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import os
import random
from concurrent.futures import ProcessPoolExecutor
from functools import partial
from pathlib import Path
from typing import Optional
import torch.nn.functional as F
import lmdb
import gzip
import pickle
import json
from itertools import product
import numpy as np
from tqdm import tqdm
import torch
from torch_geometric.data import Data, Dataset
from torch_geometric.loader import DataLoader
import periodictable
from torch.utils.data.distributed import DistributedSampler
from torch.utils.data import SubsetRandomSampler, random_split, Subset
import bisect
HARTREE_2_EV = 27.2114
BOHR_2_ANGSTROM = 1.8897
_MEAN_ENERGY = -4.269320623583757
_STD_ENERGY = 1.0
_STD_FORCE_SCALE = 1.0
atomic_number_mapping = {}
for element in periodictable.elements:
atomic_number_mapping[element.symbol] = element.number
atomic_number_mapping[element.symbol.upper()] = element.number
atomic_number_mapping[element.symbol.lower()] = element.number
atom_energy = {
1: -0.5002727762,
4: -14.6684425428,
5: -24.6543539532,
6: -37.8462799513,
7: -54.5844893657,
8: -75.0606214015,
9: -99.7155354215,
14: -289.3723539998,
15: -341.2580898032,
16: -398.1049925382,
17: -460.1362417086,
21: -760.5813501324,
22: -849.3013849537,
23: -943.8255794204,
24: -1044.2810289455,
25: -1150.8680174849,
26: -1263.5207828239406,
27: -1382.5485719267936,
28: -1508.0542451335,
29: -1640.1731641564784,
31: -1924.5926070018,
32: -2076.6914561594,
33: -2235.5683127287,
34: -2401.2347730327,
35: -2573.8397377628
}
def find_last_index_with_key(objects, key):
last_index = -1
for i in range(len(objects) - 1, -1, -1):
if key in objects[i] and objects[i][key] is not None:
last_index = i
break
return last_index
def data_to_pyg(data, key, stage='1st', filter=False):
def process_data(phase):
nonlocal data
nonlocal key
nonlocal stage
datas = []
if phase is None or len(phase) == 0:
return datas
if stage == 'mixing':
if len(data['DFT_2nd']) != 0:
last_index = find_last_index_with_key(data['DFT_2nd'], 'energy')
if last_index == -1:
if data['DFT_1st'] is None or len(data['DFT_1st']) == 0:
return datas
last_index = find_last_index_with_key(data['DFT_1st'], 'energy')
last_data = data['DFT_1st'][last_index]
else:
last_data = data['DFT_2nd'][last_index]
else:
if data['DFT_1st'] is None or len(data['DFT_1st']) == 0:
return datas
last_index = find_last_index_with_key(data['DFT_1st'], 'energy')
last_data = data['DFT_1st'][last_index]
elif stage == '1st':
last_index = find_last_index_with_key(data['DFT_1st'], 'energy')
if last_index == -1:
return datas
last_data = phase[last_index]
elif stage == '1st_smash':
last_index = find_last_index_with_key(data['DFT_1st'], 'energy')
if last_index == -1:
return datas
last_data = phase[last_index]
elif stage == '2nd':
last_index = find_last_index_with_key(data['DFT_2nd'], 'energy')
if last_index == -1:
return datas
last_data = phase[last_index]
elif stage == 'hf':
last_index = find_last_index_with_key(data['hf'], 'energy')
if last_index == -1:
return datas
last_data = phase[last_index]
elif stage == 'pm3':
last_index = find_last_index_with_key(data['pm3'], 'energy')
if last_index == -1:
return datas
last_data = phase[last_index]
else:
raise Exception('Unknown stage')
last_coordinates = last_data['coordinates']
last_energy = last_data['energy']
if stage == '1st_smash':
if 'charge' in last_coordinates[0]:
return datas
for d in phase:
coords = d['coordinates']
energy = d['energy']
gradient = d['gradient']
formation_energies = []
atomic_numbers = []
positions = []
last_positions = []
forces = []
if coords is None or len(
coords) == 0:
continue
if stage == '1st_smash':
if 'charge' in coords[0]:
continue
if energy is None:
continue
if len(coords) != len(last_coordinates):
continue
if len(gradient) != len(coords):
continue
for i, atom_info in enumerate(coords):
atom = atom_info['atom']
atomic_number = atomic_number_mapping[atom]
x = atom_info['x']
y = atom_info['y']
z = atom_info['z']
atomic_numbers.append(atomic_number)
formation_energies.append(atom_energy[atomic_number])
positions.append([x, y, z])
last_positions.append([last_coordinates[i]['x'], last_coordinates[i]['y'],
last_coordinates[i]['z']])
forces.append([-gradient[i]['dx'] * HARTREE_2_EV * BOHR_2_ANGSTROM, -gradient[i]['dy'] * HARTREE_2_EV * BOHR_2_ANGSTROM,
-gradient[i]['dz'] * HARTREE_2_EV * BOHR_2_ANGSTROM])
x = torch.tensor(atomic_numbers, dtype=torch.long).view(-1,
1)
pos = torch.tensor(positions, dtype=torch.float)
last_pos = torch.tensor(last_positions,
dtype=torch.float)
y = torch.tensor([(energy - sum(formation_energies)) * HARTREE_2_EV / x.size(0)],
dtype=torch.float)
last_y = torch.tensor([(last_energy - sum(formation_energies)) * HARTREE_2_EV / x.size(0)],
dtype=torch.float)
y_force = torch.tensor(forces,
dtype=torch.float)
if (torch.isnan(x).any() or torch.isnan(pos).any() or torch.isnan(last_pos).any() or torch.isnan(
y).any() or torch.isnan(last_y).any() or torch.isnan(y_force).any()):
continue
ds = Data(x=x, natoms=x.size(0), pos=pos, last_pos=last_pos, y=y, last_y=last_y, y_force=y_force, cid=str(key))
datas.append(ds)
return datas
if stage == '1st':
return process_data(data['DFT_1st'])
elif stage == '1st_smash':
return process_data(data['DFT_1st'])
elif stage == '2nd':
return process_data(data['DFT_2nd'])
elif stage == 'mixing':
return process_data(data['DFT_1st']) + process_data(data['DFT_2nd'])
elif stage == 'pm3':
return process_data(data['pm3'])
elif stage == 'hf':
return process_data(data['hf'])
else:
raise Exception('Unknown stage')
def process_key(key, db_path, stage, filtering):
env = lmdb.open(str(db_path), subdir=False, readonly=True, lock=False)
with env.begin(write=False) as txn:
datapoint_pickled = txn.get(key)
data_objects = data_to_pyg(pickle.loads(gzip.decompress(datapoint_pickled)), stage, filter=filtering)
if len(data_objects) > 0:
return key
else:
return None
def process_num(key, db_path, stage, filtering):
env = lmdb.open(str(db_path), subdir=False, readonly=True, lock=False)
with env.begin(write=False) as txn:
datapoint_pickled = txn.get(key)
data_objects = data_to_pyg(pickle.loads(gzip.decompress(datapoint_pickled)), stage, filter=filtering)
if len(data_objects) > 0:
return len(data_objects)
else:
return None
def get_valid_nums(db_path, keys, stage, filtering):
valid_nums = []
worker_func = partial(process_num, db_path=db_path, stage=stage, filtering=filtering)
with ProcessPoolExecutor(max_workers=32) as executor:
results = executor.map(worker_func, keys)
for maybe_len in tqdm(results, total=len(keys), desc="Get valid numbers"):
if maybe_len is not None:
valid_nums.append(maybe_len)
return valid_nums
def filter_valid_keys(db_path, keys, stage, filtering):
valid_keys = []
worker_func = partial(process_key, db_path=db_path, stage=stage, filtering=filtering)
with ProcessPoolExecutor(max_workers=32) as executor:
results = executor.map(worker_func, keys)
for maybe_key in tqdm(results, total=len(keys), desc="Filtering valid keys"):
if maybe_key is not None:
valid_keys.append(maybe_key)
return valid_keys
class LMDBDataset(Dataset):
def __init__(self, path, transform=None, keys_file='valid_keys', stage='1st', total_traj=True,
SubsetOnly=False, getTest = False, stochastic_frame = False) -> None:
super(LMDBDataset, self).__init__()
self.path = Path(path)
self.keys_file = keys_file
self.stage = stage
self.total_traj = total_traj
self.stochastic_frame = stochastic_frame
assert self.path.is_dir(), "Path is not a directory"
db_paths = sorted(self.path.glob("*.lmdb"))
assert len(db_paths) > 0, f"No LMDBs found in '{self.path}'"
self._keys = []
if total_traj:
self._nums = []
self.envs = []
self.SubsetOnly = SubsetOnly
self.postfix = ""
if SubsetOnly:
self.postfix = "_Subset"
for i, db_path in enumerate(db_paths):
if SubsetOnly:
if 'Data06.lmdb' not in str(db_path):
continue
# If we're generating the test set, skip all lmdbs that aren't the test otherwise skip only the test lmdb
if getTest:
if 'test.lmdb' not in str(db_path):
continue
else:
if 'test.lmdb' in str(db_path):
continue
cur_env = self.connect_db(db_path)
self.envs.append(cur_env)
lmdb_name = Path(str(db_path)).stem
if os.path.exists(self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}.txt')):
self._keys.append(self.load_keys(lmdb_name))
else:
with cur_env.begin() as txn:
all_keys = [key for key in tqdm(txn.cursor().iternext(values=False))]
filter_keys = filter_valid_keys(db_path, all_keys, self.stage, not self.SubsetOnly)
self._keys.append(filter_keys)
self.save_keys(filter_keys, lmdb_name)
if total_traj:
if os.path.exists(
self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}_number.txt')):
self._nums.append(self.load_nums(lmdb_name))
else:
numbers = get_valid_nums(db_path, self._keys[-1], self.stage, not self.SubsetOnly)
self._nums.append(numbers)
self.save_numbers(numbers, lmdb_name)
if not total_traj:
keylens = [len(k) for k in self._keys]
self._keylen_cumulative = np.cumsum(keylens).tolist()
self.num_samples = sum(keylens)
else:
keylens = [sum(k) for k in self._nums]
self._keylen_cumulative = np.cumsum(keylens).tolist()
self._num_cumulative = [np.cumsum(k).tolist() for k in
self._nums]
self.num_samples = sum(
keylens)
nums_flat = np.concatenate([np.array(nums) for nums in self._nums])
cumulative_nums = np.cumsum(nums_flat)
start_indices = np.concatenate(([0], cumulative_nums[:-1]))
self.trajectory_indices = list(zip(start_indices.tolist(), cumulative_nums.tolist()))
self.transform = transform
self.maximum_dist = 0
def save_keys(self, keys, lmdb_name):
with open(self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}.txt'), 'w') as f:
for key in keys:
f.write(key.hex() + '\n')
def save_numbers(self, numbers, lmdb_name):
with open(self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}_number.txt'), 'w') as f:
for num in numbers:
f.write(str(num) + '\n')
def load_keys(self, lmdb_name):
with open(self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}.txt'), 'r') as f:
keys = [bytes.fromhex(line.strip()) for line in f]
return keys
def load_nums(self, lmdb_name):
with open(self.path / Path(self.keys_file + f'_{lmdb_name}_{self.stage}{self.postfix}_number.txt'), 'r') as f:
nums = [int(line.strip()) for line in f]
return nums
def __len__(self) -> int:
return self.num_samples
def __getitem__(self, idx: int):
db_idx = bisect.bisect(self._keylen_cumulative, idx)
el_idx = idx
if db_idx != 0:
el_idx = idx - self._keylen_cumulative[db_idx - 1]
assert el_idx >= 0
if not self.total_traj:
datapoint_pickled = (
self.envs[db_idx]
.begin()
.get(self._keys[db_idx][el_idx])
)
data_objects = data_to_pyg(pickle.loads(gzip.decompress(datapoint_pickled)), self._keys[db_idx][el_idx], filter=not self.SubsetOnly)
if len(data_objects) == 0:
return None
if self.transform is not None:
data_objects = [self.transform(data_object, self.stochastic_frame) for data_object in data_objects]
return random.choice(data_objects)
else:
num_idx = bisect.bisect(self._num_cumulative[db_idx], el_idx)
data_idx = el_idx
if num_idx != 0:
data_idx = el_idx - self._num_cumulative[db_idx][num_idx - 1]
assert data_idx >= 0
datapoint_pickled = (
self.envs[db_idx]
.begin()
.get(self._keys[db_idx][num_idx])
)
data_objects = data_to_pyg(pickle.loads(gzip.decompress(datapoint_pickled)), self._keys[db_idx][num_idx], filter=not self.SubsetOnly)
data_object = data_objects[data_idx]
if self.transform is not None:
data_object = self.transform(data_object, self.stochastic_frame)
return data_object
def connect_db(self, lmdb_path: Optional[Path] = None) -> lmdb.Environment:
env = lmdb.open(
str(lmdb_path),
subdir=False,
readonly=True,
lock=False,
readahead=False,
meminit=False,
max_readers=128,
)
return env
def close_db(self) -> None:
self.env.close()
class CommonLMDBDataset(Dataset):
def __init__(self, path, transform=None) -> None:
super(CommonLMDBDataset, self).__init__()
self.path = Path(path)
assert self.path.is_file(), "Path is not a file"
self.env = self.connect_db(self.path)
self.transform = transform
def __len__(self) -> int:
with self.env.begin() as txn:
self.all_keys = [key for key in tqdm(txn.cursor().iternext(values=False))]
return len(self.all_keys)
def __getitem__(self, idx: int):
datapoint_pickled = self.env.begin().get(self.all_keys[idx])
data_object = pickle.loads(gzip.decompress(datapoint_pickled))
pos = random.choice([pos for pos in data_object.pos])
data_object.pos = pos
if self.transform is not None:
data_object = self.transform(data_object, self.stochastic_frame)
return data_object
def connect_db(self, lmdb_path: Optional[Path] = None) -> lmdb.Environment:
env = lmdb.open(
str(lmdb_path),
subdir=False,
readonly=True,
lock=False,
readahead=False,
meminit=False,
max_readers=128,
)
return env
def close_db(self) -> None:
self.env.close()
def initialize_datasets(root, transform, stage, total_traj, SubsetOnly, stochastic_frame):
lmdb_dataset = LMDBDataset(
root,
transform=transform,
stage=stage,
total_traj=total_traj,
SubsetOnly=SubsetOnly,
stochastic_frame=stochastic_frame
)
if not total_traj:
train_size = int(0.8 * len(lmdb_dataset))
val_size = len(lmdb_dataset) - train_size
with open('splits/new_split.json' if SubsetOnly else 'splits/new_split_full.json', 'r') as f:
split = json.load(f)
mol_indices = list(range(len(lmdb_dataset)))
mol_indices_np = np.array(mol_indices)
train_trajectory_indices = (mol_indices_np[split['train']]).tolist()
val_trajectory_indices = (mol_indices_np[split['val']]).tolist()
train_dataset = Subset(lmdb_dataset, train_trajectory_indices)
val_dataset = Subset(lmdb_dataset, val_trajectory_indices)
else:
num_trajectories = len(lmdb_dataset.trajectory_indices)
trajectory_indices = list(range(num_trajectories))
with open('splits/new_split.json' if SubsetOnly else 'splits/new_split_full.json', 'r') as f:
split = json.load(f)
trajectory_indices_np = np.array(trajectory_indices)
train_trajectory_indices = (trajectory_indices_np[split['train']]).tolist()
val_trajectory_indices = (trajectory_indices_np[split['val']]).tolist()
train_snapshot_indices = []
val_snapshot_indices = []
for idx_set, snapshot_indices_set in zip(
[train_trajectory_indices, val_trajectory_indices],
[train_snapshot_indices, val_snapshot_indices],
):
for traj_idx in idx_set:
start_idx, end_idx = lmdb_dataset.trajectory_indices[traj_idx]
snapshot_indices_set.extend(range(start_idx, end_idx))
train_dataset = Subset(lmdb_dataset, train_snapshot_indices)
val_dataset = Subset(lmdb_dataset, val_snapshot_indices)
lmdb_test_dataset = LMDBDataset(
root,
transform=transform,
stage=stage,
total_traj=True,
SubsetOnly=False,
getTest=True,
stochastic_frame=stochastic_frame
)
test_snapshot_indices = []
for start_idx, end_idx in lmdb_test_dataset.trajectory_indices:
test_snapshot_indices.extend(range(start_idx, end_idx))
test_dataset = Subset(lmdb_test_dataset, test_snapshot_indices)
return {"train": train_dataset, "val": val_dataset, "test": test_dataset}
def scale_transform(data, stochastic_frame=False):
y_scale = (data.y - _MEAN_ENERGY) / _STD_ENERGY
data.y = y_scale
data.y_force = data.y_force / _STD_FORCE_SCALE
data.pos = data.pos - data.pos.mean(0, keepdim=True)
data.num_atoms = data.pos.size(0)
if stochastic_frame:
plus_minus_list = list(product([1, -1], repeat=3))
index = random.randint(0, len(plus_minus_list) - 1)
signs = plus_minus_list[index]
Q = torch.linalg.eig(data.pos.T @ data.pos)[1] * torch.tensor(signs).unsqueeze(0)
data.Q = Q.to(torch.float32).unsqueeze(0).expand(data.pos.size(0), 3, 3)
return data
class LMDBDataLoader:
def __init__(
self,
root,
batch_size=32,
num_workers=4,
stage='1st',
total_traj=False,
SubsetOnly=False,
stochastic_frame=False
) -> None:
self.batch_size = batch_size
self.num_workers = num_workers
self.datasets = initialize_datasets(root, scale_transform, stage, total_traj,
SubsetOnly=SubsetOnly, stochastic_frame=stochastic_frame)
def train_loader(self, distributed=False):
if distributed:
sampler = DistributedSampler(self.datasets["train"])
else:
subset_indices = torch.randperm(len(self.datasets["train"]))
sampler = SubsetRandomSampler(subset_indices)
return DataLoader(
self.datasets["train"],
batch_size=self.batch_size,
drop_last=False,
num_workers=self.num_workers,
sampler=sampler,
pin_memory=True,
)
def val_loader(self, distributed=False):
if distributed:
sampler = DistributedSampler(self.datasets["val"])
return DataLoader(
self.datasets["val"],
batch_size=self.batch_size,
drop_last=False,
num_workers=self.num_workers,
sampler=sampler,
pin_memory=True,
)
return DataLoader(
self.datasets["val"],
batch_size=self.batch_size,
drop_last=False,
num_workers=self.num_workers,
pin_memory=True,
)
def test_loader(self, distributed=False):
if distributed:
sampler = DistributedSampler(self.datasets["test"])
return DataLoader(
self.datasets["test"],
batch_size=self.batch_size,
drop_last=False,
num_workers=self.num_workers,
sampler=sampler,
pin_memory=True,
)
return DataLoader(
self.datasets["test"],
batch_size=self.batch_size,
drop_last=False,
num_workers=self.num_workers,
pin_memory=True,
)
def serialize_and_compress(data: Data):
"""
Serializes the Data object using msgpack and compresses it using lz4.
"""
return gzip.compress(pickle.dumps(data)) |