
data_files: List[str],
yaml_file_path: str,
checkpoint: str,
output_dir: str,
rgb_outputs: bool,
img_size: int,
mask_ratio: float = None,
input_indices: list[int] = None,
):
os.makedirs(output_dir, exist_ok=True)
# Get parameters --------
with open(yaml_file_path, "r") as f:
params = yaml.safe_load(f)
# data related
train_params = params["train_params"]
num_frames = len(data_files)
bands = train_params["bands"]
mean = train_params["data_mean"]
std = train_params["data_std"]
# model related
model_params = params["model_args"]
img_size = model_params["img_size"] if img_size is None else img_size
depth = model_params["depth"]
patch_size = model_params["patch_size"]
embed_dim = model_params["embed_dim"]
num_heads = model_params["num_heads"]
tubelet_size = model_params["tubelet_size"]
decoder_embed_dim = model_params["decoder_embed_dim"]
decoder_num_heads = model_params["decoder_num_heads"]
decoder_depth = model_params["decoder_depth"]
batch_size = 1
mask_ratio = train_params["mask_ratio"] if mask_ratio is None else mask_ratio
print(
f"\nTreating {len(data_files)} files as {len(data_files)} time steps from the same location\n"
)
if len(data_files) != 3:
print(
"The original model was trained for 3 time steps (expecting 3 files). \nResults with different numbers of timesteps may vary"
)
if torch.cuda.is_available():
device = torch.device("cuda")
else:
device = torch.device("cpu")
print(f"Using {device} device.\n")
# Loading data ---------------------------------------------------------------------------------
input_data, meta_data = load_example(
file_paths=data_files, indices=input_indices, mean=mean, std=std
)
# Create model and load checkpoint -------------------------------------------------------------
model = MaskedAutoencoderViT(
img_size=img_size,
patch_size=patch_size,
num_frames=num_frames,
tubelet_size=tubelet_size,
in_chans=len(bands),
embed_dim=embed_dim,
depth=depth,
num_heads=num_heads,
decoder_embed_dim=decoder_embed_dim,
decoder_depth=decoder_depth,
decoder_num_heads=decoder_num_heads,
mlp_ratio=4.0,
norm_layer=functools.partial(torch.nn.LayerNorm, eps=1e-6),
norm_pix_loss=False,
)
total_params = sum(p.numel() for p in model.parameters() if p.requires_grad)
print(f"\n--> Model has {total_params:,} parameters.\n")
model.to(device)
state_dict = torch.load(checkpoint, map_location=device)
# discard fixed pos_embedding weight
del state_dict["pos_embed"]
del state_dict["decoder_pos_embed"]
model.load_state_dict(state_dict, strict=False)
print(f"Loaded checkpoint from {checkpoint}")
# Running model --------------------------------------------------------------------------------
model.eval()
channels = [bands.index(b) for b in ["B04", "B03", "B02"]] # BGR -> RGB
# Reflect pad if not divisible by img_size
original_h, original_w = input_data.shape[-2:]
pad_h = img_size - (original_h % img_size)
pad_w = img_size - (original_w % img_size)
input_data = np.pad(
input_data, ((0, 0), (0, 0), (0, 0), (0, pad_h), (0, pad_w)), mode="reflect"
)
# Build sliding window
batch = torch.tensor(input_data, device="cpu")
windows = batch.unfold(3, img_size, img_size).unfold(4, img_size, img_size)
h1, w1 = windows.shape[3:5]
windows = rearrange(
windows, "b c t h1 w1 h w -> (b h1 w1) c t h w", h=img_size, w=img_size
)
# Split into batches if number of windows > batch_size
num_batches = windows.shape[0] // batch_size if windows.shape[0] > batch_size else 1
windows = torch.tensor_split(windows, num_batches, dim=0)
# Run model
rec_imgs = []
mask_imgs = []
for x in windows:
rec_img, mask_img = run_model(model, x, mask_ratio, device)
rec_imgs.append(rec_img)
mask_imgs.append(mask_img)
rec_imgs = torch.concat(rec_imgs, dim=0)
mask_imgs = torch.concat(mask_imgs, dim=0)
# Build images from patches
rec_imgs = rearrange(
rec_imgs,
"(b h1 w1) c t h w -> b c t (h1 h) (w1 w)",
h=img_size,
w=img_size,
b=1,
c=len(bands),
t=num_frames,
h1=h1,
w1=w1,
)
mask_imgs = rearrange(
mask_imgs,
"(b h1 w1) c t h w -> b c t (h1 h) (w1 w)",
h=img_size,
w=img_size,
b=1,
c=len(bands),
t=num_frames,
h1=h1,
w1=w1,
)
# Cut padded images back to original size
rec_imgs_full = rec_imgs[..., :original_h, :original_w]
mask_imgs_full = mask_imgs[..., :original_h, :original_w]
batch_full = batch[..., :original_h, :original_w]
# Build output images
if rgb_outputs:
for d in meta_data:
d.update(count=3, dtype="uint8", compress="lzw", nodata=0)
save_rgb_imgs(
batch_full[0, ...],
rec_imgs_full[0, ...],
mask_imgs_full[0, ...],
channels,
mean,
std,
output_dir,
meta_data,
)
else:
for d in meta_data:
d.update(compress="lzw", nodata=0)
save_imgs(
rec_imgs_full[0, ...],
mask_imgs_full[0, ...],
mean,
std,
output_dir,
meta_data,
)
print("Done!")
if __name__ == "__main__":
parser = argparse.ArgumentParser("MAE run inference", add_help=False)
parser.add_argument(
"--data_files",
required=True,
type=str,
nargs="+",
help="Path to the data files. Assumes multi-band files.",
)
parser.add_argument(
"--yaml_file_path",
type=str,
required=True,
help="Path to yaml file containing model training parameters.",
)
parser.add_argument(
"--checkpoint",
required=True,
type=str,
help="Path to a checkpoint file to load from.",
)
parser.add_argument(
"--output_dir",
required=True,
type=str,
help="Path to the directory where to save outputs.",
)
parser.add_argument(
"--mask_ratio",
default=None,
type=float,
help="Masking ratio (percentage of removed patches). "
"If None (default) use same value used for pretraining.",
)
parser.add_argument(
"--img_size",
default=224,
type=int,
help="Image size to be used with model. Defaults to 224",
)
parser.add_argument(
"--input_indices",
default=None,
type=int,
nargs="+",
help="0-based indices of channels to be selected from the input. By default takes all.",
)
parser.add_argument(
"--rgb_outputs",
action="store_true",
help="If present, output files will only contain RGB channels. "
"Otherwise, all bands will be saved.",
)
args = parser.parse_args()
main(**vars(args))