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import json
import math
from typing import Callable, Iterable, TYPE_CHECKING
import numpy as np
import torch
if TYPE_CHECKING:
from torch import Tensor
from .base import ModelBase, TextModel, gguf, logger
@ModelBase.register(
"LLaMAForCausalLM",
"LlamaForCausalLM",
"MistralForCausalLM",
"MixtralForCausalLM",
"VLlama3ForCausalLM",
"LlavaForConditionalGeneration",
"VoxtralForConditionalGeneration",
"LlamaForCausalLMEagle3",
"Eagle3LlamaForCausalLM",
"Eagle3Speculator",
"Eagle3DraftModel",
"IQuestCoderForCausalLM",
"LlamaModel")
class LlamaModel(TextModel):
model_arch = gguf.MODEL_ARCH.LLAMA
undo_permute = True
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
# fix for SmolVLM2, missing `num_attention_heads` in config.json
if self.hf_arch == "VLlama3ForCausalLM":
self.hparams["num_attention_heads"] = self.hparams.get("num_attention_heads", 32)
# Mistral consolidated format has no config.json; origin_hf_arch is HF-only.
if self.is_mistral_format:
self.origin_hf_arch = None
else:
hparams = ModelBase.load_hparams(self.dir_model, is_mistral_format=False)
self.origin_hf_arch = hparams.get('architectures', [None])[0]
# Detect eagle3 draft checkpoint by hparams (some models don't use a distinct HF arch name)
if "draft_vocab_size" in self.hparams and self.hparams["num_hidden_layers"] == 1:
self.is_eagle3 = True
self.model_arch = gguf.MODEL_ARCH.EAGLE3
logger.info("Detected EAGLE-3 draft model, switching to EAGLE3 architecture")
# Re-initialize tensor_map with eagle3 architecture
self.tensor_map = gguf.get_tensor_name_map(self.model_arch, self.block_count)
# Update gguf_writer architecture
self.gguf_writer.arch = gguf.MODEL_ARCH_NAMES[self.model_arch]
self.gguf_writer.add_architecture()
if self.target_model_dir is None:
raise ValueError(
"EAGLE-3 model requires --target-model-dir to be specified. "
"Please provide the path to the target model directory to read config.json"
)
# Read both eagle3 raw config and target model config
with open(self.dir_model / "config.json", 'r', encoding='utf-8') as f:
eagle3_raw_config = json.load(f)
with open(self.target_model_dir / "config.json", 'r', encoding='utf-8') as f:
target_config = json.load(f)
if "text_config" in target_config:
target_config = {**target_config, **target_config["text_config"]}
self.target_vocab_size = target_config["vocab_size"]
# target_layers: derived from target model layer count (low/mid/high)
target_num_layers = target_config["num_hidden_layers"]
target_layers = [2, target_num_layers // 2, target_num_layers - 3]
logger.info(f"EAGLE-3: target_layers = {target_layers} (target model has {target_num_layers} layers)")
self.gguf_writer.add_target_layers(target_layers)
# target_hidden_size: prefer eagle3 config, fallback to target config
if eagle3_raw_config.get("target_hidden_size") is not None:
target_hidden_size = eagle3_raw_config["target_hidden_size"]
src = "EAGLE-3 config"
else:
target_hidden_size = target_config["hidden_size"]
src = "target model config"
logger.info(f"EAGLE-3: target_hidden_size = {target_hidden_size} (from {src})")
self.gguf_writer.add_target_hidden_size(target_hidden_size)
# norm_before_residual (RedHat-style eagle3 specific)
norm_before_residual = eagle3_raw_config.get("norm_before_residual", False)
logger.info(f"EAGLE-3: norm_before_residual = {norm_before_residual}")
self.gguf_writer.add_norm_before_residual(norm_before_residual)
def set_vocab(self):
# eagle3: use tokenizer from target model if provided
original_dir_model = None
if getattr(self, 'is_eagle3', False):
assert self.target_model_dir is not None
logger.info(f"EAGLE-3: Using tokenizer from target model: {self.target_model_dir}")
original_dir_model = self.dir_model
self.dir_model = self.target_model_dir
if self.origin_hf_arch == "GlmasrModel":
return self._set_vocab_glmedge()
if self.is_mistral_format:
return self._set_vocab_mistral()
path_tekken_json = self.dir_model / "tekken.json"
path_tokenizer_json = self.dir_model / "tokenizer.json"
if path_tekken_json.is_file() and not path_tokenizer_json.is_file():
self._set_vocab_mistral()
tokenizer_config_file = self.dir_model / 'tokenizer_config.json'
if tokenizer_config_file.is_file():
with open(tokenizer_config_file, "r", encoding="utf-8") as f:
tokenizer_config_json = json.load(f)
if (add_prefix_space := tokenizer_config_json.get("add_prefix_space")) is not None:
self.gguf_writer.add_add_space_prefix(add_prefix_space)
if tokenizer_config_json.get("tokenizer_class") == "HybridDNATokenizer":
return self._set_vocab_hybriddna()
try:
self._set_vocab_sentencepiece()
except FileNotFoundError:
try:
self._set_vocab_llama_hf()
except (FileNotFoundError, TypeError):
# Llama 3
self._set_vocab_gpt2()
# Apply to CodeLlama only (and ignore for Llama 3 with a vocab size of 128256)
if self.hparams.get("vocab_size", 32000) == 32016:
special_vocab = gguf.SpecialVocab(
self.dir_model, load_merges=False,
special_token_types = ['prefix', 'suffix', 'middle', 'eot']
)
special_vocab._set_special_token("prefix", 32007)
special_vocab._set_special_token("suffix", 32008)
special_vocab._set_special_token("middle", 32009)
special_vocab._set_special_token("eot", 32010)
special_vocab.add_to_gguf(self.gguf_writer)
# Apply to granite small models only
if self.hparams.get("vocab_size", 32000) == 49152:
self.gguf_writer.add_add_bos_token(False)
# eagle3: Restore original dir_model
if original_dir_model is not None:
self.dir_model = original_dir_model
def set_gguf_parameters(self):
super().set_gguf_parameters()
hparams = self.hparams
if not self.is_mistral_format:
self.gguf_writer.add_vocab_size(hparams["vocab_size"])
if (rope_dim := hparams.get("head_dim")) is None:
rope_dim = hparams["hidden_size"] // hparams["num_attention_heads"]
self.gguf_writer.add_rope_dimension_count(rope_dim)
@staticmethod
def permute(weights: Tensor, n_head: int, n_head_kv: int | None):
if n_head_kv is not None and n_head != n_head_kv:
n_head = n_head_kv
return (weights.reshape(n_head, 2, weights.shape[0] // n_head // 2, *weights.shape[1:])
.swapaxes(1, 2)
.reshape(weights.shape))
def _repack_nvfp4(self, name: str, weight: Tensor, scale: Tensor, scale2: Tensor, input_scale: Tensor):
# Mirror the BF16 Q/K RoPE permutation site in modify_tensors; the NVFP4 path bypasses it.
if self.undo_permute:
n_head = self.find_hparam(["n_heads", "num_attention_heads"], optional=True)
n_kv_head = self.find_hparam(["n_kv_heads", "num_key_value_heads"], optional=True)
if n_head is not None:
if name.endswith("q_proj.weight"):
weight = LlamaModel.permute(weight, n_head, n_head)
scale = LlamaModel.permute(scale, n_head, n_head)
elif name.endswith("k_proj.weight"):
weight = LlamaModel.permute(weight, n_head, n_kv_head)
scale = LlamaModel.permute(scale, n_head, n_kv_head)
super()._repack_nvfp4(name, weight, scale, scale2, input_scale)
_experts: list[dict[str, Tensor]] | None = None
@classmethod
def filter_tensors(cls, item: tuple[str, Callable[[], Tensor]]) -> tuple[str, Callable[[], Tensor]] | None:
name, gen = item
if "text_model." in name:
name = name.replace("text_model.", "") # for SmolVLM
return super().filter_tensors((name, gen))
def index_tensors(self, remote_hf_model_id: str | None = None) -> dict[str, Callable[[], Tensor]]:
tensors = super().index_tensors(remote_hf_model_id)
# Handle Eagle3Speculator nested config
if "transformer_layer_config" in self.hparams:
self.hparams = {**self.hparams, **self.hparams["transformer_layer_config"]}
# eagle3 detection
if "draft_vocab_size" in self.hparams and self.hparams["num_hidden_layers"] == 1:
logger.info("EAGLE-3: renaming midlayer.* / layers.0.* to model.layers.0.*")
new_tensors = {}
for name, gen in tensors.items():
if name.startswith("midlayer."):
new_name = "model.layers.0." + name[len("midlayer."):]
new_tensors[new_name] = gen
elif name.startswith("layers.0."): # Eagle3Speculator format
new_name = "model." + name
new_tensors[new_name] = gen
else:
new_tensors[name] = gen
return new_tensors
return tensors
def modify_tensors(self, data_torch: Tensor, name: str, bid: int | None) -> Iterable[tuple[str, Tensor]]:
# eagle3: special tensors that bypass standard llama mapping
if getattr(self, 'is_eagle3', False):
if name == "fc.weight":
yield (name, data_torch)
return
if name == "d2t":
# store for manual int64 handling in prepare_tensors (avoid F32 conversion)
if not hasattr(self, '_eagle3_int_tensors'):
self._eagle3_int_tensors = {}
self._eagle3_int_tensors[name] = data_torch
return
if name == "t2d":
# not used at runtime, skip
return
if name.endswith(".hidden_norm.weight"):
yield (self.format_tensor_name(gguf.MODEL_TENSOR.ATTN_NORM_2, bid), data_torch)
return
n_head = self.find_hparam(["n_heads", "num_attention_heads"])
n_kv_head = self.find_hparam(["n_kv_heads", "num_key_value_heads"])
if self.hf_arch == "LlamaModel":
name = "model." + name
if self.undo_permute:
if name.endswith(("q_proj.weight", "q_proj.bias")):
data_torch = LlamaModel.permute(data_torch, n_head, n_head)
if name.endswith(("k_proj.weight", "k_proj.bias")):
data_torch = LlamaModel.permute(data_torch, n_head, n_kv_head)
# process the experts separately
if name.find("block_sparse_moe.experts") != -1:
n_experts = self.hparams["num_local_experts"]
assert bid is not None
if self._experts is None:
self._experts = [{} for _ in range(self.block_count)]
self._experts[bid][name] = data_torch
if len(self._experts[bid]) >= n_experts * 3:
# merge the experts into a single 3d tensor
for wid in ["w1", "w2", "w3"]:
datas: list[Tensor] = []
for xid in range(n_experts):
ename = f"model.layers.{bid}.block_sparse_moe.experts.{xid}.{wid}.weight"
datas.append(self._experts[bid][ename])
del self._experts[bid][ename]
data_torch = torch.stack(datas, dim=0)
merged_name = f"layers.{bid}.feed_forward.experts.{wid}.weight"
yield from super().modify_tensors(data_torch, merged_name, bid)
return
else:
return
yield from super().modify_tensors(data_torch, name, bid)
def generate_extra_tensors(self) -> Iterable[tuple[str, Tensor]]:
if rope_params := self.rope_parameters.get("full_attention", self.rope_parameters):
if rope_params.get("rope_type", '').lower() == "llama3":
base = rope_params.get("rope_theta", 10000.0)
if (dim := self.hparams.get("head_dim")) is None:
dim = self.hparams["hidden_size"] // self.hparams["num_attention_heads"]
freqs = 1.0 / (base ** (torch.arange(0, dim, 2, dtype=torch.float32) / dim))
factor = rope_params.get("factor", 8.0)
low_freq_factor = rope_params.get("low_freq_factor", 1.0)
high_freq_factor = rope_params.get("high_freq_factor", 4.0)
old_context_len = rope_params.get("original_max_position_embeddings", 8192)
low_freq_wavelen = old_context_len / low_freq_factor
high_freq_wavelen = old_context_len / high_freq_factor
# assert low_freq_wavelen != high_freq_wavelen # Errors for Llama4
rope_factors = []
for freq in freqs:
wavelen = 2 * math.pi / freq
if wavelen < high_freq_wavelen:
rope_factors.append(1)
elif wavelen > low_freq_wavelen:
rope_factors.append(factor)
else:
smooth = (old_context_len / wavelen - low_freq_factor) / (high_freq_factor - low_freq_factor)
rope_factors.append(1 / ((1 - smooth) / factor + smooth))
yield (self.format_tensor_name(gguf.MODEL_TENSOR.ROPE_FREQS), torch.tensor(rope_factors, dtype=torch.float32))
def prepare_tensors(self):
# eagle3: collect d2t original dtype before parent converts tensors to F32
eagle3_original_dtypes = {}
if getattr(self, 'is_eagle3', False):
for name, data_torch in self.get_tensors():
if name == "d2t":
eagle3_original_dtypes[name] = data_torch.dtype
super().prepare_tensors()
# eagle3: write d2t as absolute target token ids
if getattr(self, 'is_eagle3', False) and hasattr(self, '_eagle3_int_tensors'):
for name, data_torch in self._eagle3_int_tensors.items():
old_dtype = eagle3_original_dtypes.get(name, data_torch.dtype)
data = data_torch.to(torch.int64).cpu().numpy()
if name == "d2t":
data = data.reshape(-1)
data = data + np.arange(data.size, dtype=np.int64)
if np.any((data < 0) | (data >= self.target_vocab_size)):
raise ValueError(f"EAGLE-3 d2t target ids out of range for target vocab size {self.target_vocab_size}")
if np.unique(data).size != data.size:
raise ValueError("EAGLE-3 d2t contains duplicate target ids")
data_qtype = gguf.GGMLQuantizationType.I64
shape_str = f"{{{', '.join(str(n) for n in reversed(data.shape))}}}"
logger.info(f"{name + ',':<30} {old_dtype} --> {data_qtype.name}, shape = {shape_str}")
self.gguf_writer.add_tensor(name, data, raw_dtype=data_qtype)
if self._experts is not None:
# flatten `list[dict[str, Tensor]]` into `list[str]`
experts = [k for d in self._experts for k in d.keys()]
if len(experts) > 0:
raise ValueError(f"Unprocessed experts: {experts}")
@ModelBase.register("ArceeForCausalLM")
class ArceeModel(LlamaModel):
model_arch = gguf.MODEL_ARCH.ARCEE
def set_gguf_parameters(self):
super().set_gguf_parameters()
self._try_set_pooling_type()
@ModelBase.register(
"Llama4ForConditionalGeneration",
"Llama4ForCausalLM",
)
class Llama4Model(LlamaModel):
model_arch = gguf.MODEL_ARCH.LLAMA4
undo_permute = False
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
# IMPORTANT: the normal "intermediate_size" is renamed to "intermediate_size_mlp", we need to undo this
self.hparams["intermediate_size_moe"] = self.hparams["intermediate_size"]
self.hparams["intermediate_size"] = self.hparams["intermediate_size_mlp"]
def set_vocab(self):
self._set_vocab_gpt2()
def set_gguf_parameters(self):
super().set_gguf_parameters()
self.gguf_writer.add_interleave_moe_layer_step(self.hparams["interleave_moe_layer_step"])
self.gguf_writer.add_expert_feed_forward_length(self.hparams["intermediate_size_moe"])
if "layer_types" in self.hparams:
if all(lt == "full_attention" for lt in self.hparams["layer_types"]):
# all layers are full attention (for MobileLLM), disable swa
self.gguf_writer.add_sliding_window(0)
def modify_tensors(self, data_torch: Tensor, name: str, bid: int | None):
# split the gate_up into gate and up
if "gate_up_proj" in name:
name_up = name.replace("gate_up_proj", "up_proj.weight")
name_gate = name.replace("gate_up_proj", "gate_proj.weight")
dim_half = data_torch.shape[-1] // 2
gate_proj_weight, up_proj_weight = data_torch.transpose(-1, -2).split(dim_half, dim=-2)
yield from super().modify_tensors(gate_proj_weight, name_gate, bid)
yield from super().modify_tensors(up_proj_weight, name_up, bid)
return
if name.endswith("down_proj"):
name += ".weight"
data_torch = data_torch.transpose(-1, -2)
yield from super().modify_tensors(data_torch, name, bid)
@ModelBase.register("LlamaBidirectionalModel")
class LlamaEmbedNemotronModel(LlamaModel):
model_arch = gguf.MODEL_ARCH.LLAMA_EMBED
@ModelBase.register("SmolLM3ForCausalLM")
class SmolLM3Model(LlamaModel):
model_arch = gguf.MODEL_ARCH.SMOLLM3
@ModelBase.register("ApertusForCausalLM")
class ApertusModel(LlamaModel):
model_arch = gguf.MODEL_ARCH.APERTUS
undo_permute = False
_alpha_n = {}
_alpha_p = {}
_beta = {}
_eps = {}
def modify_tensors(self, data_torch, name, bid):
# Handle xIELU activation parameters
n_layers = self.hparams["num_hidden_layers"]
if name.endswith(".act_fn.alpha_n"):
self._alpha_n[bid] = data_torch.to("cpu").float().item()
if (len(self._alpha_n) == n_layers):
self.gguf_writer.add_xielu_alpha_n([self._alpha_n[k] for k in sorted(self._alpha_n)])
return
if name.endswith(".act_fn.alpha_p"):
self._alpha_p[bid] = data_torch.to("cpu").float().item()
if (len(self._alpha_p) == n_layers):
self.gguf_writer.add_xielu_alpha_p([self._alpha_p[k] for k in sorted(self._alpha_p)])
return
if name.endswith(".act_fn.beta"):
self._beta[bid] = data_torch.to("cpu").float().item()
if (len(self._beta) == n_layers):
self.gguf_writer.add_xielu_beta([self._beta[k] for k in sorted(self._beta)])
return
if name.endswith(".act_fn.eps"):
self._eps[bid] = data_torch.to("cpu").float().item()
if (len(self._eps) == n_layers):
self.gguf_writer.add_xielu_eps([self._eps[k] for k in sorted(self._eps)])
return
yield from super().modify_tensors(data_torch, name, bid)
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