Dean
/
Chemformer
mirror of https://github.com/MolecularAI/Chemformer


  
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            import random

import pytest
import torch

from molbart.models.transformer_models import BARTModel
from molbart.modules.data.util import BatchEncoder
from molbart.modules.decoder import DecodeSampler
from molbart.modules.tokenizer import ChemformerTokenizer, ReplaceTokensMasker

regex = r"\[[^\]]+]|Br?|Cl?|N|O|S|P|F|I|b|c|n|o|s|p|\(|\)|\.|=|#|-|\+|\\\\|\/|:|~|@|\?|>|\*|\$|\%[0-9]{2}|[0-9]"

# Use dummy SMILES strings
react_data = ["CCO.C", "CCCl", "C(=O)CBr"]

# Use dummy SMILES strings
prod_data = ["cc", "CCl", "CBr"]

model_args = {
    "d_model": 5,
    "num_layers": 2,
    "num_heads": 1,
    "d_feedforward": 32,
    "lr": 0.0001,
    "weight_decay": 0.0,
    "activation": "gelu",
    "num_steps": 1000,
    "max_seq_len": 40,
}

random.seed(a=1)
torch.manual_seed(1)


@pytest.fixture
def setup_encoder():
    tokeniser = ChemformerTokenizer(
        smiles=react_data + prod_data, regex_token_patterns=regex.split(".")
    )
    masker = ReplaceTokensMasker(tokeniser)
    encoder = BatchEncoder(
        tokeniser, masker=masker, max_seq_len=model_args["max_seq_len"]
    )
    return tokeniser, masker, encoder


def test_pos_emb_shape(setup_encoder):
    tokeniser, _, _ = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)

    pos_embs = model._positional_embs()

    assert pos_embs.shape[0] == model_args["max_seq_len"]
    assert pos_embs.shape[1] == model.d_model


def test_construct_input_shape(setup_encoder):
    tokeniser, _, encoder = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)
    token_ids, mask = encoder(react_data)

    emb = model._construct_input(token_ids, mask)

    assert emb.shape[0] == max([len(ts) for ts in token_ids.transpose(0, 1)])
    assert emb.shape[1] == 3
    assert emb.shape[2] == model_args["d_model"]


def test_bart_forward_shape(setup_encoder):
    tokeniser, _, encoder = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)

    react_ids, react_mask = encoder(react_data, mask=True)
    prod_ids, prod_mask = encoder(prod_data, mask=True)

    batch_input = {
        "encoder_input": react_ids,
        "encoder_pad_mask": react_mask,
        "decoder_input": prod_ids,
        "decoder_pad_mask": prod_mask,
    }

    output = model(batch_input)
    model_output = output["model_output"]
    token_output = output["token_output"]

    exp_seq_len = 4  # From expected tokenised length of prod data
    exp_batch_size = len(prod_data)
    exp_dim = model_args["d_model"]
    exp_vocab_size = len(tokeniser)

    assert tuple(model_output.shape) == (exp_seq_len, exp_batch_size, exp_dim)
    assert tuple(token_output.shape) == (exp_seq_len, exp_batch_size, exp_vocab_size)


def test_bart_encode_shape(setup_encoder):
    tokeniser, _, encoder = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)

    react_ids, react_mask = encoder(react_data)

    batch_input = {"encoder_input": react_ids, "encoder_pad_mask": react_mask}

    output = model.encode(batch_input)

    exp_seq_len = 9  # From expected tokenised length of react data
    exp_batch_size = len(react_data)
    exp_dim = model_args["d_model"]

    assert tuple(output.shape) == (exp_seq_len, exp_batch_size, exp_dim)


def test_bart_decode_shape(setup_encoder):
    tokeniser, _, encoder = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)

    react_ids, react_mask = encoder(react_data)
    encode_input = {"encoder_input": react_ids, "encoder_pad_mask": react_mask}

    memory = model.encode(encode_input)

    prod_ids, prod_mask = encoder(prod_data)
    batch_input = {
        "decoder_input": prod_ids,
        "decoder_pad_mask": prod_mask,
        "memory_input": memory,
        "memory_pad_mask": react_mask,
    }

    output = model.decode(batch_input)

    exp_seq_len = 4  # From expected tokenised length of prod data
    exp_batch_size = len(react_data)
    exp_vocab_size = len(tokeniser)

    assert tuple(output.shape) == (exp_seq_len, exp_batch_size, exp_vocab_size)


def test_calc_token_acc(setup_encoder):
    tokeniser, _, encoder = setup_encoder
    pad_token_idx = tokeniser["pad"]
    sampler = DecodeSampler(tokeniser, model_args["max_seq_len"])
    model = BARTModel(sampler, pad_token_idx, len(tokeniser), **model_args)

    react_ids, react_mask = encoder(react_data[1:])
    target_ids = react_ids[1:, :]
    target_mask = react_mask[1:, :]

    # 9 is expected seq len of react data when padded
    token_output = torch.rand([8, len(react_data[1:]), len(tokeniser)])

    """
    Expected outputs
    CCCl
    C(=O)CBr

    Vocab:
    0 <PAD>
    3 &
    6 C
    7 O
    8 .
    9 Cl
    10 (
    11 =
    12 )
    13 Br
    """

    # Batch element 0
    token_output[0, 0, 6] += 1
    token_output[1, 0, 6] -= 1
    token_output[2, 0, 9] += 1
    token_output[3, 0, 3] += 1
    token_output[4, 0, 0] += 1
    token_output[5, 0, 0] -= 1

    # Batch element 1
    token_output[0, 1, 6] += 1
    token_output[1, 1, 10] += 1
    token_output[2, 1, 11] += 1
    token_output[3, 1, 7] += 1
    token_output[4, 1, 12] -= 1
    token_output[5, 1, 6] += 1
    token_output[6, 1, 13] -= 1
    token_output[7, 1, 3] += 1

    batch_input = {"target": target_ids, "target_mask": target_mask}
    model_output = {"token_output": token_output}
    token_acc = model._calc_token_acc(batch_input, model_output)

    exp_token_acc = (3 + 6) / (4 + 8)

    assert exp_token_acc == token_acc