import unittest
import torch as T

from layers.tacotron import Prenet, CBHG, Decoder, Encoder
from layers.losses import L1LossMasked
from utils.generic_utils import sequence_mask


class PrenetTests(unittest.TestCase):
    def test_in_out(self):
        layer = Prenet(128, out_features=[256, 128])
        dummy_input = T.rand(4, 128)

        print(layer)
        output = layer(dummy_input)
        assert output.shape[0] == 4
        assert output.shape[1] == 128


class CBHGTests(unittest.TestCase):
    def test_in_out(self):
        layer = self.cbhg = CBHG(
            128,
            K=8,
            conv_bank_features=80,
            conv_projections=[160, 128],
            highway_features=80,
            gru_features=80,
            num_highways=4)
        dummy_input = T.rand(4, 8, 128)

        print(layer)
        output = layer(dummy_input)
        assert output.shape[0] == 4
        assert output.shape[1] == 8
        assert output.shape[2] == 160


class DecoderTests(unittest.TestCase):
    def test_in_out(self):
        layer = Decoder(in_features=256, memory_dim=80, r=2, memory_size=4, attn_windowing=False, attn_norm="sigmoid")
        dummy_input = T.rand(4, 8, 256)
        dummy_memory = T.rand(4, 2, 80)

        output, alignment, stop_tokens = layer(dummy_input, dummy_memory, mask=None)

        assert output.shape[0] == 4
        assert output.shape[1] == 1, "size not {}".format(output.shape[1])
        assert output.shape[2] == 80 * 2, "size not {}".format(output.shape[2])
        assert stop_tokens.shape[0] == 4


class EncoderTests(unittest.TestCase):
    def test_in_out(self):
        layer = Encoder(128)
        dummy_input = T.rand(4, 8, 128)

        print(layer)
        output = layer(dummy_input)
        print(output.shape)
        assert output.shape[0] == 4
        assert output.shape[1] == 8
        assert output.shape[2] == 256  # 128 * 2 BiRNN


class L1LossMaskedTests(unittest.TestCase):
    def test_in_out(self):
        layer = L1LossMasked()
        dummy_input = T.ones(4, 8, 128).float()
        dummy_target = T.ones(4, 8, 128).float()
        dummy_length = (T.ones(4) * 8).long()
        output = layer(dummy_input, dummy_target, dummy_length)
        assert output.item() == 0.0

        dummy_input = T.ones(4, 8, 128).float()
        dummy_target = T.zeros(4, 8, 128).float()
        dummy_length = (T.ones(4) * 8).long()
        output = layer(dummy_input, dummy_target, dummy_length)
        assert output.item() == 1.0, "1.0 vs {}".format(output.data[0])
        dummy_input = T.ones(4, 8, 128).float()
        dummy_target = T.zeros(4, 8, 128).float()
        dummy_length = (T.arange(5, 9)).long()
        mask = (
            (sequence_mask(dummy_length).float() - 1.0) * 100.0).unsqueeze(2)
        output = layer(dummy_input + mask, dummy_target, dummy_length)
        assert output.item() == 1.0, "1.0 vs {}".format(output.data[0])