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EasyFL_with_...
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applications
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fedssl
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client_with_pgfed.py

client_with_pgfed.py 6.8 KB
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  1. import copy
    2. 

  2. import gc
    3. 

  3. import logging
    4. 

  4. import time
    5. 

  5. from collections import Counter
    6. 

  6. 

  7. import numpy as np
    8. 

  8. import torch
    9. 

  9. import torch._utils
    10. 

  10. import torch.nn as nn
    11. 

  11. import torch.nn.functional as F
    12. 

  12. 

  13. import model
    14. 

  14. import utils
    15. 

  15. from communication import ONLINE, TARGET, BOTH, LOCAL, GLOBAL, DAPU, NONE, EMA, DYNAMIC_DAPU, DYNAMIC_EMA_ONLINE, SELECTIVE_EMA
    16. 

  16. from easyfl.client.base import BaseClient
    17. 

  17. from easyfl.distributed.distributed import CPU
    18. 

  18. 

  19. from client import FedSSLClient
    20. 

  20. 

  21. logger = logging.getLogger(__name__)
    22. 

  22. 

  23. L2 = "l2"
    24. 

  24. 

  25. def model_dot_product(w1, w2, requires_grad=True):
    26. 

  26.     """ Return the sum of squared difference between two models. """
    27. 

  27.     dot_product = 0.0
    28. 

  28.     for p1, p2 in zip(w1.parameters(), w2.parameters()):
    29. 

  29.         if requires_grad:
    30. 

  30.             dot_product += torch.sum(p1 * p2)
    31. 

  31.         else:
    32. 

  32.             dot_product += torch.sum(p1.data * p2.data)
    33. 

  33.     return dot_product
    34. 

  34. 

  35. class FedSSLWithPgFedClient(FedSSLClient):
    36. 

  36.     def __init__(self, cid, conf, train_data, test_data, device, sleep_time=0):
    37. 

  37.         super(FedSSLWithPgFedClient, self).__init__(cid, conf, train_data, test_data, device, sleep_time)
    38. 

  38.         self._local_model = None
    39. 

  39.         self.DAPU_predictor = LOCAL
    40. 

  40.         self.encoder_distance = 1
    41. 

  41.         self.encoder_distances = []
    42. 

  42.         self.previous_trained_round = -1
    43. 

  43.         self.weight_scaler = None
    44. 

  44. 

  45.         self.latest_grad = None
    46. 

  46.         self.lambdaa = 1.0 # PGFed learning rate for a_i, Regularization weight for pFedMe
    47. 

  47.         self.prev_loss_minuses = {}
    48. 

  48.         self.prev_mean_grad = None
    49. 

  49.         self.prev_convex_comb_grad = None
    50. 

  50.         self.a_i = None
    51. 

  51. 

  52.     def train(self, conf, device=CPU):
    53. 

  53.         start_time = time.time()
    54. 

  54.         loss_fn, optimizer = self.pretrain_setup(conf, device)
    55. 

  55.         if conf.model in [model.MoCo, model.MoCoV2]:
    56. 

  56.             self.model.reset_key_encoder()
    57. 

  57.         self.train_loss = []
    58. 

  58.         self.model.to(device)
    59. 

  59.         old_model = copy.deepcopy(nn.Sequential(*list(self.model.children())[:-1])).cpu()
    60. 

  60.         for i in range(conf.local_epoch):
    61. 

  61.             batch_loss = []
    62. 

  62.             for (batched_x1, batched_x2), _ in self.train_loader:
    63. 

  63.                 x1, x2 = batched_x1.to(device), batched_x2.to(device)
    64. 

  64.                 optimizer.zero_grad()
    65. 

  65. 

  66.                 if conf.model in [model.MoCo, model.MoCoV2]:
    67. 

  67.                     loss = self.model(x1, x2, device)
    68. 

  68.                 elif conf.model == model.SimCLR:
    69. 

  69.                     images = torch.cat((x1, x2), dim=0)
    70. 

  70.                     features = self.model(images)
    71. 

  71.                     logits, labels = self.info_nce_loss(features)
    72. 

  72.                     loss = loss_fn(logits, labels)
    73. 

  73.                 else:
    74. 

  74.                     loss = self.model(x1, x2)
    75. 

  75. 

  76.                 loss.backward()
    77. 

  77.                 if self.prev_convex_comb_grad is not None:
    78. 

  78.                     for p_m, p_prev_conv in zip(self.model.parameters(), self.prev_convex_comb_grad.parameters()):
    79. 

  79.                         p_m.grad.data += p_prev_conv.data
    80. 

  80.                     dot_prod = model_dot_product(self.model, self.prev_mean_grad, requires_grad=False)
    81. 

  81.                     self.update_a_i(dot_prod)
    82. 

  82.                 optimizer.step()
    83. 

  83.                 batch_loss.append(loss.item())
    84. 

  84. 

  85.                 if conf.model in [model.BYOL, model.BYOLNoSG, model.BYOLNoPredictor] and conf.momentum_update:
    86. 

  86.                     self.model.update_moving_average()
    87. 

  87. 

  88.             current_epoch_loss = sum(batch_loss) / len(batch_loss)
    89. 

  89.             self.train_loss.append(float(current_epoch_loss))
    90. 

  90. 

  91.         self.loss_minus = 0.0
    92. 

  92.         test_num = 0
    93. 

  93.         optimizer.zero_grad()
    94. 

  94.         for (batched_x1, batched_x2), _ in self.train_loader:
    95. 

  95.             x1, x2 = batched_x1.to(self.device), batched_x2.to(self.device)
    96. 

  96.             test_num += x1.size(0)
    97. 

  97. 

  98.             if conf.model in [model.MoCo, model.MoCoV2]:
    99. 

  99.                 loss = self.model(x1, x2, device)
    100. 

  100.             elif conf.model == model.SimCLR:
    101. 

  101.                 images = torch.cat((x1, x2), dim=0)
    102. 

  102.                 features = self.model(images)
    103. 

  103.                 logits, labels = self.info_nce_loss(features)
    104. 

  104.                 loss = loss_fn(logits, labels)
    105. 

  105.             else:
    106. 

  106.                 loss = self.model(x1, x2)
    107. 

  107. 

  108.             self.loss_minus += loss.item() * x1.size(0)
    109. 

  109. 

  110.         self.loss_minus /= test_num
    111. 

  111.         if not self.latest_grad:
    112. 

  112.             self.latest_grad = copy.deepcopy(self.model)
    113. 

  113.         
    114. 

  114.         # delete later: for test 
    115. 

  115.         # all_grads_none = True
    116. 

  116.         # for p_l, p in zip(self.latest_grad.parameters(), self.model.parameters()):
    117. 

  117.         #     if p.grad is not None:
    118. 

  118.         #         p_l.data = p.grad.data.clone() / len(self.train_loader)
    119. 

  119.         #         all_grads_none = False
    120. 

  120.         #     else:
    121. 

  121.         #         p_l.data = torch.zeros_like(p_l.data)
    122. 

  122.         # if all_grads_none:
    123. 

  123.         #     print("All None")
    124. 

  124.         
    125. 

  125.         self.loss_minus -= model_dot_product(self.latest_grad, self.model, requires_grad=False)
    126. 

  126. 

  127.         self.train_time = time.time() - start_time
    128. 

  128. 

  129.         # store trained model locally
    130. 

  130.         # self._local_model = copy.deepcopy(self.model).cpu()
    131. 

  131.         # self.previous_trained_round = conf.round_id
    132. 

  132.         # if conf.update_predictor in [DAPU, DYNAMIC_DAPU, SELECTIVE_EMA] or conf.update_encoder in [DYNAMIC_EMA_ONLINE, SELECTIVE_EMA]:
    133. 

  133.         #     new_model = copy.deepcopy(nn.Sequential(*list(self.model.children())[:-1])).cpu()
    134. 

  134.         #     self.encoder_distance = self._calculate_divergence(old_model, new_model)
    135. 

  135.         #     self.encoder_distances.append(self.encoder_distance.item())
    136. 

  136.         #     self.DAPU_predictor = self._DAPU_predictor_usage(self.encoder_distance)
    137. 

  137.         #     if self.conf.auto_scaler == 'y' and self.conf.random_selection:
    138. 

  138.         #         self._calculate_weight_scaler()
    139. 

  139.         #     if (conf.round_id + 1) % 100 == 0:
    140. 

  140.         #         logger.info(f"Client {self.cid}, encoder distances: {self.encoder_distances}")
    141. 

  141. 

  142.     def update_a_i(self, dot_prod):
    143. 

  143.         for clt_j, mu_loss_minus in self.prev_loss_minuses.items():
    144. 

  144.             self.a_i[clt_j] -= self.lambdaa * (mu_loss_minus + dot_prod)
    145. 

  145.             self.a_i[clt_j] = max(self.a_i[clt_j], 0.0)
    146. 

  146. 

  147.     def set_prev_mean_grad(self, mean_grad):
    148. 

  148.         if self.prev_mean_grad is None:
    149. 

  149.             print("Initing prev_mean_grad")
    150. 

  150.             self.prev_mean_grad = copy.deepcopy(mean_grad)
    151. 

  151.         else:
    152. 

  152.             print("Setting prev_mean_grad")
    153. 

  153.             self.set_model(self.prev_mean_grad, mean_grad)
    154. 

  154. 

  155.     def set_prev_convex_comb_grad(self, convex_comb_grad, momentum=0.0):
    156. 

  156.         if self.prev_convex_comb_grad is None:
    157. 

  157.             print("Initing prev_convex_comb_grad")
    158. 

  158.             self.prev_convex_comb_grad = copy.deepcopy(convex_comb_grad)
    159. 

  159.         else:
    160. 

  160.             print("Setting prev_convex_comb_grad")
    161. 

  161.             self.set_model(self.prev_convex_comb_grad, convex_comb_grad, momentum=momentum)
    162. 

  162. 

  163.     def set_model(self, old_m, new_m, momentum=0.0):
    164. 

  164.         for p_old, p_new in zip(old_m.parameters(), new_m.parameters()):
    165. 

  165.             p_old.data = (1 - momentum) * p_new.data.clone() + momentum * p_old.data.clone()
    166.