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import torch |
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from torch import nn |
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from torchdiffeq import odeint |
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import wandb |
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import math |
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class ODELinear(nn.Module): |
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def __init__( |
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self, |
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dim: int, |
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factor, |
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act, |
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**kwargs |
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): |
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super().__init__() |
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self.ode_up_proj = nn.Parameter(torch.empty(dim//2, factor*dim)) |
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self.ode_down_proj = nn.Parameter(torch.empty(factor*dim, dim//2)) |
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self.dim = dim |
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if act == "tanh": |
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self.act = torch.nn.Tanh() |
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elif act == "silu": |
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self.act = torch.nn.SiLU() |
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else: |
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raise ValueError(f"act must be one of ['tanh', 'silu'], got {act}") |
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self.reset_parameters() |
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def reset_parameters(self): |
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nn.init.kaiming_uniform_(self.ode_up_proj, a=math.sqrt(5)) |
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nn.init.zeros_(self.ode_down_proj) |
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def get_time_embedding(self, t, base=10000, device='cuda', dtype=torch.float32): |
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if t < 1: |
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alpha = 1 |
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else: |
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alpha = 2*t-1 |
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ntk_base = base * alpha ** (self.dim / (self.dim-2)) |
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ntk_inv_freq = 1.0 / (ntk_base ** (torch.arange(0, self.dim, 2, dtype=torch.float32).to(device) / self.dim)) |
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index = torch.arange(0, self.dim, 2, dtype=torch.float32).to(device) |
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delta_ntk_freq = -2*index/(self.dim-2) * 1 / (base ** (index/self.dim) * (alpha ** (index/(self.dim-2) + 1))) |
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return delta_ntk_freq.to(device, dtype=dtype), ntk_inv_freq.to(device, dtype=dtype) |
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def forward(self, t, x: torch.Tensor): |
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device = x.device |
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delta_time, time = self.get_time_embedding(t.to(device), device=device, dtype=x.dtype) |
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x = x + torch.log(time) |
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time_embed = delta_time / time |
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delta_inv_freq = self.act(x @ self.ode_up_proj.float()) @ self.ode_down_proj.float() |
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delta_inv_freq = delta_inv_freq + time_embed |
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return delta_inv_freq |
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class CLEXScalingRotaryEmbedding(nn.Module): |
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def __init__(self, dim, max_position_embeddings=2048, rope_scaling=None, base=10000, device=None) -> None: |
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super().__init__() |
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self.max_t = rope_scaling["max_factor"] |
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self.dim = dim |
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self.max_position_embeddings = max_position_embeddings |
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self.base = base |
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inv_freq = 1.0 / (self.base ** (torch.arange(0, self.dim, 2).float().to(device) / self.dim)) |
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self.register_buffer("inv_freq", inv_freq) |
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self.proj_func = ODELinear(dim, rope_scaling["param_factor"], rope_scaling["act"]) |
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self.rope_cached = None |
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self.max_t_cached = 0 |
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self.freq_cached = None |
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self.time_dt = rope_scaling["time_dt"] |
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self.ode_args = { |
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"method": "rk4", |
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"options": {"step_size": self.time_dt}, |
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} |
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def sample_random_times(self, max_t, device): |
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return torch.randint(1, max_t, (1,), dtype = torch.long, device=device) |
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def get_random_position_ids(self, n=2048, max=8192): |
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positions = torch.randperm(max)[:n].sort().values |
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return positions |
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def get_continuous_freq(self, time_grid, ex_positions, device): |
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solution = odeint( |
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self.proj_func, torch.log(self.inv_freq.to(device, dtype=torch.float32)), time_grid, **self.ode_args |
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) |
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if time_grid.size(0) == 2: |
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scale_inv_freq = torch.exp(solution[1]) |
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freqs = torch.outer(ex_positions.float().squeeze(), scale_inv_freq) |
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else: |
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scale_inv_freq = torch.exp(solution) |
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return scale_inv_freq |
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embed = torch.cat((freqs,freqs), dim=-1) |
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return embed |
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def forward(self, input_embeds, seq_len, do_train=False): |
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device = self.proj_func.ode_up_proj.device |
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dtype = input_embeds.dtype |
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scale_factor = seq_len // self.max_position_embeddings |
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if do_train: |
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t_val = self.sample_random_times(self.max_t+1, device)[0] |
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if scale_factor < 1.0: |
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scale_factor = 1 |
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sampled_position_ids = self.get_random_position_ids(n=seq_len-2, max=seq_len*t_val-2).float() |
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ex_positions = torch.cat([ |
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torch.tensor([0]), |
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(sampled_position_ids + 1) / scale_factor, |
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torch.tensor([seq_len*t_val//scale_factor-1])] |
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).to(device, dtype=torch.float32) |
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else: |
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t_val = scale_factor if seq_len%self.max_position_embeddings == 0.0 else scale_factor + 1 |
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t_val = t_val if t_val <= self.max_t else self.max_t |
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ex_positions = torch.arange(0, self.max_position_embeddings * t_val, dtype=torch.float32).to(device) |
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if t_val == 1.0: |
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scale_inv_freq = self.inv_freq.to(device) |
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freqs = torch.outer(ex_positions.float().squeeze(), scale_inv_freq) |
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embed = torch.cat((freqs,freqs), dim=-1) |
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cos, sin = embed.cos(), embed.sin() |
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elif do_train: |
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time_grid = torch.tensor([1.0, t_val]).float().to(device) |
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embed = self.get_continuous_freq(time_grid, ex_positions, device) |
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cos, sin = embed.cos(), embed.sin() |
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else: |
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if self.freq_cached is None: |
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time_grid = torch.arange(1.0, self.max_t+1.0, dtype=torch.float32).to(device) |
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self.freq_cached = self.get_continuous_freq(time_grid, ex_positions, device) |
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if t_val != self.max_t_cached: |
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scale_inv_freq = self.freq_cached[int(t_val-1.0)] |
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freqs = torch.outer(ex_positions.float().squeeze(), scale_inv_freq) |
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embed = torch.cat((freqs,freqs), dim=-1) |
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self.rope_cached = torch.cat((embed.cos()[None, :, :], embed.sin()[None, :, :]), dim=0) |
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self.max_t_cached = t_val |
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cos, sin = self.rope_cached |
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return torch.cat( |
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(cos[None, :seq_len].to(dtype=dtype), |
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sin[None, :seq_len].to(dtype=dtype)), |
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dim=0 |
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) |
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