# Copyright 2024 The HuggingFace Team. All rights reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import math import warnings from functools import wraps from typing import TYPE_CHECKING, Optional, TypedDict from .utils import is_torch_available, logging logger = logging.get_logger(__name__) if is_torch_available(): import torch if TYPE_CHECKING: from .configuration_utils import PreTrainedConfig def dynamic_rope_update(rope_forward): """ Decorator function to update the RoPE parameters in the forward pass, if the model is using a dynamic RoPE (i.e. a RoPE implementation that may recompute its frequencies in the forward pass). Args: rope_forward (Callable): The forward pass of the RoPE implementation. Returns: The decorated forward pass. """ def longrope_frequency_update(self, position_ids, device, layer_type=None): """Longrope uses long factor if sequence is larger than original pretraining length, short otherwise.""" seq_len = torch.max(position_ids) + 1 if layer_type is None: rope_type = self.rope_type original_inv_freq = self.original_inv_freq prefix = "" original_max_position_embeddings = self.config.rope_parameters["original_max_position_embeddings"] else: rope_type = self.rope_type[layer_type] original_inv_freq = getattr(self, f"{layer_type}_original_inv_freq") prefix = f"{layer_type}_" original_max_position_embeddings = self.config.rope_parameters[layer_type][ "original_max_position_embeddings" ] if seq_len > original_max_position_embeddings: if not hasattr(self, f"{layer_type}_long_inv_freq"): rope_init_fn = ROPE_INIT_FUNCTIONS[rope_type] long_inv_freq, _ = rope_init_fn( self.config, device, seq_len=original_max_position_embeddings + 1, layer_type=layer_type, ) self.register_buffer(f"{prefix}inv_freq", long_inv_freq, persistent=False) setattr(self, f"{prefix}long_inv_freq", long_inv_freq) else: # This .to() is needed if the model has been moved to a device after being initialized (because # the buffer is automatically moved, but not the original copy) original_inv_freq = original_inv_freq.to(device) self.register_buffer(f"{prefix}inv_freq", original_inv_freq, persistent=False) setattr(self, f"{prefix}original_inv_freq", original_inv_freq) def dynamic_frequency_update(self, position_ids, device, layer_type=None): """ dynamic RoPE layers should recompute `inv_freq` in the following situations: 1 - growing beyond the cached sequence length (allow scaling) 2 - the current sequence length is in the original scale (avoid losing precision with small sequences) """ seq_len = torch.max(position_ids) + 1 if layer_type is None: rope_type = self.rope_type max_seq_len_cached = self.max_seq_len_cached original_inv_freq = self.original_inv_freq prefix = "" else: rope_type = self.rope_type[layer_type] max_seq_len_cached = getattr(self, f"{layer_type}_max_seq_len_cached", self.max_seq_len_cached) original_inv_freq = getattr(self, f"{layer_type}_original_inv_freq") prefix = f"{layer_type}_" if seq_len > max_seq_len_cached: # growth rope_init_fn = ROPE_INIT_FUNCTIONS[rope_type] inv_freq, self.attention_scaling = rope_init_fn( self.config, device, seq_len=seq_len, layer_type=layer_type, ) # TODO joao: may break with compilation self.register_buffer(f"{prefix}inv_freq", inv_freq, persistent=False) setattr(self, f"{layer_type}_max_seq_len_cached", seq_len) if seq_len < self.original_max_seq_len and max_seq_len_cached > self.original_max_seq_len: # reset # This .to() is needed if the model has been moved to a device after being initialized (because # the buffer is automatically moved, but not the original copy) original_inv_freq = original_inv_freq.to(device) self.register_buffer(f"{prefix}inv_freq", original_inv_freq, persistent=False) setattr(self, f"{prefix}original_inv_freq", original_inv_freq) setattr(self, f"{layer_type}_max_seq_len_cached", self.original_max_seq_len) @wraps(rope_forward) def wrapper(self, x, position_ids, layer_type=None): rope_type = self.rope_type if layer_type is None else self.rope_type[layer_type] kwargs = {"layer_type": layer_type} if layer_type is not None else {} if "dynamic" in rope_type: dynamic_frequency_update(self, position_ids, device=x.device, **kwargs) elif rope_type == "longrope": longrope_frequency_update(self, position_ids, device=x.device, **kwargs) return rope_forward(self, x, position_ids, **kwargs) return wrapper def _compute_linear_scaling_rope_parameters( config: Optional["PreTrainedConfig"] = None, device: Optional["torch.device"] = None, seq_len: int | None = None, layer_type: str | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies with linear scaling. Credits to the Reddit user /u/kaiokendev Args: config ([`~transformers."PreTrainedConfig"`]): The model configuration. This function assumes that the config will provide at least the following properties: * rope_theta (`float`): The base wavelength from which the inverse frequencies will be derived. * hidden_size (`int`): The numerator when deriving a head_dim, if not provided directly. * num_attention_heads (`int`): The denominator when deriving a head_dim, if not provided directly. Additionally, this function will make use of the following properties if they are found in the config: * head_dim (`int`, *optional*): The size of the key-value heads in the model. If None, this value will be derived as hidden_size // num_attention_heads. * partial_rotary_factor (`float`, *optional*): If less than 1.0, inverse frequencies will be returned for the first fraction of the head_dim. Defaults to 1.0. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length. Unused for this type of RoPE. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin (unused in this type of RoPE). """ # For backward compatibility standardize the `rope_parameters_dict` if it uses old format config.standardize_rope_params() rope_parameters_dict = config.rope_parameters[layer_type] if layer_type is not None else config.rope_parameters factor = rope_parameters_dict["factor"] # Gets the default RoPE parameters base = rope_parameters_dict["rope_theta"] partial_rotary_factor = rope_parameters_dict.get("partial_rotary_factor", 1.0) head_dim = getattr(config, "head_dim", None) or config.hidden_size // config.num_attention_heads dim = int(head_dim * partial_rotary_factor) attention_factor = 1.0 # Unused in this type of RoPE # Compute the inverse frequencies inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.int64).to(device=device, dtype=torch.float) / dim)) # Then applies linear scaling to the frequencies. # NOTE: originally, scaling was applied to the position_ids. However, we get `embs = inv_freq @ position_ids`, so # applying scaling to the inverse frequencies is equivalent. inv_freq /= factor return inv_freq, attention_factor def _compute_dynamic_ntk_parameters( config: Optional["PreTrainedConfig"] = None, device: Optional["torch.device"] = None, seq_len: int | None = None, layer_type: str | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies with NTK scaling. Credits to the Reddit users /u/bloc97 and /u/emozilla Args: config ([`~transformers."PreTrainedConfig"`]): The model configuration. This function assumes that the config will provide at least the following properties: * rope_theta (`float`): The base wavelength from which the inverse frequencies will be derived. * hidden_size (`int`): The numerator when deriving a head_dim, if not provided directly. * num_attention_heads (`int`): The denominator when deriving a head_dim, if not provided directly. * max_position_embeddings (`int`): The default sequence length used to update the dynamic RoPE at inference time * rope_parameters (`dict[str, float]`): The standard RoPE scaling parameters, from which `factor` will be accessed. The value of `factor` is used to determine the new base frequency, along with the current sequence length (seq_len), the maximum positional embeddings (max_position_embeddings), and the computed dimensionality (dim) of the rotary embeddings. If seq_len <= max_position_embeddings, this factor has no effect. If seq_len <= max_position_embeddings, this factor effectively stretches the context window using an exponent derived from `dim`. Additionally, this function will make use of the following properties if they are found in the config: * head_dim (`int`, *optional*): The size of the key-value heads in the model. If None, this value will be derived as hidden_size // num_attention_heads. * partial_rotary_factor (`float`, *optional*): If less than 1.0, inverse frequencies will be returned for the first fraction of the head_dim. Defaults to 1.0. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length, used to update the dynamic RoPE at inference time. If `None` or shorter than max_position_embeddings, this value will be overridden by max_position_embeddings. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin (unused in this type of RoPE). """ # For backward compatibility standardize the `rope_parameters_dict` if it uses old format config.standardize_rope_params() rope_parameters_dict = config.rope_parameters[layer_type] if layer_type is not None else config.rope_parameters base = rope_parameters_dict["rope_theta"] partial_rotary_factor = rope_parameters_dict.get("partial_rotary_factor", 1.0) head_dim = getattr(config, "head_dim", config.hidden_size // config.num_attention_heads) dim = int(head_dim * partial_rotary_factor) factor = rope_parameters_dict["factor"] attention_factor = 1.0 # Unused in this type of RoPE # seq_len: default to max_position_embeddings, e.g. at init time if seq_len is None: seq_len = config.max_position_embeddings elif isinstance(seq_len, torch.Tensor): seq_len = torch.maximum( seq_len, torch.tensor(config.max_position_embeddings, dtype=seq_len.dtype, device=seq_len.device), ) else: seq_len = max(seq_len, config.max_position_embeddings) # Compute the inverse frequencies base = base * ((factor * seq_len / config.max_position_embeddings) - (factor - 1)) ** (dim / (dim - 2)) inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.int64).to(device=device, dtype=torch.float) / dim)) return inv_freq, attention_factor def _compute_yarn_parameters( config: "PreTrainedConfig", device: Optional["torch.device"] = None, seq_len: int | None = None, layer_type: str | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies with NTK scaling. Please refer to the [original paper](https://huggingface.co/papers/2309.00071) Args: config ([`~transformers."PreTrainedConfig"`]): The model configuration. This function assumes that the config will provide at least the following properties: * rope_theta (`float`): The base wavelength from which the inverse frequencies will be derived. * hidden_size (`int`): The numerator when deriving a head_dim, if not provided directly. * num_attention_heads (`int`): The denominator when deriving a head_dim, if not provided directly. * max_position_embeddings (`int`): The maximum length of the positional embeddings. * rope_parameters (`dict[str, float | int]`): The standard RoPE scaling parameters, from which the following keys will be accessed: * `attention_factor` (`float`, *optional*): The scaling factor to be applied to the computed cos/sin. If None, the value is inferred from `factor`, `mscale`, and `mscale_all_dim` as avaialble. * `beta_fast` (`float`, *optional*, defaults to 32): Parameter to set the boundary for extrapolation (only) in the linear ramp function. * `beta_slow` (`float`, *optional*, defaults to 1): Parameter to set the boundary for interpolation (only) in the linear ramp function. * `factor` (`float`, *optional*): The scaling factor applied when interpolating the position IDs to extend the possible context length. Additionally, if `attention_factor` is None, the log of this value is used to compute a value for `attention_factor`, possibly in conjunciton with `mscale` and `mscale_all_dim`, if provided. * `mscale` (`float`, *optional*): If `attention_factor` is None and both `mscale` and `mscale_all_dim` are provided, `mscale` acts scalar augmenting `log(factor)` when computing the numerator for the inferred value of `attention_factor`. If not provided, `attention_factor` will be calculated based on `factor` only. * `mscale_all_dim` (`float`, *optional*): If `attention_factor` is None and both `mscale` and `mscale_all_dim` are provided, `mscale_all_dim` acts scalar augmenting `log(factor)` when computing the denominator for the inferred value of `attention_factor`. If not provided, `attention_factor` will be calculated based on `factor` only. * `original_max_position_embeddings` (`int`): The original max position embeddings used during pretraining. * `truncate` (`bool`, *optional*): Whether to truncate the correction range. Additionally, this function will make use of the following properties if they are found in the config: * head_dim (`int`, *optional*): The size of the key-value heads in the model. If None, this value will be derived as hidden_size // num_attention_heads. * partial_rotary_factor (`float`, *optional*, defaults to 1.0): If less than 1.0, inverse frequencies will be returned for the first fraction of the head_dim. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length. Unused for this type of RoPE. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin. """ # For backward compatibility standardize the `rope_parameters_dict` if it uses old format config.standardize_rope_params() rope_parameters_dict = config.rope_parameters[layer_type] if layer_type is not None else config.rope_parameters base = rope_parameters_dict["rope_theta"] partial_rotary_factor = rope_parameters_dict.get("partial_rotary_factor", 1.0) head_dim = getattr(config, "head_dim", config.hidden_size // config.num_attention_heads) dim = int(head_dim * partial_rotary_factor) factor = rope_parameters_dict["factor"] attention_factor = rope_parameters_dict.get("attention_factor") mscale = rope_parameters_dict.get("mscale") mscale_all_dim = rope_parameters_dict.get("mscale_all_dim") original_max_position_embeddings = rope_parameters_dict["original_max_position_embeddings"] # NOTE: DeekSeek-V3 (and potentially other models) have `original_max_position_embeddings` field # containing the pretrained value. They use the ratio between `max_position_embeddings` and this value # to compute the default attention scaling factor, instead of using `factor`. if factor is None: factor = config.max_position_embeddings / original_max_position_embeddings def get_mscale(scale, mscale=1): if scale <= 1: return 1.0 return 0.1 * mscale * math.log(scale) + 1.0 # Sets the attention factor as suggested in the paper if attention_factor is None: if mscale and mscale_all_dim: attention_factor = float(get_mscale(factor, mscale) / get_mscale(factor, mscale_all_dim)) else: attention_factor = get_mscale(factor) # Optional config options # beta_fast/beta_slow: as suggested in the paper, default to 32/1 (correspondingly) beta_fast = rope_parameters_dict.get("beta_fast") or 32 beta_slow = rope_parameters_dict.get("beta_slow") or 1 # Compute the inverse frequencies def find_correction_dim(num_rotations, dim, base, max_position_embeddings): """Inverse dimension formula to find the dimension based on the number of rotations""" return (dim * math.log(max_position_embeddings / (num_rotations * 2 * math.pi))) / (2 * math.log(base)) def find_correction_range(low_rot, high_rot, dim, base, max_position_embeddings, truncate): """Find dimension range bounds based on rotations""" low = find_correction_dim(low_rot, dim, base, max_position_embeddings) high = find_correction_dim(high_rot, dim, base, max_position_embeddings) if truncate: low = math.floor(low) high = math.ceil(high) return max(low, 0), min(high, dim - 1) def linear_ramp_factor(min, max, dim): if min == max: max += 0.001 # Prevent singularity linear_func = (torch.arange(dim, dtype=torch.float32) - min) / (max - min) ramp_func = torch.clamp(linear_func, 0, 1) return ramp_func # Note on variable naming: "interpolation" comes from the original technique, where we interpolate the position IDs # to expand the possible context length. In other words, interpolation = apply scaling factor. pos_freqs = base ** (torch.arange(0, dim, 2).to(device=device, dtype=torch.float) / dim) inv_freq_extrapolation = 1.0 / pos_freqs inv_freq_interpolation = 1.0 / (factor * pos_freqs) truncate = config.rope_parameters.get("truncate", True) low, high = find_correction_range(beta_fast, beta_slow, dim, base, original_max_position_embeddings, truncate) # Get n-dimensional rotational scaling corrected for extrapolation inv_freq_extrapolation_factor = 1 - linear_ramp_factor(low, high, dim // 2).to(device=device, dtype=torch.float) inv_freq = ( inv_freq_interpolation * (1 - inv_freq_extrapolation_factor) + inv_freq_extrapolation * inv_freq_extrapolation_factor ) return inv_freq, attention_factor def _compute_longrope_parameters( config: "PreTrainedConfig", device: Optional["torch.device"] = None, seq_len: int | None = None, layer_type: str | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies with LongRoPE scaling. Please refer to the [original implementation](https://github.com/microsoft/LongRoPE) Args: config ([`~transformers."PreTrainedConfig"`]): The model configuration. This function assumes that the config will provide at least the following properties: * rope_theta (`float`): The base wavelength from which the inverse frequencies will be derived. * hidden_size (`int`): The numerator when deriving a head_dim, if not provided directly. * num_attention_heads (`int`): The denominator when deriving a head_dim, if not provided directly. * max_position_embeddings (`int`): The maximum length of the positional embeddings. * original_max_position_embeddings (`int`, *optional*): The original max position embeddings used during pretraining. If not provided, defaults to `max_position_embeddings`. * rope_parameters (`dict[str, float]`): The standard RoPE scaling parameters, from which the following keys will be accessed: * `attention_factor` (`float`, *optional*): The scaling factor to be applied on the attention computation. If unspecified, it defaults to value recommended by the implementation, inferred from the value of `factor`. * `factor` (`float`, *optional*): The scaling factor to apply to the RoPE embeddings. If both `max_position_embeddings` and `original_max_position_embeddings` are provided, this value will be overridden s the ratio between those values. * `long_factor` (`float`, *optional*): The scale factor applied when computing the inverse frequencies if `seq_len` is provided and greater than `original_max_position_embeddings`. * `short_factor` (`float`, *optional*): The scale factor applied when computing the inverse frequencies if `seq_len` is None or less-than-or-equal-to `original_max_position_embeddings`. Additionally, this function will make use of the following properties if they are found in the config: * head_dim (`int`, *optional*): The size of the key-value heads in the model. If None, this value will be derived as hidden_size // num_attention_heads. * partial_rotary_factor (`float`, *optional*, defaults to 1.0): If less than 1.0, inverse frequencies will be returned for the first fraction of the head_dim. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin. """ # For backward compatibility standardize the `rope_parameters_dict` if it uses old format config.standardize_rope_params() rope_parameters_dict = config.rope_parameters[layer_type] if layer_type is not None else config.rope_parameters base = rope_parameters_dict["rope_theta"] partial_rotary_factor = rope_parameters_dict.get("partial_rotary_factor", 1.0) head_dim = getattr(config, "head_dim", config.hidden_size // config.num_attention_heads) dim = int(head_dim * partial_rotary_factor) long_factor = rope_parameters_dict["long_factor"] short_factor = rope_parameters_dict["short_factor"] factor = rope_parameters_dict.get("factor") attention_factor = rope_parameters_dict.get("attention_factor") original_max_position_embeddings = rope_parameters_dict["original_max_position_embeddings"] # NOTE: Phi3 (and potentially other models) modify `max_position_embeddings` and have a # `original_max_position_embeddings` field containing the pretrained value. They use the ratio between these two # values to compute the default attention scaling factor, instead of using `factor`. if factor is None: factor = config.max_position_embeddings / original_max_position_embeddings # Sets the attention factor as suggested in the paper if attention_factor is None: if factor <= 1.0: attention_factor = 1.0 else: attention_factor = math.sqrt(1 + math.log(factor) / math.log(original_max_position_embeddings)) # Compute the inverse frequencies -- scaled based on the target sequence length if seq_len and seq_len > original_max_position_embeddings: ext_factors = torch.tensor(long_factor, dtype=torch.float32, device=device) else: ext_factors = torch.tensor(short_factor, dtype=torch.float32, device=device) inv_freq_shape = torch.arange(0, dim, 2, dtype=torch.int64, device=device).float() / dim inv_freq = 1.0 / (ext_factors * base**inv_freq_shape) return inv_freq, attention_factor def _compute_llama3_parameters( config: "PreTrainedConfig", device: Optional["torch.device"] = None, seq_len: int | None = None, layer_type: str | None = None, ) -> tuple["torch.Tensor", float]: """ Computes the inverse frequencies for llama 3.1. Args: config ([`~transformers."PreTrainedConfig"`]): The model configuration. This function assumes that the config will provide at least the following properties: * rope_theta (`float`): The base wavelength from which the inverse frequencies will be derived. * hidden_size (`int`): The numerator when deriving a head_dim, if not provided directly. * num_attention_heads (`int`): The denominator when deriving a head_dim, if not provided directly. * rope_parameters (`dict[str, float | int]`): The standard RoPE scaling parameters, from which the following keys will be accessed: * `factor` (`float`, *optional*): The scaling factor applied to the inverse frequencies when 1) the wavelength is greater than `low_freq_wavelen` prior to smoothing, and 2) to all inverse frequencies during smoothing. * `high_freq_factor` (`float`): The scale factor used to compute `high_freq_wavelen` and the value for the denominator of the smoothing factor prior to the `low_freq_factor` shift. * `low_freq_factor` (`float`): The scale factor used to compute `low_freq_wavelen` and the shift applied to the numerator and denominator of the smoothing factor. frequencies if `seq_len` is None or less-than-or-equal-to `original_max_position_embeddings`. * `original_max_position_embeddings` (`int`): The original max position embeddings used during pretraining. If not provided, the function falls back to `max_position_embeddings`. Additionally, this function will make use of the following properties if they are found in the config: * head_dim (`int`, *optional*): The size of the key-value heads in the model. If None, this value will be derived as hidden_size // num_attention_heads. * partial_rotary_factor (`float`, *optional*): If less than 1.0, inverse frequencies will be returned for the first fraction of the head_dim. Defaults to 1.0. device (`torch.device`): The device to use for initialization of the inverse frequencies. seq_len (`int`, *optional*): The current sequence length. Unused for this type of RoPE. Returns: Tuple of (`torch.Tensor`, `float`), containing the inverse frequencies for the RoPE embeddings and the post-processing scaling factor applied to the computed cos/sin. """ # For backward compatibility standardize the `rope_parameters_dict` if it uses old format config.standardize_rope_params() rope_parameters_dict = config.rope_parameters[layer_type] if layer_type is not None else config.rope_parameters # Gets the default RoPE parameters base = rope_parameters_dict["rope_theta"] partial_rotary_factor = rope_parameters_dict.get("partial_rotary_factor", 1.0) head_dim = getattr(config, "head_dim", None) or config.hidden_size // config.num_attention_heads dim = int(head_dim * partial_rotary_factor) attention_factor = 1.0 # Unused in this type of RoPE # Compute the inverse frequencies inv_freq = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.int64).to(device=device, dtype=torch.float) / dim)) factor = rope_parameters_dict["factor"] # `8` in the original implementation low_freq_factor = rope_parameters_dict["low_freq_factor"] # `1` in the original implementation high_freq_factor = rope_parameters_dict["high_freq_factor"] # `4` in the original implementation old_context_len = rope_parameters_dict["original_max_position_embeddings"] # `8192` in the original implementation low_freq_wavelen = old_context_len / low_freq_factor high_freq_wavelen = old_context_len / high_freq_factor wavelen = 2 * math.pi / inv_freq # wavelen < high_freq_wavelen: do nothing # wavelen > low_freq_wavelen: divide by factor inv_freq_llama = torch.where(wavelen > low_freq_wavelen, inv_freq / factor, inv_freq) # otherwise: interpolate between the two, using a smooth factor smooth_factor = (old_context_len / wavelen - low_freq_factor) / (high_freq_factor - low_freq_factor) smoothed_inv_freq = (1 - smooth_factor) * inv_freq_llama / factor + smooth_factor * inv_freq_llama is_medium_freq = ~(wavelen < high_freq_wavelen) * ~(wavelen > low_freq_wavelen) inv_freq_llama = torch.where(is_medium_freq, smoothed_inv_freq, inv_freq_llama) return inv_freq_llama, attention_factor # This maps the "rope_type" string field in rope config to the corresponding function to compute the RoPE parameters # from the model config. You can append new {'rope_type': callable} pairs to this rope_parameters to enable custom RoPE # parameterizations, as long as the callable has the same signature. ROPE_INIT_FUNCTIONS = { "linear": _compute_linear_scaling_rope_parameters, "dynamic": _compute_dynamic_ntk_parameters, "yarn": _compute_yarn_parameters, "longrope": _compute_longrope_parameters, "llama3": _compute_llama3_parameters, } class RopeParameters(TypedDict, total=False): """ Args: rope_theta (`float`): The base period of the RoPE embeddings. rope_type (`str`, *optional*, defaults to "default"): The sub-variant of RoPE to use. Can be one of ['default', 'linear', 'dynamic', 'yarn', 'longrope', 'llama3'], with 'default' being the original RoPE implementation. partial_rotary_factor (`float`, *optional*): The percentage of the query and key head embedding on which RoPE will be applied. factor (`float`, *optional*): Used with all rope types except 'default'. The scaling factor to apply to the RoPE embeddings. In most scaling types, a `factor` of x will enable the model to handle sequences of length x * original maximum pre-trained length. original_max_position_embeddings (`int`, *optional*): Used with 'yarn', 'longrope' and 'llama3'. The original max position embeddings used during pretraining. attention_factor (`float`, *optional*): Used with 'yarn' and 'longrope'. The scaling factor to be applied on the attention computation. If unspecified, it defaults to value recommended by the implementation, using the `factor` field to infer the suggested value. beta_fast (`float`, *optional*): Only used with 'yarn'. Parameter to set the boundary for extrapolation (only) in the linear ramp function. If unspecified, it defaults to 32. beta_slow (`float`, *optional*): Only used with 'yarn'. Parameter to set the boundary for interpolation (only) in the linear ramp function. If unspecified, it defaults to 1. short_factor (`list[float]`, *optional*): Only used with 'longrope'. The scaling factor to be applied to short contexts (< `original_max_position_embeddings`). Must be a list of numbers with the same length as the hidden size divided by the number of attention heads divided by 2 long_factor (`list[float]`, *optional*): Only used with 'longrope'. The scaling factor to be applied to long contexts (< `original_max_position_embeddings`). Must be a list of numbers with the same length as the hidden size divided by the number of attention heads divided by 2 low_freq_factor (`float`, *optional*): Only used with 'llama3'. Scaling factor applied to low frequency components of the RoPE high_freq_factor (`float`, *optional*): Only used with 'llama3'. Scaling factor applied to high frequency components of the RoPE """ rope_theta: float rope_type: str | None partial_rotary_factor: float | None factor: float | None original_max_position_embeddings: int | None attention_factor: float | None beta_fast: float | None beta_slow: float | None short_factor: list[float] | None long_factor: list[float] | None low_freq_factor: float | None high_freq_factor: float | None class RotaryEmbeddingConfigMixin: """ A Mixin containing the functionality to standardize and validate RoPE parameters. """ default_theta = 10_000.0 def convert_rope_params_to_dict(self, ignore_keys_at_rope_validation: set | None = None, **kwargs): rope_scaling = kwargs.pop("rope_scaling", None) self.rope_parameters = rope_scaling or self.rope_parameters self.rope_parameters = self.rope_parameters if self.rope_parameters is not None else {} # Standardize and validate the correctness of rotary position embeddings parameters self.rope_parameters.setdefault("rope_theta", kwargs.pop("rope_theta", self.default_theta)) if "partial_rotary_factor" in kwargs: self.rope_parameters.setdefault("partial_rotary_factor", kwargs["partial_rotary_factor"]) ignore_keys_at_rope_validation = {"partial_rotary_factor"} self.standardize_rope_params() self.validate_rope(ignore_keys=ignore_keys_at_rope_validation) return kwargs def standardize_rope_params(self): """ Helper to standardize the config's rope params field by ensuring the params are defined for each later type. For old model the fn will duplicate a single rope param in each layer type (backward compatibility) """ # Move `rope_theta` and `partial_rotary_factor` to the `rope_parameters`, if not there yet rope_theta = getattr(self, "rope_theta", None) partial_rotary_factor = getattr(self, "partial_rotary_factor", None) rope_parameters = getattr(self, "rope_parameters", None) or {} layer_types = getattr(self, "layer_types", None) # Case 0: no RoPE params defined if not (rope_parameters or rope_theta): # partial_rotary_factor without rope_theta is invalid, so we don't check for it here logger.warning("`standardize_rope_params` was called but no RoPE parameters were found.") return # Case 1: RoPE param keys do not intersect with possible `layer_types` -> one global dict elif layer_types is None or rope_parameters == {} or not set(rope_parameters.keys()).issubset(layer_types): rope_parameters.setdefault("rope_type", rope_parameters.get("type", "default")) rope_parameters.setdefault("rope_theta", rope_theta) if partial_rotary_factor is not None: rope_parameters["partial_rotary_factor"] = partial_rotary_factor # Move pretraining-time maximum length to rope parameter dict for RoPE types with scaling if rope_parameters["rope_type"] in ["llama3", "yarn", "longrope"]: if hasattr(self, "original_max_position_embeddings"): # NOTE: Phi3 (and potentially other models) save `original_max_position_embeddings` field # containing the pretrained value outside rope parameters. This is an exception case where we # give priority to `self.original_max_position_embeddings self.rope_parameters["original_max_position_embeddings"] = self.original_max_position_embeddings else: self.rope_parameters.setdefault("original_max_position_embeddings", self.max_position_embeddings) # Case 2: different RoPE for each layer -> several params as nested dict else: for layer_type in set(layer_types): rope_parameters[layer_type].setdefault("rope_type", rope_parameters[layer_type].get("type", "default")) rope_parameters[layer_type].setdefault("rope_theta", rope_theta) if partial_rotary_factor is not None: rope_parameters[layer_type]["partial_rotary_factor"] = partial_rotary_factor if rope_parameters[layer_type]["rope_type"] in ["llama3", "yarn", "longrope"]: self.rope_parameters[layer_type].setdefault( "original_max_position_embeddings", self.max_position_embeddings ) self.rope_parameters = rope_parameters def validate_rope(self: "PreTrainedConfig", ignore_keys: set | None = None): """ Validate the RoPE config arguments, given a `"PreTrainedConfig"` object """ rope_parameters_dict = self.rope_parameters if rope_parameters_dict is None: return if getattr(self, "layer_types", None) is not None and set(rope_parameters_dict.keys()).issubset( self.layer_types ): pass else: rope_parameters_dict = {"full_attention": rope_parameters_dict} for rope_parameters in rope_parameters_dict.values(): rope_type = rope_parameters.get("rope_type", rope_parameters.get("type", "default")) validation_fn = getattr(self, f"_validate_{rope_type}_rope_parameters", None) rope_parameters["rope_type"] = rope_type if validation_fn is not None: validation_fn(rope_parameters, ignore_keys=ignore_keys) else: logger.warning( f"Missing validation function in 'RotaryEmbeddingConfigMixin' for 'rope_type'='{rope_type}'" ) def _validate_default_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = {"rope_type", "rope_theta"} received_keys = set(rope_parameters.keys()) rope_type = rope_parameters["rope_type"] self._check_received_keys(rope_type, received_keys, required_keys, ignore_keys=ignore_keys) def _validate_linear_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = {"rope_type", "factor", "rope_theta"} received_keys = set(rope_parameters.keys()) rope_type = rope_parameters["rope_type"] self._check_received_keys(rope_type, received_keys, required_keys, ignore_keys=ignore_keys) factor = rope_parameters["factor"] if factor is None or not isinstance(factor, float) or factor < 1.0: logger.warning(f"`rope_parameters`'s factor field must be a float >= 1, got {factor}") def _validate_dynamic_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = {"rope_type", "factor"} received_keys = set(rope_parameters.keys()) rope_type = rope_parameters["rope_type"] self._check_received_keys(rope_type, received_keys, required_keys, ignore_keys=ignore_keys) factor = rope_parameters["factor"] if factor is None or not isinstance(factor, float) or factor < 1.0: logger.warning(f"`rope_parameters`'s factor field must be a float >= 1, got {factor}") def _validate_yarn_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = {"rope_type", "factor", "rope_theta", "original_max_position_embeddings"} optional_keys = { "attention_factor", "beta_fast", "beta_slow", "mscale", "mscale_all_dim", "truncate", } received_keys = set(rope_parameters.keys()) rope_type = rope_parameters["rope_type"] self._check_received_keys(rope_type, received_keys, required_keys, optional_keys, ignore_keys=ignore_keys) factor = rope_parameters["factor"] if factor is None or not isinstance(factor, float) or factor < 1.0: logger.warning(f"`rope_parameters`'s factor field must be a float >= 1, got {factor}") attention_factor = rope_parameters.get("attention_factor") if attention_factor is not None and (not isinstance(attention_factor, float) or attention_factor < 0): logger.warning( f"`rope_parameters`'s attention_factor field must be a float greater than 0, got {attention_factor}" ) beta_fast = rope_parameters.get("beta_fast") if beta_fast is not None and not isinstance(beta_fast, float): logger.warning(f"`rope_parameters`'s beta_fast field must be a float, got {beta_fast}") beta_slow = rope_parameters.get("beta_slow") if beta_slow is not None and not isinstance(beta_slow, float): logger.warning(f"`rope_parameters`'s beta_slow field must be a float, got {beta_slow}") if (beta_fast or 32) < (beta_slow or 1): logger.warning( f"`rope_parameters`'s beta_fast field must be greater than beta_slow, got beta_fast={beta_fast} " f"(defaults to 32 if None) and beta_slow={beta_slow} (defaults to 1 if None)" ) # Double-check: `factor` should be the ratio between the pre-yarn and post-yarn context lengths. # NOTE: we might get `implicit_factor == 1` if config's `original_max_position_embeddings` was # inferred from `max_position_embeddings` during standardization original_max_position_embeddings = self.rope_parameters["original_max_position_embeddings"] implicit_factor = self.max_position_embeddings / original_max_position_embeddings if implicit_factor != factor and implicit_factor != 1: logger.warning_once( f"The explicitly set RoPE scaling factor (config.rope_parameters['factor'] = {factor}) does not match " "the ratio implicitly set by other parameters (implicit factor = " "post-yarn context length / pre-yarn context length = " "config.max_position_embeddings / config.rope_parameters['original_max_position_embeddings'] = " f"{implicit_factor}). Using the explicit factor ({factor}) in YaRN. This may cause unexpected " "behaviour in model usage, please correct the 'original_max_position_embeddings' fields in the model config." ) def _validate_longrope_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = {"rope_type", "short_factor", "long_factor", "rope_theta", "original_max_position_embeddings"} optional_keys = {"attention_factor", "factor"} received_keys = set(rope_parameters.keys()) rope_type = rope_parameters["rope_type"] self._check_received_keys(rope_type, received_keys, required_keys, optional_keys, ignore_keys=ignore_keys) partial_rotary_factor = rope_parameters.get("partial_rotary_factor", 1.0) head_dim = getattr(self, "head_dim", self.hidden_size // self.num_attention_heads) dim = int(head_dim * partial_rotary_factor) short_factor = rope_parameters.get("short_factor") if not isinstance(short_factor, list) and all(isinstance(x, (int, float)) for x in short_factor): logger.warning(f"`rope_parameters`'s short_factor field must be a list of numbers, got {short_factor}") if len(short_factor) != dim // 2: logger.warning( f"`rope_parameters`'s short_factor field must have length {dim // 2}, got {len(short_factor)}" ) long_factor = rope_parameters.get("long_factor") if not isinstance(long_factor, list) and all(isinstance(x, (int, float)) for x in long_factor): logger.warning(f"`rope_parameters`'s long_factor field must be a list of numbers, got {long_factor}") if len(long_factor) != dim // 2: logger.warning( f"`rope_parameters`'s long_factor field must have length {dim // 2}, got {len(long_factor)}" ) factor = rope_parameters.get("factor") original_max_position_embeddings = rope_parameters["original_max_position_embeddings"] # Handle Phi3 divergence: we prefer the use of `attention_factor` and/or `factor` over # `original_max_position_embeddings` to compute internal variables. The latter is undesirable if factor is None and original_max_position_embeddings is not None: logger.warning_once( "This model config has set a `rope_parameters['original_max_position_embeddings']` field, to be used together with " "`max_position_embeddings` to determine a scaling factor. Please set the `factor` field of `rope_parameters`" "with this ratio instead -- we recommend the use of this field over `original_max_position_embeddings`, " "as it is compatible with most model architectures." ) elif factor is None and original_max_position_embeddings is None: logger.warning("Missing required keys in `rope_parameters`: 'factor'") elif not isinstance(factor, float) or factor < 1.0: logger.warning(f"`rope_parameters`'s factor field must be a float >= 1, got {factor}") attention_factor = rope_parameters.get("attention_factor") if attention_factor is not None and (not isinstance(attention_factor, float) or attention_factor < 0.0): logger.warning( f"`rope_parameters`'s attention_factor field must be a float greater than 0, got {attention_factor}" ) def _validate_llama3_rope_parameters(self, rope_parameters: dict, ignore_keys: set | None = None): required_keys = { "rope_type", "factor", "original_max_position_embeddings", "low_freq_factor", "high_freq_factor", "rope_theta", } rope_type = rope_parameters["rope_type"] received_keys = set(rope_parameters.keys()) self._check_received_keys(rope_type, received_keys, required_keys, ignore_keys=ignore_keys) factor = rope_parameters["factor"] if factor is None or not isinstance(factor, float) or factor < 1.0: logger.warning(f"`rope_parameters`'s factor field must be a float >= 1, got {factor}") low_freq_factor = rope_parameters["low_freq_factor"] high_freq_factor = rope_parameters["high_freq_factor"] if low_freq_factor is None or not isinstance(low_freq_factor, float): logger.warning(f"`rope_parameters`'s low_freq_factor field must be a float, got {low_freq_factor}") if high_freq_factor is None or not isinstance(high_freq_factor, float): logger.warning(f"`rope_parameters`'s high_freq_factor field must be a float, got {high_freq_factor}") if high_freq_factor <= low_freq_factor: logger.warning( "`rope_parameters`'s high_freq_factor field must be greater than low_freq_factor, got high_freq_factor=" f"{high_freq_factor} and low_freq_factor={low_freq_factor}" ) original_max_position_embeddings = rope_parameters["original_max_position_embeddings"] if original_max_position_embeddings is None or not isinstance(original_max_position_embeddings, int): logger.warning( "`rope_parameters`'s original_max_position_embeddings field must be an integer, got " f"{original_max_position_embeddings}" ) if original_max_position_embeddings >= self.max_position_embeddings: logger.warning( "`rope_parameters`'s original_max_position_embeddings field must be less than max_position_embeddings, got " f"{original_max_position_embeddings} and max_position_embeddings={self.max_position_embeddings}" ) @staticmethod def _check_received_keys( rope_type: str, received_keys: set, required_keys: set, optional_keys: set | None = None, ignore_keys: set | None = None, ): """Compare the received keys in `config.rope_parameters` against the expected and optional keys""" # BC: "rope_type" was originally "type" -- let's check for "rope_type" when "type" is present if "type" in received_keys: received_keys -= {"type"} required_keys.add("rope_type") optional_keys = optional_keys or set() if "partial_rotary_factor" not in optional_keys: optional_keys.add("partial_rotary_factor") # Some models need to store model-specific keys, and we don't want to throw warning at them if ignore_keys is not None: received_keys -= ignore_keys missing_keys = required_keys - received_keys if missing_keys: raise KeyError(f"Missing required keys in `rope_parameters` for 'rope_type'='{rope_type}': {missing_keys}") unused_keys = received_keys - required_keys - optional_keys if unused_keys: logger.warning(f"Unrecognized keys in `rope_parameters` for 'rope_type'='{rope_type}': {unused_keys}") def rope_config_validation(config: RotaryEmbeddingConfigMixin, ignore_keys: set | None = None): """ This is a deprecated function. It has been kept for backward compatibility with custom code models. """ warnings.warn( "`rope_config_validation` is deprecated and has been removed. " "Its functionality has been moved to RotaryEmbeddingConfigMixin.validate_rope method. " "PreTrainedConfig inherits this class, so please call self.validate_rope() instead. " "Also, make sure to use the new rope_parameters syntax. " "You can call self.standardize_rope_params() in the meantime.", FutureWarning, ) config.standardize_rope_params() config.validate_rope(ignore_keys=ignore_keys)