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import numpy as np | |
import torch | |
import torch.nn.functional as F | |
import torchaudio | |
from matplotlib.animation import FuncAnimation | |
def l2_normalize(matrix): | |
""" | |
L2 Normalize the matrix along its rows. | |
Parameters: | |
matrix (numpy.ndarray): The input matrix. | |
Returns: | |
numpy.ndarray: The L2 normalized matrix. | |
""" | |
l2_norms = np.linalg.norm(matrix, axis=1, keepdims=True) | |
normalized_matrix = matrix / l2_norms | |
return normalized_matrix | |
def z_normalize(matrix): | |
""" | |
Z-normalize the matrix along its rows (mean=0 and std=1). | |
Z-normalization is also known as "standardization", and derives from z-score. | |
Z = (X - mean) / std | |
Z-nomarlized, each row has mean=0 and std=1. | |
Parameters: | |
matrix (numpy.ndarray): The input matrix. | |
Returns: | |
numpy.ndarray: The Z normalized matrix. | |
""" | |
mean = np.mean(matrix, axis=1, keepdims=True) | |
std = np.std(matrix, axis=1, keepdims=True) | |
normalized_matrix = (matrix - mean) / std | |
return normalized_matrix | |
def l2_normalize_tensors(tensor_tuple): | |
""" | |
Applies L2 normalization on the last two dimensions for each tensor in a tuple. | |
Parameters: | |
tensor_tuple (tuple of torch.Tensor): A tuple containing N tensors, each of shape (1, k, 30, 30). | |
Returns: | |
tuple of torch.Tensor: A tuple containing N L2-normalized tensors. | |
""" | |
normalized_tensors = [] | |
for tensor in tensor_tuple: | |
# Ensure the tensor is a floating-point type | |
tensor = tensor.float() | |
# Calculate L2 norm on the last two dimensions, keeping the dimensions using keepdim=True | |
l2_norm = torch.linalg.norm(tensor, dim=(-2, -1), keepdim=True) | |
# Apply L2 normalization | |
normalized_tensor = tensor / ( | |
l2_norm + 1e-7) # Small value to avoid division by zero | |
normalized_tensors.append(normalized_tensor) | |
return tuple(normalized_tensors) | |
def z_normalize_tensors(tensor_tuple): | |
""" | |
Applies Z-normalization on the last two dimensions for each tensor in a tuple. | |
Parameters: | |
tensor_tuple (tuple of torch.Tensor): A tuple containing N tensors, each of shape (1, k, 30, 30). | |
Returns: | |
tuple of torch.Tensor: A tuple containing N Z-normalized tensors. | |
""" | |
normalized_tensors = [] | |
for tensor in tensor_tuple: | |
# Ensure the tensor is a floating-point type | |
tensor = tensor.float() | |
# Calculate mean and std on the last two dimensions | |
mean = tensor.mean(dim=(-2, -1), keepdim=True) | |
std = tensor.std(dim=(-2, -1), keepdim=True) | |
# Apply Z-normalization | |
normalized_tensor = (tensor - mean) / ( | |
std + 1e-7) # Small value to avoid division by zero | |
normalized_tensors.append(normalized_tensor) | |
return tuple(normalized_tensors) | |
def apply_temperature_to_attention_tensors(tensor_tuple, temperature=1.0): | |
""" | |
Applies temperature scaling to the attention weights in each tensor in a tuple. | |
Parameters: | |
tensor_tuple (tuple of torch.Tensor): A tuple containing N tensors, | |
each of shape (1, k, 30, 30). | |
temperature (float): Temperature parameter to control the sharpness | |
of the attention weights. Default is 1.0. | |
Returns: | |
tuple of torch.Tensor: A tuple containing N tensors with scaled attention weights. | |
""" | |
scaled_attention_tensors = [] | |
for tensor in tensor_tuple: | |
# Ensure the tensor is a floating-point type | |
tensor = tensor.float() | |
# Flatten the last two dimensions | |
flattened_tensor = tensor.reshape(1, tensor.shape[1], | |
-1) # Modified line here | |
# Apply temperature scaling and softmax along the last dimension | |
scaled_attention = flattened_tensor / temperature | |
scaled_attention = F.softmax(scaled_attention, dim=-1) | |
# Reshape to original shape | |
scaled_attention = scaled_attention.view_as(tensor) | |
scaled_attention_tensors.append(scaled_attention) | |
return tuple(scaled_attention_tensors) | |
def shorten_att(tensor_tuple, length=30): | |
shortend_tensors = [] | |
for tensor in tensor_tuple: | |
shortend_tensors.append(tensor[:, :, :length, :length]) | |
return tuple(shortend_tensors) | |
def keep_top_k(matrix, k=6): | |
""" | |
Keep only the top k values in each row, set the rest to 0. | |
Parameters: | |
matrix (numpy.ndarray): The input matrix. | |
k (int): The number of top values to keep in each row. | |
Returns: | |
numpy.ndarray: The transformed matrix. | |
""" | |
topk_indices_per_row = np.argpartition(matrix, -k, axis=1)[:, -k:] | |
result_matrix = np.zeros_like(matrix) | |
for i in range(matrix.shape[0]): | |
result_matrix[i, topk_indices_per_row[i]] = matrix[ | |
i, topk_indices_per_row[i]] | |
return result_matrix | |
def test_case_forward_enc_perceiver_tf_dec_multi_t5(): | |
import torch | |
from model.ymt3 import YourMT3 | |
from config.config import audio_cfg, model_cfg, shared_cfg | |
model_cfg["encoder_type"] = "perceiver-tf" | |
model_cfg["encoder"]["perceiver-tf"]["attention_to_channel"] = True | |
model_cfg["encoder"]["perceiver-tf"]["num_latents"] = 26 | |
model_cfg["decoder_type"] = "multi-t5" | |
audio_cfg["codec"] = "spec" | |
audio_cfg["hop_length"] = 300 | |
model = YourMT3(audio_cfg=audio_cfg, model_cfg=model_cfg) | |
model.eval() | |
# x = torch.randn(2, 1, 32767) | |
# labels = torch.randint(0, 400, (2, 1024), requires_grad=False) | |
# # forward | |
# output = model.forward(x, labels) | |
# # inference | |
# result = model.inference(x, None) | |
# display latents | |
checkpoint = torch.load( | |
"../logs/ymt3/ptf_mc13_256_all_cross_v6_xk5_amp0811_edr005_attend_c_full_plus_2psn_nl26_sb_b26r_800k/checkpoints/model.ckpt", | |
map_location="cpu") | |
state_dict = checkpoint['state_dict'] | |
new_state_dict = { | |
k: v | |
for k, v in state_dict.items() if 'pitchshift' not in k | |
} | |
model.load_state_dict(new_state_dict, strict=False) | |
latents = model.encoder.latent_array.latents.detach().numpy() | |
import matplotlib.pyplot as plt | |
import numpy as np | |
from sklearn.metrics.pairwise import cosine_similarity | |
cos = cosine_similarity(latents) | |
from utils.data_modules import AMTDataModule | |
from einops import rearrange | |
# dm = AMTDataModule(data_preset_multi={"presets": ["slakh"]}) | |
#dm.setup("test") | |
# dl = dm.test_dataloader() | |
# ds = list(dl.values())[0].dataset | |
# audio, notes, tokens, _ = ds.__getitem__(7) | |
# x = audio[[16], ::] | |
# label = tokens[[16], :] | |
# from utils.task_manager import TaskManager | |
# tm = TaskManager(task_name='mc13_256') | |
# dm = AMTDataModule(data_preset_multi={"presets": ["slakh"]}, | |
# task_manager=tm, | |
# train_stem_iaug_prob=None, | |
# train_stem_xaug_policy=None) | |
# dm.setup('fit') | |
# dl = dm.train_dataloader() | |
# ds = dl.flattened[0].dataset | |
# audio,tokens, _, _ = ds.__getitem__(67) | |
# x = audio[[5], ::] | |
# label = tokens[[5], :] | |
# save audio | |
# torchaudio.save("singing.wav", x[0, :, :], 16000) | |
x, _ = torchaudio.load('piano.wav')#'test.wav') | |
x = x.unsqueeze(0) | |
# spectrogram | |
x_spec = model.spectrogram(x) | |
x_conv = model.pre_encoder(x_spec) | |
# Create a larger figure | |
plt.figure( | |
figsize=(15, | |
10)) # Adjust these numbers as needed for width and height | |
plt.subplot(2, 4, 1) | |
plt.imshow(x_spec[0].detach().numpy().T, aspect='auto', origin='lower') | |
plt.title("spectrogram") | |
plt.xlabel('time step') | |
plt.ylabel('frequency bin') | |
plt.subplot(2, 4, 2) | |
plt.imshow(x_conv[0][:, :, 0].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("conv(spec), ch=0") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 3) | |
plt.imshow(x_conv[0][:, :, 42].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=42") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 4) | |
plt.imshow(x_conv[0][:, :, 80].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=80") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 5) | |
plt.imshow(x_conv[0][:, :, 11].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=11") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 6) | |
plt.imshow(x_conv[0][:, :, 20].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=20") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 7) | |
plt.imshow(x_conv[0][:, :, 77].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=77") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.subplot(2, 4, 8) | |
plt.imshow(x_conv[0][:, :, 90].detach().numpy().T, | |
aspect='auto', | |
origin='lower') | |
plt.title("ch=90") | |
plt.xlabel('time step') | |
plt.ylabel('F') | |
plt.tight_layout() | |
plt.show() | |
# encoding | |
output = model.encoder(inputs_embeds=x_conv, | |
output_hidden_states=True, | |
output_attentions=True) | |
enc_hs_all, att, catt = output["hidden_states"], output[ | |
"attentions"], output["cross_attentions"] | |
enc_hs_last = enc_hs_all[2] | |
# enc_hs: time-varying encoder hidden state | |
plt.subplot(2, 3, 1) | |
plt.imshow(enc_hs_all[0][0][:, :, 21].detach().numpy().T) | |
plt.title('ENC_HS B0, d21') | |
plt.colorbar(orientation='horizontal') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.subplot(2, 3, 4) | |
plt.imshow(enc_hs_all[0][0][:, :, 127].detach().numpy().T) | |
plt.colorbar(orientation='horizontal') | |
plt.title('B0, d127') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.subplot(2, 3, 2) | |
plt.imshow(enc_hs_all[1][0][:, :, 21].detach().numpy().T) | |
plt.colorbar(orientation='horizontal') | |
plt.title('B1, d21') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.subplot(2, 3, 5) | |
plt.imshow(enc_hs_all[1][0][:, :, 127].detach().numpy().T) | |
plt.colorbar(orientation='horizontal') | |
plt.title('B1, d127') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.subplot(2, 3, 3) | |
plt.imshow(enc_hs_all[2][0][:, :, 21].detach().numpy().T) | |
plt.colorbar(orientation='horizontal') | |
plt.title('B2, d21') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.subplot(2, 3, 6) | |
plt.imshow(enc_hs_all[2][0][:, :, 127].detach().numpy().T) | |
plt.colorbar(orientation='horizontal') | |
plt.title('B2, d127') | |
plt.ylabel('latent k') | |
plt.xlabel('t') | |
plt.tight_layout() | |
plt.show() | |
# enc_hs: time-varying encoder hidden state by k (block, 1, t, k, d) | |
# --> (t, d) for each k in last block | |
data = enc_hs_all[2][0].detach().numpy() # (T, K, D) | |
fig, axs = plt.subplots( | |
5, 5, figsize=(10, 9)) # 25 subplots arranged in 5 rows and 5 columns | |
axs = axs.flatten( | |
) # Flatten the 2D array of axes to 1D for easy iteration | |
for k in range(25): # Iterating through K indices from 0 to 24 | |
axs[k].imshow(data[:, k, :].T, | |
cmap='viridis') # Transposing the matrix to swap T and D | |
axs[k].set_title(f'k={k}') | |
axs[k].set_xlabel('Time step') | |
axs[k].set_ylabel('Dim') | |
# Adjusting layout for better visibility | |
plt.tight_layout() | |
plt.show() | |
#!! Projected encoder hidden state for 13 channels, that is conditioning for decoder | |
enc_hs_proj = model.pre_decoder(enc_hs_last) | |
fig, axs = plt.subplots(1, 13, figsize=(26, 8)) # 13 subplots in a row | |
data = enc_hs_proj[0].detach().numpy() | |
for ch in range(13): | |
axs[ch].imshow(np.rot90(data[ch]), cmap='viridis') # Rotate 90 degrees | |
axs[ch].set_title(f'ch: {ch}') | |
axs[ch].set_xlabel('Time step') | |
axs[ch].set_ylabel('Dim') | |
plt.suptitle( | |
'linear projection of encoder outputs by channel, which is conditioning for enc-dec cross attention', | |
y=0.1, | |
fontsize=12) | |
plt.tight_layout(rect=[0, 0.1, 1, 1]) | |
plt.show() | |
plt.subplot(221) | |
plt.imshow(enc_hs_all[2][0][0, :, :].detach().numpy(), aspect='auto') | |
plt.title('enc_hs, t=0') | |
plt.ylabel('latent k') | |
plt.xlabel('d') | |
plt.subplot(222) | |
plt.imshow(enc_hs_all[2][0][10, :, :].detach().numpy(), aspect='auto') | |
plt.title('enc_hs, t=10') | |
plt.ylabel('latent k') | |
plt.xlabel('d') | |
plt.subplot(223) | |
plt.imshow(enc_hs_all[2][0][20, :, :].detach().numpy(), aspect='auto') | |
plt.title('enc_hs, t=20') | |
plt.ylabel('latent k') | |
plt.xlabel('d') | |
plt.subplot(224) | |
plt.imshow(enc_hs_all[2][0][30, :, :].detach().numpy(), aspect='auto') | |
plt.title('enc_hs, t=30') | |
plt.ylabel('latent k') | |
plt.xlabel('d') | |
plt.tight_layout() | |
plt.show() | |
# enc_hs correlation: which dim has most unique info? | |
plt.subplot(1, 3, 1) | |
a = rearrange(enc_hs_last, '1 t k d -> t (k d)').detach().numpy() | |
plt.imshow(cosine_similarity(a)) | |
plt.title("enc hs, t x t cos_sim") | |
plt.subplot(1, 3, 2) | |
b = rearrange(enc_hs_last, '1 t k d -> k (t d)').detach().numpy() | |
plt.imshow(cosine_similarity(b)) | |
plt.title("enc hs, k x k cos_sim") | |
plt.subplot(1, 3, 3) | |
c = rearrange(enc_hs_last, '1 t k d -> d (k t)').detach().numpy() | |
plt.imshow(cosine_similarity(c)) | |
plt.title("cross att, d x d cos_sim") | |
plt.tight_layout() | |
plt.show() | |
#!! enc latent | |
plt.imshow(model.encoder.latent_array.latents.detach().numpy()) | |
plt.title('latent array') | |
plt.xlabel('d') | |
plt.ylabel('latent k') | |
plt.show() | |
#!! enc Spectral Cross Attention: (T x head x K x D). How latent K attends to conv channel C? | |
plt.subplot(311) | |
plt.imshow( | |
torch.sum(torch.sum(catt[0][0], axis=0), axis=0).detach().numpy()) | |
plt.title('block=0') | |
plt.ylabel('latent k') | |
plt.xlabel('conv channel') | |
plt.subplot(312) | |
plt.imshow( | |
torch.sum(torch.sum(catt[1][0], axis=0), axis=0).detach().numpy()) | |
plt.title('block=1') | |
plt.ylabel('latent k') | |
plt.xlabel('conv channel') | |
plt.subplot(313) | |
plt.imshow( | |
torch.sum(torch.sum(catt[2][0], axis=0), axis=0).detach().numpy()) | |
plt.title('block=2') | |
plt.ylabel('latent k') | |
plt.xlabel('conv channel') | |
# f'spectral cross attention. T-C-F Model', | |
# y=0, | |
# fontsize=12) | |
plt.tight_layout() | |
plt.show() | |
#!! Animation of SCA for varying time, head in last block | |
fig, (ax1, ax2) = plt.subplots(2, 1, figsize=(10, 6)) # Adjusted figsize for better layout | |
# Function to update the plots for each frame in the animation | |
def update(t): | |
# Clear previous images | |
ax1.clear() | |
ax2.clear() | |
# Update subplot for h=3 | |
ax1.imshow(catt[2][0][t, 3, :, :].detach().numpy()) | |
ax1.set_title(f'block=2, t={t}, head=3') | |
ax1.set_ylabel('latent k'); ax1.set_xlabel('conv channel') | |
# Update subplot for h=5 | |
ax2.imshow(catt[2][0][t, 5, :, :].detach().numpy()) | |
ax2.set_title(f'block=2, t={t}, head=5') | |
ax2.set_ylabel('latent k'); ax2.set_xlabel('conv channel') | |
# Adjust layout | |
fig.tight_layout() | |
# Create the animation | |
anim = FuncAnimation(fig, update, frames=range(0, 110), interval=200) | |
anim.save('animation.gif', writer='pillow', fps=5) | |
fig, axs = plt.subplots(3, 1, figsize=(12, 18), gridspec_kw={'height_ratios': [1, 1, 0.5]}) # Adjusted for different subplot sizes | |
# Subplots for catt visualization (h=3 and h=5) | |
ax_catt3, ax_catt5, ax_att_row = axs | |
# Creating 8 subplots for att visualization within the third row | |
for i in range(8): | |
ax_att_row = fig.add_subplot(3, 8, 17 + i) # Adding subplots in the third row | |
# Update function for the combined animation | |
def combined_update_smaller_att(t): | |
# Update subplot for catt with h=3 | |
ax_catt3.clear() | |
ax_catt3.imshow(catt[2][0][t, 3, :, :].detach().numpy()) | |
ax_catt3.set_title(f'block=2, t={t}, head=3') | |
ax_catt3.set_ylabel('latent k'); ax_catt3.set_xlabel('conv channel') | |
# Update subplot for catt with h=5 | |
ax_catt5.clear() | |
ax_catt5.imshow(catt[2][0][t, 5, :, :].detach().numpy()) | |
ax_catt5.set_title(f'block=2, t={t}, head=5') | |
ax_catt5.set_ylabel('latent k'); ax_catt5.set_xlabel('conv channel') | |
# Update subplots for att (8 heads in one row) | |
for i in range(8): | |
ax = fig.add_subplot(3, 8, 17 + i) | |
ax.clear() | |
ax.imshow(att[0][1][t, i, :, :].detach().numpy(), cmap='viridis') | |
ax.set_title(f't={t}, head={i}') | |
ax.set_xlabel('k') | |
ax.set_ylabel('k') | |
ax.axis('square') # Make each subplot square-shaped | |
# Adjust layout | |
fig.tight_layout() | |
combined_anim_smaller_att = FuncAnimation(fig, combined_update_smaller_att, frames=range(0, 110), interval=200) | |
combined_anim_smaller_att.save('combined_animation_smaller_att.gif', writer='pillow', fps=5) | |
# enc Latent Self-attention: How latent K attends to K? | |
plt.subplot(231) | |
plt.imshow(torch.sum(torch.sum(att[0][0], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B0L0') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.subplot(234) | |
plt.imshow(torch.sum(torch.sum(att[0][1], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B0L1') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.subplot(232) | |
plt.imshow(torch.sum(torch.sum(att[1][0], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B1L0') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.subplot(235) | |
plt.imshow(torch.sum(torch.sum(att[1][1], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B1L1') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.subplot(233) | |
plt.imshow(torch.sum(torch.sum(att[2][0], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B2L0') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.subplot(236) | |
plt.imshow(torch.sum(torch.sum(att[2][1], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B2L1') | |
plt.xlabel('latent k') | |
plt.ylabel('latent k') | |
plt.tight_layout() | |
plt.show() | |
# Time varying, different head for latent self-attention | |
#!!! Display latent self-attention for each head | |
bl = 0 # first latent transformer block, last layer att | |
data = att[bl][1].detach().numpy() | |
time_steps = [30, 50, 100] | |
fig, axs = plt.subplots( | |
len(time_steps), 8, | |
figsize=(16, 6)) # Subplots for each time step and head | |
for i, t in enumerate(time_steps): | |
for head in range(8): | |
axs[i, head].imshow(data[t, head, :, :], cmap='viridis') | |
axs[i, head].set_title(f't={t}, head={head}') | |
axs[i, head].set_xlabel('k') | |
axs[i, head].set_ylabel('k') | |
plt.suptitle( | |
f'latent transformer block={bl}, last layer self-attention over time', | |
y=0, | |
fontsize=12) | |
plt.tight_layout() | |
plt.show() | |
bl = 1 # second latent transformer block, last layer att | |
data = att[bl][1].detach().numpy() | |
time_steps = [30, 50, 100] | |
fig, axs = plt.subplots( | |
len(time_steps), 8, | |
figsize=(16, 6)) # Subplots for each time step and head | |
for i, t in enumerate(time_steps): | |
for head in range(8): | |
axs[i, head].imshow(data[t, head, :, :], cmap='viridis') | |
axs[i, head].set_title(f't={t}, head={head}') | |
axs[i, head].set_xlabel('k') | |
axs[i, head].set_ylabel('k') | |
plt.suptitle( | |
f'latent transformer block={bl}, last layer self-attention over time', | |
y=0, | |
fontsize=12) | |
plt.tight_layout() | |
plt.show() | |
bl = 2 # last latent transformer block, last layer att | |
data = att[bl][1].detach().numpy() | |
time_steps = [30, 50, 100] | |
fig, axs = plt.subplots( | |
len(time_steps), 8, | |
figsize=(16, 6)) # Subplots for each time step and head | |
for i, t in enumerate(time_steps): | |
for head in range(8): | |
axs[i, head].imshow(data[t, head, :, :], cmap='viridis') | |
axs[i, head].set_title(f't={t}, head={head}') | |
axs[i, head].set_xlabel('k') | |
axs[i, head].set_ylabel('k') | |
plt.suptitle( | |
f'latent transformer block={bl}, last layer self-attention over time', | |
y=0, | |
fontsize=12) | |
plt.tight_layout() | |
plt.show() | |
# Temporal Self-attention: (K x H x T x T) How time t attends to time t? | |
plt.subplot(231) | |
plt.imshow(torch.sum(torch.sum(att[0][2], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B0L2') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.subplot(234) | |
plt.imshow(torch.sum(torch.sum(att[0][3], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B0L3') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.subplot(232) | |
plt.imshow(torch.sum(torch.sum(att[1][2], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B1L2') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.subplot(235) | |
plt.imshow(torch.sum(torch.sum(att[1][3], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B1L3') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.subplot(233) | |
plt.imshow(torch.sum(torch.sum(att[2][2], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B2L2') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.subplot(236) | |
plt.imshow(torch.sum(torch.sum(att[2][3], axis=1), | |
axis=0).detach().numpy(), | |
origin='upper') | |
plt.title('B2L3') | |
plt.xlabel('t') | |
plt.ylabel('t') | |
plt.tight_layout() | |
plt.show() | |
# decoding | |
dec_input_ids = model.shift_right_fn(label) | |
dec_inputs_embeds = model.embed_tokens(dec_input_ids) | |
dec_output = model.decoder(inputs_embeds=dec_inputs_embeds, | |
encoder_hidden_states=enc_hs_proj, | |
output_attentions=True, | |
output_hidden_states=True, | |
return_dict=True) | |
dec_att, dec_catt = dec_output.attentions, dec_output.cross_attentions | |
dec_hs_all = dec_output.hidden_states | |
dec_last_hs = dec_output.last_hidden_state | |
# lm head | |
logits = model.lm_head(dec_last_hs) | |
# pred ids | |
pred_ids = torch.argmax(logits, dim=3) | |
# dec att | |
plt.subplot(1, 2, 1) | |
plt.imshow(torch.sum(dec_att[5][0], axis=0).detach().numpy()) | |
plt.title('decoder attention, layer0') | |
plt.xlabel('decoder time step') | |
plt.ylabel('decoder time step') | |
plt.subplot(1, 2, 2) | |
plt.imshow(torch.sum(dec_att[7][0], axis=0).detach().numpy()) | |
plt.title('decoder attention, final layer') | |
plt.xlabel('decoder step') | |
plt.show() | |
# dec catt | |
def remove_values_after_eos(catt_np, pred_ids, max_k): | |
# catt_np: (k, head, t, t) | |
# pred_ids: (1, k, t)) | |
max_length = pred_ids.shape[-1] | |
seq_lengths = np.zeros((max_k), dtype=np.int32) | |
for k in range(max_k): | |
for t in range(max_length): | |
if pred_ids[0, k, t] == 1: | |
break | |
catt_np[k, :, t+1:, :] = 0 | |
# catt_np[k, :, :, t+1:] = 0 | |
seq_lengths[k] = t+1 | |
return catt_np, seq_lengths | |
# data = dec_catt[1].detach().numpy() # last layer's cross attention | |
l = 4 | |
data = dec_catt[l].detach().numpy() | |
data, seq_lengths = remove_values_after_eos(data, pred_ids, max_k=13) | |
seq_lengths[:]= 256 | |
fig, axs = plt.subplots(13, 6, figsize=(21, 39)) # 13 rows (for k=0:12) and 7 columns (for head=0:6) | |
for k in range(13): | |
s = seq_lengths[k] | |
for head in range(6): | |
axs[k, head].imshow(data[k, head, :s, :].T, aspect='auto', cmap='viridis') | |
axs[k, head].set_title(f'Layer {l}, k={k}, head={head}') | |
axs[k, head].set_xlabel('Decoder step') | |
axs[k, head].set_ylabel('Encoder frame') | |
plt.tight_layout() | |
plt.show() | |
# # dec catt by head with xxx | |
# dec_att_z = z_normalize_tensors(shorten_att(dec_att)) | |
# plt.imshow(dec_att_z[0][0, 0, :, :].detach().numpy()) | |
# from bertviz import head_view | |
# token = [] | |
# for i in label[0, :30]: | |
# token.append(str(i)) | |
# head_view(dec_att_z, tokens) | |
# dec_hs | |
plt.subplot(1, 2, 1) | |
k=2 | |
plt.imshow(dec_last_hs[0][k].detach().numpy(), origin='upper') | |
plt.colorbar(orientation='horizontal') | |
plt.title('decoder last hidden state, k=0') | |
plt.xlabel('hidden dim') | |
plt.ylabel('time step') | |
plt.subplot(1, 2, 2) | |
k=12 | |
plt.imshow(dec_last_hs[0][k].detach().numpy(), origin='upper') | |
plt.colorbar(orientation='horizontal') | |
plt.title('decoder last hidden state, k=12') | |
plt.xlabel('hidden dim') | |
plt.show() | |
# lm head | |
logits = model.lm_head(dec_last_hs) | |
k=6 | |
plt.imshow(logits[0][k][0:200, :].detach().numpy().T, origin='upper') | |
plt.title('lm head output') | |
plt.xlabel('vocab dim') | |
plt.ylabel('time step') | |
plt.show() | |
softmax = torch.nn.Softmax(dim=3) | |
logits_sm = softmax(logits) # B, K, T, V | |
k=6 | |
plt.imshow(logits_sm[0][k][:255, :].detach().numpy().T, origin='upper') | |
plt.title('lm head softmax') | |
plt.xlabel('vocab dim') | |
plt.ylabel('time step') | |
# plt.xlim([1000, 1350]) | |
plt.show() | |
k = 10 | |
print(torch.argmax(logits, dim=3)[0,k,:]) | |