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# SPDX-License-Identifier: Apache-2.0
# SPDX-FileCopyrightText: Copyright contributors to the vLLM project
# Adapted from
# https://github.com/huggingface/transformers/blob/main/src/transformers/models/Glm4v/modeling_Glm4v.py
# Copyright 2025 The vLLM team.
# Copyright 2025 The ZhipuAI Team.
# Copyright 2025 The HuggingFace Inc. team.
# All rights reserved.
#
# This code is based on EleutherAI's GPT-NeoX library and the GPT-NeoX
# and OPT implementations in this library. It has been modified from its
# original forms to accommodate minor architectural differences compared
# to GPT-NeoX and OPT used by the Meta AI team that trained the model.
#
# 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.
"""Inference-only GLM-4.1V & GLM-4.6V-Flash, AutoGLM-Phone-9B model
compatible with HuggingFace weights."""
import math
from collections.abc import Callable, Iterable, Iterator, Mapping, Sequence
from functools import partial
from typing import Annotated, Any, Literal, TypeAlias
import numpy as np
import torch
import torch.nn as nn
import torch.nn.functional as F
import transformers
from einops import rearrange
from packaging.version import Version
from transformers import BatchFeature, Glm4vProcessor
from transformers.models.glm4v.configuration_glm4v import (
Glm4vTextConfig,
Glm4vVisionConfig,
)
from transformers.models.glm4v.image_processing_glm4v import (
Glm4vImageProcessor,
smart_resize,
)
from transformers.models.glm4v.video_processing_glm4v import Glm4vVideoProcessor
from transformers.video_utils import VideoMetadata
from vllm.config import VllmConfig
from vllm.config.multimodal import BaseDummyOptions, VideoDummyOptions
from vllm.distributed import get_tensor_model_parallel_world_size, parallel_state
from vllm.distributed import utils as dist_utils
from vllm.inputs import MultiModalDataDict
from vllm.logger import init_logger
from vllm.model_executor.layers.attention import (
MMEncoderAttention,
)
from vllm.model_executor.layers.conv import Conv2dLayer, Conv3dLayer
from vllm.model_executor.layers.layernorm import RMSNorm
from vllm.model_executor.layers.linear import (
ColumnParallelLinear,
MergedColumnParallelLinear,
QKVParallelLinear,
RowParallelLinear,
)
from vllm.model_executor.layers.quantization import QuantizationConfig
from vllm.model_executor.layers.quantization.compressed_tensors import (
compressed_tensors,
)
from vllm.model_executor.layers.rotary_embedding import get_rope
from vllm.model_executor.layers.rotary_embedding.common import (
ApplyRotaryEmb,
)
from vllm.model_executor.models.module_mapping import MultiModelKeys
from vllm.multimodal import MULTIMODAL_REGISTRY
from vllm.multimodal.inputs import (
MultiModalFeatureSpec,
MultiModalFieldConfig,
MultiModalKwargsItems,
VideoItem,
)
from vllm.multimodal.parse import ImageSize, MultiModalDataItems, MultiModalDataParser
from vllm.multimodal.processing import (
BaseDummyInputsBuilder,
BaseMultiModalProcessor,
BaseProcessingInfo,
PromptReplacement,
PromptUpdate,
PromptUpdateDetails,
)
from vllm.sequence import IntermediateTensors
from vllm.utils.tensor_schema import TensorSchema, TensorShape
from vllm.v1.attention.backends.registry import AttentionBackendEnum
from vllm.v1.worker.encoder_cudagraph_defs import EncoderCudaGraphReplayBuffers
from ..layers.activation import SiluAndMul
from .interfaces import (
MultiModalEmbeddings,
SupportsEncoderCudaGraph,
SupportsLoRA,
SupportsMRoPE,
SupportsMultiModal,
SupportsPP,
)
from .qwen2_vl import _create_qwen2vl_field_factory
from .utils import (
AutoWeightsLoader,
WeightsMapper,
init_vllm_registered_model,
maybe_prefix,
)
from .vision import (
get_vit_attn_backend,
is_vit_use_data_parallel,
run_dp_sharded_mrope_vision_model,
)
logger = init_logger(__name__)
# For profile run
_MAX_FRAMES_PER_VIDEO = 600
TRANSFORMERS_WITH_GA = Version(transformers.__version__) >= Version("5.10.0.dev0")
def _to_video_metadata(metadata: Mapping[str, Any]) -> VideoMetadata:
return VideoMetadata(
**{k: metadata[k] for k in metadata if k != "do_sample_frames"}
)
# === Vision Inputs === #
class Glm4vImagePixelInputs(TensorSchema):
"""
Dimensions:
- np: Number of patches
- cpp: Number of channels * patch_size * patch_size
- ni: Number of images
- g: Grid dimensions (3 for grid_t, grid_h, grid_w)
"""
type: Literal["pixel_values"] = "pixel_values"
pixel_values: Annotated[torch.Tensor, TensorShape("np", "cpp")]
image_grid_thw: Annotated[torch.Tensor, TensorShape("ni", 3)]
class Glm4vImageEmbeddingInputs(TensorSchema):
"""
Dimensions:
- f: Number of image features (varies based on image resolution)
- h: Hidden size (must match language model backbone)
- n: Number of images
- g: Grid dimensions (3 for grid_t, grid_h, grid_w)
"""
type: Literal["image_embeds"] = "image_embeds"
image_embeds: Annotated[torch.Tensor, TensorShape("f", "h")]
image_grid_thw: Annotated[torch.Tensor, TensorShape("n", 3)]
Glm4vImageInputs: TypeAlias = Glm4vImagePixelInputs | Glm4vImageEmbeddingInputs
class Glm4vVideoPixelInputs(TensorSchema):
"""
Dimensions:
- np: Number of patches
- ctpp: Number of channels * temporal_patch_size *
patch_size * patch_size
- f: Number of frames
- g: Grid dimensions (3 for grid_t which is usually 1 for processed
video, grid_h, grid_w)
"""
type: Literal["pixel_values_videos"] = "pixel_values_videos"
pixel_values_videos: Annotated[torch.Tensor, TensorShape("np", "ctpp")]
video_grid_thw: Annotated[torch.Tensor, TensorShape("f", 3)]
class Glm4vVideoEmbeddingInputs(TensorSchema):
"""
Dimensions:
- p: Number of video patches across all frames
- h: Hidden size (must match language model backbone)
- f: Number of frames
- g: Grid dimensions (3 for grid_t which is usually 1 for processed
video, grid_h, grid_w)
"""
type: Literal["video_embeds"] = "video_embeds"
video_embeds: Annotated[torch.Tensor, TensorShape("p", "h")]
video_grid_thw: Annotated[torch.Tensor, TensorShape("f", 3)]
Glm4vVideoInputs: TypeAlias = Glm4vVideoPixelInputs | Glm4vVideoEmbeddingInputs
# ==== Vision Encoder ==== #
class Glm4vVisionMLP(nn.Module):
def __init__(
self,
in_features: int,
hidden_features: int,
bias: bool = False,
quant_config: QuantizationConfig | None = None,
prefix: str = "",
):
super().__init__()
use_data_parallel = is_vit_use_data_parallel()
self.gate_up_proj = MergedColumnParallelLinear(
input_size=in_features,
output_sizes=[hidden_features] * 2,
bias=bias,
quant_config=quant_config,
prefix=f"{prefix}.gate_up_proj",
disable_tp=use_data_parallel,
)
self.down_proj = RowParallelLinear(
hidden_features,
in_features,
bias=bias,
quant_config=quant_config,
prefix=f"{prefix}.down_proj",
disable_tp=use_data_parallel,
)
self.act_fn = SiluAndMul()
def forward(self, x: torch.Tensor):
x, _ = self.gate_up_proj(x)
x = self.act_fn(x)
x, _ = self.down_proj(x)
return x
def all_gather_interleave(local_tensor, hidden_size: int, tp_size: int):
"""All-gather the input tensor interleavely across model parallel group."""
import torch.distributed as dist
gathered_tensors = [torch.zeros_like(local_tensor) for _ in range(tp_size)]
dist.all_gather(
gathered_tensors,
local_tensor,
group=parallel_state.get_tp_group().device_group,
)
gathered_tensors_split = [
torch.split(tensor, hidden_size // tp_size, -1) for tensor in gathered_tensors
]
ordered_tensors = [
tensor for pair in zip(*gathered_tensors_split) for tensor in pair
]
result_tensor = torch.cat(ordered_tensors, dim=-1)
return result_tensor
class Glm4vVisionAttention(nn.Module):
def __init__(
self,
embed_dim: int,
num_heads: int,
projection_size: int,
quant_config: QuantizationConfig | None = None,
prefix: str = "",
) -> None:
super().__init__()
# Per attention head and per partition values.
use_data_parallel = is_vit_use_data_parallel()
self.tp_size = (
1 if use_data_parallel else get_tensor_model_parallel_world_size()
)
self.tp_rank = (
0 if use_data_parallel else parallel_state.get_tensor_model_parallel_rank()
)
self.hidden_size_per_attention_head = dist_utils.divide(
projection_size, num_heads
)
self.num_attention_heads_per_partition = dist_utils.divide(
num_heads, self.tp_size
)
self.qkv = QKVParallelLinear(
hidden_size=embed_dim,
head_size=self.hidden_size_per_attention_head,
total_num_heads=num_heads,
total_num_kv_heads=num_heads,
bias=False,
quant_config=quant_config,
# Change qkv prefix to align with GLM-4.5V-FP8 quantization cfg
prefix=f"{prefix}.qkv_proj"
if isinstance(quant_config, compressed_tensors.CompressedTensorsConfig)
else f"{prefix}.qkv",
disable_tp=use_data_parallel,
)
self.proj = RowParallelLinear(
input_size=projection_size,
output_size=embed_dim,
quant_config=quant_config,
prefix=f"{prefix}.proj",
bias=False,
disable_tp=use_data_parallel,
)
self.attn = MMEncoderAttention(
num_heads=self.num_attention_heads_per_partition,
head_size=self.hidden_size_per_attention_head,
scale=self.hidden_size_per_attention_head**-0.5,
prefix=f"{prefix}.attn",
)
self.apply_rotary_emb = ApplyRotaryEmb(enforce_enable=True)
def split_qkv(self, qkv: torch.Tensor) -> tuple[torch.Tensor, ...]:
# [s, b, 3 * head * head_dim]
seq_len, bs, _ = qkv.shape
# [s, b, 3 * head * head_dim] -> 3 * [s, b, head * head_dim]
q, k, v = qkv.chunk(3, dim=2)
# 3 * [s, b, head * head_dim] -> 3 * [s, b, head, head_dim]
new_shape = (
seq_len,
bs,
self.num_attention_heads_per_partition,
self.hidden_size_per_attention_head,
)
q, k, v = (x.view(*new_shape) for x in (q, k, v))
return q, k, v
def forward(
self,
x: torch.Tensor,
cu_seqlens: torch.Tensor,
rotary_pos_emb_cos: torch.Tensor,
rotary_pos_emb_sin: torch.Tensor,
max_seqlen: torch.Tensor | None = None, # Only used for Flash Attention
) -> torch.Tensor:
# [s, b, c] --> [s, b, head * 3 * head_dim]
x, _ = self.qkv(x)
# [s, b, 3 * head * head_dim] -> 3 * [s, b, head, head_dim]
q, k, v = self.split_qkv(x)
q, k, v = (rearrange(x, "s b ... -> b s ...").contiguous() for x in (q, k, v))
if rotary_pos_emb_cos is not None and rotary_pos_emb_sin is not None:
# [2 * b, s, heads, head_dim]
qk_concat = torch.cat([q, k], dim=0)
qk_rotated = self.apply_rotary_emb(
qk_concat,
rotary_pos_emb_cos,
rotary_pos_emb_sin,
)
q, k = torch.chunk(qk_rotated, 2, dim=0)
context_layer = self.attn(
query=q,
key=k,
value=v,
cu_seqlens=cu_seqlens,
max_seqlen=max_seqlen,
)
context_layer = rearrange(context_layer, "b s h d -> s b (h d)").contiguous()
output, _ = self.proj(context_layer)
return output
class Glm4vVisionBlock(nn.Module):
def __init__(
self,
dim: int,
num_heads: int,
mlp_hidden_dim: int,
norm_layer: Callable[[int], nn.Module] | None = None,
quant_config: QuantizationConfig | None = None,
prefix: str = "",
) -> None:
super().__init__()
if norm_layer is None:
norm_layer = partial(nn.LayerNorm, eps=1e-6)
self.norm1 = norm_layer(dim)
self.norm2 = norm_layer(dim)
self.attn = Glm4vVisionAttention(
embed_dim=dim,
num_heads=num_heads,
projection_size=dim,
quant_config=quant_config,
prefix=f"{prefix}.attn",
)
self.mlp = Glm4vVisionMLP(
dim,
mlp_hidden_dim,
bias=False,
quant_config=quant_config,
prefix=f"{prefix}.mlp",
)
def forward(
self,
x: torch.Tensor,
cu_seqlens: torch.Tensor,
rotary_pos_emb_cos: torch.Tensor,
rotary_pos_emb_sin: torch.Tensor,
max_seqlen: int | None = None, # Only used for Flash Attention
) -> torch.Tensor:
x_attn = self.attn(
self.norm1(x),
cu_seqlens=cu_seqlens,
rotary_pos_emb_cos=rotary_pos_emb_cos,
rotary_pos_emb_sin=rotary_pos_emb_sin,
max_seqlen=max_seqlen,
)
x_fused_norm, residual = self.norm2(x, residual=x_attn)
x = residual + self.mlp(x_fused_norm)
return x
class Glm4vVisionPatchEmbed(nn.Module):
def __init__(
self,
patch_size: int = 14,
temporal_patch_size: int = 1,
in_channels: int = 3,
hidden_size: int = 1536,
) -> None:
super().__init__()
self.patch_size = patch_size
self.temporal_patch_size = temporal_patch_size
self.hidden_size = hidden_size
kernel_size = (temporal_patch_size, patch_size, patch_size)
self.proj = Conv3dLayer(
in_channels,
hidden_size,
kernel_size=kernel_size,
stride=kernel_size,
bias=True,
)
def forward(self, x: torch.Tensor) -> torch.Tensor:
L, C = x.shape
x = x.view(L, -1, self.temporal_patch_size, self.patch_size, self.patch_size)
x = self.proj(x).view(L, self.hidden_size)
return x
class Glm4vPatchMerger(nn.Module):
def __init__(
self,
d_model: int,
context_dim: int,
quant_config: QuantizationConfig | None = None,
bias: bool = False,
prefix: str = "",
) -> None:
super().__init__()
use_data_parallel = is_vit_use_data_parallel()
self.hidden_size = d_model
self.proj = ColumnParallelLinear(
self.hidden_size,
self.hidden_size,
bias=bias,
gather_output=True,
quant_config=quant_config,
prefix=f"{prefix}.proj",
disable_tp=use_data_parallel,
)
self.post_projection_norm = nn.LayerNorm(self.hidden_size)
self.gate_up_proj = MergedColumnParallelLinear(
input_size=self.hidden_size,
output_sizes=[context_dim] * 2,
bias=bias,
quant_config=quant_config,
prefix=f"{prefix}.gate_up_proj",
disable_tp=use_data_parallel,
)
self.down_proj = RowParallelLinear(
context_dim,
self.hidden_size,
bias=bias,
quant_config=quant_config,
prefix=f"{prefix}.down_proj",
disable_tp=use_data_parallel,
)
self.act_fn = SiluAndMul()
self.extra_activation_func = nn.GELU()
def forward(self, x: torch.Tensor):
x, _ = self.proj(x)
x = self.extra_activation_func(self.post_projection_norm(x))
gate_up, _ = self.gate_up_proj(x)
x = self.act_fn(gate_up)
x, _ = self.down_proj(x)
return x
class Glm4vVisionEmbeddings(nn.Module):
def __init__(self, config: Glm4vVisionConfig):
super().__init__()
self.config = config
self.embed_dim = config.hidden_size
self.image_size = config.image_size
self.patch_size = config.patch_size
self.num_patches = (self.image_size // self.patch_size) ** 2
self.num_positions = self.num_patches
self.position_embedding = nn.Embedding(self.num_positions, self.embed_dim)
self.register_buffer(
"position_ids",
torch.arange(self.num_positions).expand((1, -1)),
persistent=False,
)
def forward(
self, embeddings, lengths, image_shapes, h_coords, w_coords
) -> torch.Tensor:
pos_embed_weight = self.position_embedding.weight
hidden_size = pos_embed_weight.shape[1]
total_seq = h_coords.shape[0]
device = pos_embed_weight.device
# Move coordinates to correct device
h_coords, w_coords = h_coords.to(device), w_coords.to(device)
# Handle empty sequence case
if total_seq == 0:
adapted_pos_embed = torch.empty(
0, hidden_size, device=device, dtype=pos_embed_weight.dtype
)
else:
# Convert inputs to tensors if needed
if isinstance(lengths, list):
lengths = torch.tensor(lengths, device=device, dtype=torch.long)
if not isinstance(image_shapes, torch.Tensor):
image_shapes = torch.tensor(
image_shapes, device=device, dtype=torch.long
)
# Prepare 2D position embedding
orig_size_sq = pos_embed_weight.shape[0]
orig_size = int(orig_size_sq**0.5)
pos_embed_2d = (
pos_embed_weight.view(orig_size, orig_size, hidden_size)
.permute(2, 0, 1)
.unsqueeze(0)
.to(device=device, dtype=torch.float32)
)
# Calculate target dimensions for each patch
# Add bounds checking for data parallel mode
if len(lengths) > image_shapes.shape[0]:
# In data parallel mode, some GPUs might not have all
# image shapes
# Use available image shapes, cycling if necessary
target_h_list = []
target_w_list = []
for i in range(len(lengths)):
# Cycle through available shapes
shape_idx = i % image_shapes.shape[0]
target_h_list.append(image_shapes[shape_idx, 1].repeat(lengths[i]))
target_w_list.append(image_shapes[shape_idx, 2].repeat(lengths[i]))
target_h = torch.cat(target_h_list).to(
device=device, dtype=torch.float32
)
target_w = torch.cat(target_w_list).to(
device=device, dtype=torch.float32
)
else:
target_h = torch.cat(
[image_shapes[i, 1].repeat(lengths[i]) for i in range(len(lengths))]
).to(device=device, dtype=torch.float32)
target_w = torch.cat(
[image_shapes[i, 2].repeat(lengths[i]) for i in range(len(lengths))]
).to(device=device, dtype=torch.float32)
# Normalize coordinates to [-1, 1] range for grid_sample
h_coords = h_coords.to(device=device, dtype=torch.float32)
w_coords = w_coords.to(device=device, dtype=torch.float32)
norm_w = ((w_coords + 0.5) / target_w) * 2 - 1
norm_h = ((h_coords + 0.5) / target_h) * 2 - 1
# Create sampling grid
grid = torch.stack((norm_w, norm_h), dim=-1).unsqueeze(0).unsqueeze(2)
# Perform bicubic interpolation
interpolated_embed_fp32 = F.grid_sample(
pos_embed_2d,
grid,
mode="bicubic",
align_corners=False,
padding_mode="border",
)
# Reshape and convert back to original dtype
adapted_pos_embed_fp32 = (
interpolated_embed_fp32.squeeze(0).squeeze(-1).permute(1, 0)
)
adapted_pos_embed = adapted_pos_embed_fp32.to(pos_embed_weight.dtype).to(
embeddings.device
)
# Add adapted position encoding to embeddings
embeddings = embeddings + adapted_pos_embed
return embeddings
class Glm4vVisionTransformer(nn.Module):
hf_to_vllm_mapper = WeightsMapper(
orig_to_new_stacked={
".attn.q.": (".attn.qkv.", "q"),
".attn.k.": (".attn.qkv.", "k"),
".attn.v.": (".attn.qkv.", "v"),
".gate_proj": (".gate_up_proj", 0),
".up_proj": (".gate_up_proj", 1),
}
)
def __init__(
self,
text_config: Glm4vTextConfig,
vision_config: Glm4vVisionConfig,
norm_eps: float = 1e-6,
quant_config: QuantizationConfig | None = None,
prefix: str = "",
) -> None:
super().__init__()
use_data_parallel = is_vit_use_data_parallel()
self.tp_size = (
1 if use_data_parallel else get_tensor_model_parallel_world_size()
)
patch_size = vision_config.patch_size
temporal_patch_size = vision_config.temporal_patch_size
in_channels = vision_config.in_channels
depth = vision_config.depth
self.hidden_size = vision_config.hidden_size
self.num_heads = vision_config.num_heads
self.patch_size = vision_config.patch_size
self.spatial_merge_size = vision_config.spatial_merge_size
self.out_hidden_size = vision_config.out_hidden_size
self.patch_embed = Glm4vVisionPatchEmbed(
patch_size=patch_size,
temporal_patch_size=temporal_patch_size,
in_channels=in_channels,
hidden_size=self.hidden_size,
)
norm_layer = partial(RMSNorm, eps=norm_eps)
head_dim = self.hidden_size // self.num_heads
self.rotary_pos_emb = get_rope(
head_size=head_dim,
max_position=8192,
is_neox_style=True,
rope_parameters={"partial_rotary_factor": 0.5},
)
self.blocks = nn.ModuleList(
[
Glm4vVisionBlock(
dim=self.hidden_size,
num_heads=self.num_heads,
mlp_hidden_dim=vision_config.out_hidden_size,
norm_layer=norm_layer,
quant_config=quant_config,
prefix=f"{prefix}.blocks.{layer_idx}",
)
for layer_idx in range(depth)
]
)
self.merger = Glm4vPatchMerger(
d_model=vision_config.out_hidden_size,
context_dim=vision_config.intermediate_size,
quant_config=quant_config,
bias=False,
prefix=f"{prefix}.merger",
)
self.embeddings = Glm4vVisionEmbeddings(vision_config)
self.post_conv_layernorm = RMSNorm(
vision_config.hidden_size, eps=vision_config.rms_norm_eps
)
self.downsample = Conv2dLayer(
in_channels=vision_config.hidden_size,
out_channels=vision_config.out_hidden_size,
kernel_size=vision_config.spatial_merge_size,
stride=vision_config.spatial_merge_size,
)
self.post_layernorm = RMSNorm(
vision_config.hidden_size, eps=vision_config.rms_norm_eps
)
self.attn_backend = get_vit_attn_backend(
head_size=head_dim,
dtype=torch.get_default_dtype(),
)
@property
def dtype(self) -> torch.dtype:
return self.patch_embed.proj.weight.dtype
@property
def device(self) -> torch.device:
return self.patch_embed.proj.weight.device
def rot_pos_emb(
self, grid_thw: list[list[int]]
) -> tuple[torch.Tensor, torch.Tensor, torch.Tensor]:
pos_ids = []
for t, h, w in grid_thw:
hpos_ids = torch.arange(h).unsqueeze(1).expand(-1, w)
wpos_ids = torch.arange(w).unsqueeze(0).expand(h, -1)
hpos_ids = (
hpos_ids.reshape(
h // self.spatial_merge_size,
self.spatial_merge_size,
w // self.spatial_merge_size,
self.spatial_merge_size,
)
.permute(0, 2, 1, 3)
.flatten()
)
wpos_ids = (
wpos_ids.reshape(
h // self.spatial_merge_size,
self.spatial_merge_size,
w // self.spatial_merge_size,
self.spatial_merge_size,
)
.permute(0, 2, 1, 3)
.flatten()
)
pos_ids.append(torch.stack([hpos_ids, wpos_ids], dim=-1).repeat(t, 1))
pos_ids = torch.cat(pos_ids, dim=0)
max_grid_size = max(max(h, w) for _, h, w in grid_thw)
# Use pre-computed cos_sin_cache from RotaryEmbedding
cos, sin = self.rotary_pos_emb.get_cos_sin(max_grid_size)
pos_ids = pos_ids.to(cos.device, non_blocking=True)
cos_combined = cos[pos_ids].flatten(1)
sin_combined = sin[pos_ids].flatten(1)
return cos_combined, sin_combined, pos_ids
def compute_attn_mask_seqlen(
self,
cu_seqlens: torch.Tensor,
) -> torch.Tensor | None:
max_seqlen = None
if self.attn_backend in {
AttentionBackendEnum.FLASH_ATTN,
AttentionBackendEnum.ROCM_AITER_FA,
AttentionBackendEnum.TRITON_ATTN,
}:
max_seqlen = (cu_seqlens[1:] - cu_seqlens[:-1]).max()
return max_seqlen
def pos_embeds_interpolate(self, grid_thw: list[list[int]]) -> torch.Tensor:
"""Pre-compute absolute position embeddings for all input samples.
The original `self.embeddings` fused token embeddings and position embeddings
in one call, which prevented preparing position embeddings as static metadata
required by CUDA graph capture / replay. This method decouples the two by
feeding an all-zero token tensor to `self.embeddings`. The module therefore only
performs bicubic interpolation based on the coordinates and returns pure
position embeddings. These are cached in `prepare_encoder_metadata` and later
added to the patch tokens in `forward` via `x = x + pos_embeds`, keeping the
forward graph compatible with CUDA graph replay. Coordinate generation matches
`rot_pos_emb` exactly to guarantee spatial alignment.
"""
device = self.embeddings.position_embedding.weight.device
dtype = self.dtype
all_embeds = []
for t, h, w in grid_thw:
# Use the same coordinate generation logic as rot_pos_emb
# to ensure consistent positional embedding interpolation
h_coords = torch.arange(h).unsqueeze(1).expand(-1, w)
w_coords = torch.arange(w).unsqueeze(0).expand(h, -1)
h_coords = (
h_coords.reshape(
h // self.spatial_merge_size,
self.spatial_merge_size,
w // self.spatial_merge_size,
self.spatial_merge_size,
)
.permute(0, 2, 1, 3)
.flatten()
)
w_coords = (
w_coords.reshape(
h // self.spatial_merge_size,
self.spatial_merge_size,
w // self.spatial_merge_size,
self.spatial_merge_size,
)
.permute(0, 2, 1, 3)
.flatten()
)
lengths = [h * w] * t
image_shapes = torch.tensor([[t, h, w]], device=device)
h_coords_repeated = h_coords.repeat(t)
w_coords_repeated = w_coords.repeat(t)
embeds = self.embeddings(
embeddings=torch.zeros(
h * w * t, self.hidden_size, device=device, dtype=dtype
),
lengths=lengths,
image_shapes=image_shapes,
h_coords=h_coords_repeated,
w_coords=w_coords_repeated,
)
all_embeds.append(embeds)
return torch.cat(all_embeds, dim=0).to(dtype)
def prepare_encoder_metadata(
self,
grid_thw_list: list[list[int]],
*,
max_batch_size: int | None = None,
max_frames_per_batch: int | None = None,
max_seqlen_override: int | None = None,
device: torch.device | None = None,
) -> dict[str, torch.Tensor | None]:
"""Compute encoder metadata from grid_thw_list.
Shared by the eager forward path, CUDA graph capture, and
CUDA graph replay to avoid duplicated implementation.
Args:
grid_thw_list: Grid configurations as list of [t, h, w].
max_batch_size: If set, pad cu_seqlens to this size
(needed for CUDA graph capture/replay).
max_frames_per_batch: If set, overrides max_batch_size for
cu_seqlens padding. For video inputs each item contributes
T attention sequences (frames); this sizes the buffer to
the total frame budget so video replays never overflow.
max_seqlen_override: If set, use this value for max_seqlen
instead of computing from cu_seqlens (needed for CUDA
graph capture to cover worst-case replay scenarios).
device: Device to place tensors on. Defaults to self.device.
"""
if device is None:
device = self.device
metadata: dict[str, torch.Tensor | None] = {}
# Positional embeddings
metadata["pos_embeds"] = self.pos_embeds_interpolate(grid_thw_list)
rotary_cos, rotary_sin, _ = self.rot_pos_emb(grid_thw_list)
metadata["rotary_pos_emb_cos"] = rotary_cos
metadata["rotary_pos_emb_sin"] = rotary_sin
# cu_seqlens from grid_thw
grid_thw_np = np.array(grid_thw_list, dtype=np.int32)
patches_per_frame = grid_thw_np[:, 1] * grid_thw_np[:, 2]
cu_seqlens = np.repeat(patches_per_frame, grid_thw_np[:, 0]).cumsum(
dtype=np.int32
)
cu_seqlens = np.concatenate([np.zeros(1, dtype=np.int32), cu_seqlens])
# Pad cu_seqlens to the required number of sequences.
# For videos each item contributes T frames = T attention sequences,
# so the total can exceed max_batch_size. max_frames_per_batch
# overrides the pad target when set.
pad_to = (
max_frames_per_batch if max_frames_per_batch is not None else max_batch_size
)
if pad_to is not None:
num_seqs = len(cu_seqlens) - 1
if num_seqs < pad_to:
cu_seqlens = np.concatenate(
[
cu_seqlens,
np.full(
pad_to - num_seqs,
cu_seqlens[-1],
dtype=np.int32,
),
]
)
# sequence_lengths (backend-specific)
metadata["sequence_lengths"] = MMEncoderAttention.maybe_compute_seq_lens(
self.attn_backend, cu_seqlens, device
)
# max_seqlen
if max_seqlen_override is not None:
max_seqlen_val = max_seqlen_override
else:
max_seqlen_val = MMEncoderAttention.compute_max_seqlen(
self.attn_backend, cu_seqlens
)
# Keep max_seqlen on CPU: attention wrappers call .item() on it,
# and having it on GPU would capture a wasteful D2H copy in CUDA
# graphs without changing behavior (the scalar is baked at capture).
metadata["max_seqlen"] = torch.tensor(max_seqlen_val, dtype=torch.int32)
# Recompute cu_seqlens (backend-specific transformation)
metadata["cu_seqlens"] = MMEncoderAttention.maybe_recompute_cu_seqlens(
self.attn_backend,
cu_seqlens,
self.hidden_size,
self.tp_size,
device,
)
return metadata
def forward(
self,
x: torch.Tensor,
grid_thw: torch.Tensor | list[list[int]],
*,
encoder_metadata: dict[str, torch.Tensor] | None = None,
) -> torch.Tensor:
if encoder_metadata is None:
if not isinstance(grid_thw, list):
grid_thw = grid_thw.tolist()
encoder_metadata = self.prepare_encoder_metadata(grid_thw)
# patchify
x = x.to(device=self.device, dtype=self.dtype)
x = self.patch_embed(x)
x = self.post_conv_layernorm(x)
pos_embeds = encoder_metadata["pos_embeds"]
x = x + pos_embeds
# transformers
x = x.unsqueeze(1)
for blk in self.blocks:
x = blk(
x,
cu_seqlens=encoder_metadata["cu_seqlens"],
rotary_pos_emb_cos=encoder_metadata["rotary_pos_emb_cos"],
rotary_pos_emb_sin=encoder_metadata["rotary_pos_emb_sin"],
max_seqlen=encoder_metadata["max_seqlen"],
)
# adapter
x = self.post_layernorm(x)
x = x.view(-1, self.spatial_merge_size, self.spatial_merge_size, x.shape[-1])
x = x.permute(0, 3, 1, 2)
x = self.downsample(x).view(-1, self.out_hidden_size)
x = self.merger(x)
return x
def load_weights(self, weights: Iterable[tuple[str, torch.Tensor]]) -> set[str]:
loader = AutoWeightsLoader(self)
return loader.load_weights(weights, mapper=self.hf_to_vllm_mapper)
class Glm4vProcessingInfo(BaseProcessingInfo):
def get_supported_mm_limits(self) -> Mapping[str, int | None]:
return {"image": None, "video": 1}
def get_image_processor(self, **kwargs: object) -> Glm4vImageProcessor:
return self.get_hf_processor(**kwargs).image_processor
def get_video_processor(self, **kwargs: object) -> Glm4vVideoProcessor:
return self.get_hf_processor(**kwargs).video_processor
def _get_processor_class_name(self) -> str | None:
from vllm.transformers_utils.processor import (
get_processor_cls_name_from_config,
)
from vllm.transformers_utils.utils import convert_model_repo_to_path
return get_processor_cls_name_from_config(
convert_model_repo_to_path(self.ctx.model_config.model),
revision=self.ctx.model_config.revision,
)
@staticmethod
def _get_longest_edge(size: Any, config_name: str) -> int:
if isinstance(size, dict):
longest_edge = size.get("longest_edge")
else:
longest_edge = getattr(size, "longest_edge", None)
if longest_edge is None:
raise ValueError(f"{config_name} must define longest_edge")
return int(longest_edge)
def get_mm_max_tokens_per_item(
self,
seq_len: int,
mm_counts: Mapping[str, int],
) -> Mapping[str, int] | None:
processor_class_name = self._get_processor_class_name()
if processor_class_name == "Glm4vProcessor":
return None
if processor_class_name is None:
processor = self.get_hf_processor()
if isinstance(processor, Glm4vProcessor):
return None
result: dict[str, int] = {}
if mm_counts.get("image", 0) > 0:
result["image"] = self.get_max_image_tokens()
if mm_counts.get("video", 0) > 0:
max_pixels = self._get_video_max_pixels()
vision_config = self.get_hf_config().vision_config
temporal_patch_size = vision_config.temporal_patch_size
patch_size = vision_config.patch_size
merge_size = vision_config.spatial_merge_size
max_vision_tokens = max_pixels // (
temporal_patch_size * patch_size**2 * merge_size**2
)
# GLMGA supports up to 640 frames (max_frames).
max_grid_t = 640 // temporal_patch_size
tokenizer = self.get_tokenizer()
max_ts_tokens = max(
len(tokenizer.encode(f"{t:.1f} seconds", add_special_tokens=False))
for t in range(min(max_grid_t, 300))
)
result["video"] = max_vision_tokens + max_grid_t * (2 + max_ts_tokens) + 2
return result
def get_data_parser(self):
return MultiModalDataParser(
video_needs_metadata=True,
expected_hidden_size=self._get_expected_hidden_size(),
)
def _get_vision_info(
self,
*,
image_width: int,
image_height: int,
num_frames: int = 16,
do_resize: bool = True,
max_image_pixels: int = 28 * 28 * 2 * 30000,
) -> tuple[ImageSize, int]:
hf_config = self.get_hf_config()
vision_config = hf_config.vision_config
patch_size = vision_config.patch_size
merge_size = vision_config.spatial_merge_size
temporal_patch_size = vision_config.temporal_patch_size
if do_resize:
resized_height, resized_width = smart_resize(
num_frames=num_frames
if num_frames > temporal_patch_size
else temporal_patch_size,
height=image_height,
width=image_width,
factor=patch_size * merge_size,
max_pixels=max_image_pixels,
)
preprocessed_size = ImageSize(width=resized_width, height=resized_height)
else:
preprocessed_size = ImageSize(width=image_width, height=image_height)
# NOTE: Frames are padded to be divisible by `temporal_patch_size`
# https://github.com/huggingface/transformers/blob/v4.48.3/src/transformers/models/qwen2_vl/image_processing_qwen2_vl.py#L294
padded_num_frames = num_frames + num_frames % temporal_patch_size
grid_t = max(padded_num_frames // temporal_patch_size, 1)
grid_h = preprocessed_size.height // patch_size
grid_w = preprocessed_size.width // patch_size
num_patches = grid_t * grid_h * grid_w
num_vision_tokens = num_patches // (merge_size**2)
return preprocessed_size, num_vision_tokens
def _get_image_max_pixels(self) -> int:
"""Read max_pixels from the HF image processor config.
Despite the name, ``longest_edge`` is a pixel **area** (total pixel
count), not an edge length. The HF processor passes it directly to
``smart_resize`` as the ``max_pixels`` argument, which constrains
``t_bar * h_bar * w_bar <= max_pixels``.
"""
mm_kwargs = self.ctx.get_merged_mm_kwargs({})
if (override_max_pixels := mm_kwargs.get("max_pixels")) is not None:
return int(override_max_pixels)
image_processor_config = self.ctx.get_hf_image_processor_config()
if not image_processor_config.get("size"):
from transformers.image_processing_base import ImageProcessingMixin
image_processor_config, _ = ImageProcessingMixin.get_image_processor_dict(
self.ctx.model_config.model,
revision=self.ctx.model_config.revision,
)
size = image_processor_config["size"]
if override_size := mm_kwargs.get("size"):
size = size | override_size
return self._get_longest_edge(size, "GLM4V image processor size")
def _get_video_max_pixels(self) -> int:
from transformers.video_processing_utils import BaseVideoProcessor
mm_kwargs = self.ctx.get_merged_mm_kwargs({})
if (override_max_pixels := mm_kwargs.get("max_pixels")) is not None:
return int(override_max_pixels)
video_processor_config, _ = BaseVideoProcessor.get_video_processor_dict(
self.ctx.model_config.model,
revision=self.ctx.model_config.revision,
)
size = video_processor_config["size"]
if override_size := mm_kwargs.get("size"):
size = size | override_size
return self._get_longest_edge(size, "GLM4V video processor size")
def get_image_size_with_most_features(self) -> ImageSize:
# Use num_frames=1 for single-image budget estimation.
# _get_vision_info defaults to num_frames=16 (video), which
# makes smart_resize constrain 16*H*W <= max_pixels, vastly
# underestimating the spatial budget for a single image and
# causing encoder cache overflow for large images
# (see https://github.com/vllm-project/vllm/issues/34040).
max_image_size, _ = self._get_vision_info(
image_width=9999999,
image_height=9999999,
num_frames=1,
max_image_pixels=self._get_image_max_pixels(),
)
return max_image_size
def get_num_image_tokens(
self,
*,
image_width: int,
image_height: int,
) -> int:
_, num_image_tokens = self._get_vision_info(
image_width=image_width,
image_height=image_height,
num_frames=1,
max_image_pixels=self._get_image_max_pixels(),
)
return num_image_tokens
def get_max_image_tokens(self) -> int:
target_width, target_height = self.get_image_size_with_most_features()
return self.get_num_image_tokens(
image_width=target_width,
image_height=target_height,
)
def get_num_video_tokens(
self,
*,
image_width: int,
image_height: int,
num_frames: int,
) -> int:
_, num_video_tokens = self._get_vision_info(
image_width=image_width,
image_height=image_height,
num_frames=num_frames,
max_image_pixels=28 * 28 * 2 * 30000,
)
return num_video_tokens
def _get_max_video_frames(self, max_tokens: int) -> int:
target_width, target_height = self.get_image_size_with_most_features()
num_frames = 0
while True:
next_num_frames = num_frames + 1
next_max_tokens = self.get_num_video_tokens(
image_width=target_width,
image_height=target_height,
num_frames=next_num_frames,
)
if next_max_tokens > max_tokens or next_max_tokens == 0:
break
num_frames = next_num_frames
return num_frames
def get_num_frames_with_most_features(
self,
seq_len: int,
mm_counts: Mapping[str, int],
) -> int:
max_images = mm_counts.get("image", 0)
max_videos = mm_counts.get("video", 0)
max_image_tokens = self.get_max_image_tokens() * max_images
max_total_frames = self._get_max_video_frames(seq_len - max_image_tokens)
max_frames_per_video = min(
max_total_frames // max(max_videos, 1), _MAX_FRAMES_PER_VIDEO
)
return max(max_frames_per_video, 1)
def _get_video_second_idx_glm4v(
self, metadata: dict[str, Any], total_frames: int
) -> list[int]:
video_processor = self.get_video_processor()
video_fps = metadata.get("fps", video_processor.fps)
meta_frames = metadata.get("total_num_frames", total_frames)
max_frame_idx = meta_frames - 1
duration = metadata.get("duration", round(max_frame_idx / video_fps) + 1)
do_sample_frames = metadata["do_sample_frames"]
if not do_sample_frames:
frame_indices = metadata["frames_indices"]
else:
if duration <= video_processor.max_duration:
n = int(math.floor(duration * video_processor.fps))
frame_indices = [
min(
max_frame_idx,
int(math.ceil(i * video_fps / video_processor.fps)),
)
for i in range(n)
]
else:
num_samples = int(video_processor.max_duration * video_processor.fps)
if num_samples >= meta_frames:
frame_indices = list(range(meta_frames))
else:
target_seconds = np.linspace(
0, duration, num_samples, endpoint=True
)
frame_indices = [
min(max_frame_idx, int(math.ceil(t * video_fps)))
for t in target_seconds
]
seen, uniq = set(), []
for idx in frame_indices:
if idx not in seen:
seen.add(idx)
uniq.append(idx)
if len(uniq) & 1:
uniq.append(uniq[-1])
frame_indices = uniq
full_second_idxs = [int(idx / video_fps) for idx in frame_indices]
timestamps_list = full_second_idxs[::2]
selected_timestamps = []
for idx in range(0, len(timestamps_list)):
selected_timestamps.append(timestamps_list[idx])
return selected_timestamps
def _get_video_second_idx_glm46v(
self, metadata: dict[str, Any], total_frames: int
) -> list[int]:
video_processor = self.get_video_processor()
video_fps = metadata["fps"]
meta_frames = metadata.get("total_num_frames", total_frames)
max_frame_idx = meta_frames - 1
duration = metadata.get("duration", round(max_frame_idx / video_fps) + 1)
do_sample_frames = metadata.get("do_sample_frames", True)
if not do_sample_frames:
frame_indices = metadata["frames_indices"]
else:
DYNAMIC_FPS_THRES = {30: 3, 300: 1, 2400: 0.5}
MAX_FRAME_COUNT_DYNAMIC = 640
MAX_DURATION = 2400
effective_duration = min(duration, MAX_DURATION)
if effective_duration <= 30:
target_fps = DYNAMIC_FPS_THRES[30]
elif effective_duration <= 300:
target_fps = DYNAMIC_FPS_THRES[300]
else:
target_fps = DYNAMIC_FPS_THRES[2400]
temporal_patch_size = getattr(video_processor, "temporal_patch_size", 1)
extract_t = int(effective_duration * target_fps * temporal_patch_size)
extract_t = min(extract_t, MAX_FRAME_COUNT_DYNAMIC)
duration_per_frame = 1 / video_fps
timestamps = [i * duration_per_frame for i in range(meta_frames)]
max_second = int(duration)
if meta_frames < extract_t:
frame_indices = np.linspace(
0, meta_frames - 1, extract_t, dtype=int
).tolist()
else:
frame_indices = []
current_second = 0.0
inv_fps = 1 / (temporal_patch_size * target_fps)
for frame_index in range(meta_frames):
if timestamps[frame_index] >= current_second:
current_second += inv_fps
frame_indices.append(frame_index)
if current_second >= max_second:
break
if len(frame_indices) < extract_t:
if len(frame_indices) == 0:
start, end = 0, max(meta_frames - 1, 0)
else:
start, end = frame_indices[0], frame_indices[-1]
frame_indices = np.linspace(start, end, extract_t, dtype=int).tolist()
elif len(frame_indices) > extract_t:
frame_indices = np.linspace(
0, meta_frames - 1, extract_t, dtype=int
).tolist()
seen, uniq = set(), []
for idx in frame_indices:
if idx not in seen:
seen.add(idx)
uniq.append(idx)
if len(uniq) & 1:
uniq.append(uniq[-1])
frame_indices = uniq
full_second_idxs = [int(idx / video_fps) for idx in frame_indices]
timestamps_list = full_second_idxs[::2]
selected_timestamps = []
for idx in range(len(timestamps_list)):
selected_timestamps.append(timestamps_list[idx])
return selected_timestamps
def _is_glmga_model(self, processor: object) -> bool:
"""Detect GLMGA variant via its Glmga sub-processors."""
for attr in ("image_processor", "video_processor"):
sub = getattr(processor, attr, None)
if sub and "Glmga" in type(sub).__name__:
return True
return False
def _get_video_second_idx_glmga(
self, metadata: dict[str, Any], total_frames: int
) -> list[int]:
"""Fixed fps=2 frame selection matching GlmgaVideoProcessor.sample_frames."""
video_processor = self.get_video_processor()
video_fps = metadata["fps"]
meta_frames = metadata.get("total_num_frames", total_frames)
max_frame_idx = meta_frames - 1
duration = metadata.get("duration", round(max_frame_idx / video_fps) + 1)
do_sample_frames = metadata.get("do_sample_frames", True)
if not do_sample_frames:
frame_indices = metadata["frames_indices"]
else:
target_fps = 2
max_frames = getattr(video_processor, "max_frames", 640)
extract_t = int(duration * target_fps)
extract_t = min(extract_t, max_frames)
duration_per_frame = 1 / video_fps
timestamps = [i * duration_per_frame for i in range(meta_frames)]
if meta_frames < extract_t:
frame_indices = [
math.floor(i * meta_frames / extract_t) for i in range(extract_t)
]
else:
frame_indices = []
current_second = 0.0
inv_fps = 1 / target_fps
for frame_index in range(meta_frames):
if timestamps[frame_index] >= current_second:
current_second += inv_fps
frame_indices.append(frame_index)
if current_second >= duration - inv_fps:
break
if len(frame_indices) < extract_t:
if len(frame_indices) == 0:
start, end = 0, max(meta_frames - 1, 0)
else:
start, end = frame_indices[0], frame_indices[-1]
frame_indices = np.linspace(start, end, extract_t, dtype=int).tolist()
elif len(frame_indices) > extract_t:
frame_indices = np.linspace(
0, meta_frames - 1, extract_t, dtype=int
).tolist()
seen, uniq = set(), []
for idx in frame_indices:
if idx not in seen:
seen.add(idx)
uniq.append(idx)
if len(uniq) & 1:
uniq.append(uniq[-1])
frame_indices = uniq
full_second_idxs = [int(idx / video_fps) for idx in frame_indices]
timestamps_list = full_second_idxs[::2]
return list(timestamps_list)
def _construct_video_placeholder(
self,
video_array: np.ndarray,
metadata: dict[str, Any],
grid_thw: torch.Tensor,
) -> list[int]:
hf_processor = self.get_hf_processor()
tokenizer = self.get_tokenizer()
image_processor = hf_processor.image_processor
hf_config = self.get_hf_config()
boi_token_id = hf_config.image_start_token_id
eoi_token_id = hf_config.image_end_token_id
bov_token_id = hf_config.video_start_token_id
eov_token_id = hf_config.video_end_token_id
merge_length = image_processor.merge_size**2
assert isinstance(grid_thw, torch.Tensor)
if isinstance(hf_processor, Glm4vProcessor):
timestamps = self._get_video_second_idx_glm4v(metadata, len(video_array))
elif self._is_glmga_model(hf_processor):
timestamps = self._get_video_second_idx_glmga(metadata, len(video_array))
else:
timestamps = self._get_video_second_idx_glm46v(metadata, len(video_array))
timestamp_format = (
"{}" if isinstance(hf_processor, Glm4vProcessor) else "{:.1f} seconds"
)
frames_idx_token = [
tokenizer.encode(timestamp_format.format(i), add_special_tokens=False)
for i in timestamps
]
T, H, W = grid_thw
num_tokens_per_frame = int(H * W) // merge_length
placeholder = []
placeholder.append(bov_token_id)
# Glm46VProcessor uses image_token_id for video frame embeddings;
# Glm4vProcessor uses video_token_id.
frame_embed_token_id = (
hf_processor.video_token_id
if isinstance(hf_processor, Glm4vProcessor) or not TRANSFORMERS_WITH_GA
else hf_processor.image_token_id
)
for frame_idx in frames_idx_token:
placeholder.append(boi_token_id)
placeholder.extend([frame_embed_token_id] * num_tokens_per_frame)
placeholder.append(eoi_token_id)
placeholder.extend(frame_idx)
placeholder.append(eov_token_id)
return placeholder
class Glm4vDummyInputsBuilder(BaseDummyInputsBuilder[Glm4vProcessingInfo]):
def get_dummy_text(self, mm_counts: Mapping[str, int]) -> str:
num_images = mm_counts.get("image", 0)
num_videos = mm_counts.get("video", 0)
hf_config = self.info.get_hf_config()
tokenizer = self.info.get_tokenizer()
image_token = tokenizer.decode([hf_config.image_token_id])
video_token_ids = [
hf_config.video_start_token_id,
hf_config.video_token_id,
hf_config.video_end_token_id,
]
video_token = tokenizer.decode(video_token_ids)
return image_token * num_images + video_token * num_videos
def get_dummy_mm_data(
self,
seq_len: int,
mm_counts: Mapping[str, int],
mm_options: Mapping[str, BaseDummyOptions],
) -> MultiModalDataDict:
num_images = mm_counts.get("image", 0)
num_videos = mm_counts.get("video", 0)
target_width, target_height = self.info.get_image_size_with_most_features()
target_num_frames = self.info.get_num_frames_with_most_features(
seq_len, mm_counts
)
image_overrides = mm_options.get("image")
video_overrides = mm_options.get("video")
return {
"image": self._get_dummy_images(
width=target_width,
height=target_height,
num_images=num_images,
overrides=image_overrides,
),
"video": self._get_dummy_videos(
width=target_width,
height=target_height,
num_frames=target_num_frames,
num_videos=num_videos,
overrides=video_overrides,
),
}
def _get_dummy_videos(
self,
*,
width: int,
height: int,
num_frames: int,
num_videos: int,
overrides: VideoDummyOptions | None = None,
) -> list[VideoItem]:
# GLM 4.6V requires at least 2 frames
num_frames = max(num_frames, 2)
if overrides and overrides.num_frames:
overrides.num_frames = max(overrides.num_frames, 2)
videos = super()._get_dummy_videos(
width=width,
height=height,
num_frames=num_frames,
num_videos=num_videos,
overrides=overrides,
)
videos = [v.copy() for v in videos]
video_items = []
for video in videos:
video_num_frames = video.shape[0]
video_metadata = {
"fps": 2.0,
"duration": video_num_frames / 2.0,
"total_num_frames": video_num_frames,
"frames_indices": list(range(video_num_frames)),
"video_backend": "opencv",
"do_sample_frames": False,
}
video_items.append((video, video_metadata))
return video_items
class Glm4vMultiModalProcessor(BaseMultiModalProcessor[Glm4vProcessingInfo]):
@staticmethod
def _get_direct_path_inputs(
mm_data: Mapping[str, object],
mm_kwargs: Mapping[str, object],
) -> tuple[Mapping[str, object], Mapping[str, object]]:
prepared_data = dict(mm_data)
prepared_kwargs = dict(mm_kwargs)
videos = prepared_data.get("videos")
if not (isinstance(videos, list) and len(videos) > 0):
return prepared_data, prepared_kwargs
hf_videos = []
hf_video_metadata = []
for item in videos:
if isinstance(item, tuple) and len(item) == 2:
video_array, metadata = item
hf_videos.append(video_array)
if isinstance(metadata, VideoMetadata):
hf_video_metadata.append(metadata)
elif isinstance(metadata, Mapping):
hf_video_metadata.append(_to_video_metadata(metadata))
if "do_sample_frames" in metadata:
prepared_kwargs["do_sample_frames"] = metadata[
"do_sample_frames"
]
elif metadata is not None:
raise TypeError(
"Video metadata must be a mapping or VideoMetadata, "
f"got {type(metadata)}"
)
else:
hf_videos.append(item)
prepared_data["videos"] = hf_videos
if hf_video_metadata:
prepared_data["video_metadata"] = hf_video_metadata
prepared_kwargs["return_metadata"] = True
return prepared_data, prepared_kwargs
def _call_hf_processor(
self,
prompt: str,
mm_data: Mapping[str, object],
mm_kwargs: Mapping[str, object],
tok_kwargs: Mapping[str, object],
) -> BatchFeature:
mm_data = dict(mm_data)
if not mm_data:
tokenizer = self.info.get_tokenizer()
prompt_ids = tokenizer.encode(prompt, add_special_tokens=False)
return BatchFeature(dict(input_ids=[prompt_ids]), tensor_type="pt")
processor = self.info.get_hf_processor(**mm_kwargs)
# Glm46VProcessor and GLMGA handle image/video placeholders together
# via the direct path. Only Glm4vProcessor (GLM-4.1V) needs the
# split-video path because it uses image_token_id as the video
# placeholder. The direct path requires transformers >= 5.5.0
# (Glm46VProcessor / GlmgaVideoProcessor support).
use_direct_path = (
not isinstance(processor, Glm4vProcessor) and TRANSFORMERS_WITH_GA
)
if use_direct_path:
prepared_data, prepared_kwargs = self._get_direct_path_inputs(
mm_data, mm_kwargs
)
return super()._call_hf_processor(
prompt=prompt,
mm_data=prepared_data,
mm_kwargs=prepared_kwargs,
tok_kwargs=tok_kwargs,
)
if (
"videos" in mm_data
and isinstance(mm_data["videos"], list)
and len(mm_data["videos"]) > 0
):
video_grid_thw_lst = []
pixel_values_videos_lst = []
for item in mm_data.pop("videos", []):
video_array, metadata = item
# don't update mm_kwargs inplace
video_mm_kwargs = dict(**mm_kwargs)
video_mm_kwargs["do_sample_frames"] = metadata.get(
"do_sample_frames", True
)
video_mm_data = dict()
video_mm_data["videos"] = [[video_array]]
video_mm_data["video_metadata"] = [[_to_video_metadata(metadata)]]
video_outputs = super()._call_hf_processor(
prompt="<|begin_of_video|><|video|><|end_of_video|>",
mm_data=video_mm_data,
mm_kwargs=video_mm_kwargs,
tok_kwargs=tok_kwargs,
)
input_ids = video_outputs.pop("input_ids")
input_ids[input_ids == processor.image_token_id] = (
processor.video_token_id
)
video_placeholder = processor.tokenizer.batch_decode(input_ids)[0]
prompt = prompt.replace(
"<|begin_of_video|><|video|><|end_of_video|>",
video_placeholder,
1,
)
video_grid_thw_lst.append(video_outputs["video_grid_thw"])
pixel_values_videos_lst.append(video_outputs["pixel_values_videos"])
video_outputs = dict(
pixel_values_videos=torch.cat(pixel_values_videos_lst),
video_grid_thw=torch.cat(video_grid_thw_lst),
)
else:
video_outputs = dict()
processed_outputs = super()._call_hf_processor(
prompt=prompt,
mm_data=mm_data,
mm_kwargs=mm_kwargs,
tok_kwargs=tok_kwargs,
)
combined_outputs = dict(
processed_outputs,
**video_outputs,
)
return BatchFeature(combined_outputs)
def _get_mm_fields_config(
self,
hf_inputs: BatchFeature,
hf_processor_mm_kwargs: Mapping[str, object],
) -> Mapping[str, MultiModalFieldConfig]:
return _create_qwen2vl_field_factory(
self.info.get_hf_config().vision_config.spatial_merge_size
)(hf_inputs)
def _get_prompt_updates(
self,
mm_items: MultiModalDataItems,
hf_processor_mm_kwargs: Mapping[str, Any],
out_mm_kwargs: MultiModalKwargsItems,
) -> Sequence[PromptUpdate]:
hf_processor = self.info.get_hf_processor(**hf_processor_mm_kwargs)
image_processor = self.info.get_image_processor(**hf_processor_mm_kwargs)
merge_length = image_processor.merge_size**2
def get_image_replacement_glm4v(item_idx: int):
out_item = out_mm_kwargs["image"][item_idx]
grid_thw = out_item["image_grid_thw"].data
assert isinstance(grid_thw, torch.Tensor)
num_tokens = int(grid_thw.prod()) // merge_length
return [hf_processor.image_token_id] * num_tokens
def get_video_replacement_glm4v(item_idx: int):
out_item = out_mm_kwargs["video"][item_idx]
grid_thw = out_item["video_grid_thw"].data
assert isinstance(grid_thw, torch.Tensor)
video, metadata = mm_items["video"][item_idx]
placeholder = self.info._construct_video_placeholder(
video, metadata, grid_thw
)
return PromptUpdateDetails.select_token_id(
placeholder,
embed_token_id=hf_processor.video_token_id,
)
def get_video_replacement_glm46v(item_idx: int):
out_item = out_mm_kwargs["video"][item_idx]
grid_thw = out_item["video_grid_thw"].data
assert isinstance(grid_thw, torch.Tensor)
video, metadata = mm_items["video"][item_idx]
placeholder = self.info._construct_video_placeholder(
video, metadata, grid_thw
)
return PromptUpdateDetails.select_token_id(
placeholder,
embed_token_id=hf_processor.image_token_id,
)
is_glm46v = not isinstance(hf_processor, Glm4vProcessor)
return [
PromptReplacement(
modality="image",
target=hf_processor.image_token,
replacement=get_image_replacement_glm4v,
),
PromptReplacement(
modality="video",
target="<|begin_of_video|><|video|><|end_of_video|>",
replacement=(
get_video_replacement_glm46v
if is_glm46v and TRANSFORMERS_WITH_GA
else get_video_replacement_glm4v
),
),
]
@MULTIMODAL_REGISTRY.register_processor(
Glm4vMultiModalProcessor,
info=Glm4vProcessingInfo,
dummy_inputs=Glm4vDummyInputsBuilder,
)
class Glm4vForConditionalGeneration(
nn.Module,
SupportsMultiModal,
SupportsEncoderCudaGraph,
SupportsLoRA,
SupportsPP,
SupportsMRoPE,
):
packed_modules_mapping = {
"qkv_proj": [
"q_proj",
"k_proj",
"v_proj",
],
"gate_up_proj": ["gate_up_proj"],
}
# To ensure correct weight loading and mapping.
hf_to_vllm_mapper = WeightsMapper(
orig_to_new_prefix={
"lm_head.": "language_model.lm_head.",
"model.language_model.": "language_model.model.",
"model.visual.": "visual.",
}
)
supports_encoder_tp_data = True
@classmethod
def get_placeholder_str(cls, modality: str, i: int) -> str | None:
if modality.startswith("image"):
return "<|begin_of_image|><|image|><|end_of_image|>"
if modality.startswith("video"):
return "<|begin_of_video|><|video|><|end_of_video|>"
raise ValueError("Only image or video modality is supported")
def __init__(self, *, vllm_config: VllmConfig, prefix: str = ""):
super().__init__()
config = vllm_config.model_config.hf_config
quant_config = vllm_config.quant_config
multimodal_config = vllm_config.model_config.multimodal_config
self.config = config
self.model_config = vllm_config.model_config
self.multimodal_config = multimodal_config
self.use_data_parallel = multimodal_config.mm_encoder_tp_mode == "data"
self.is_multimodal_pruning_enabled = (
multimodal_config.is_multimodal_pruning_enabled()
)
with self._mark_tower_model(vllm_config, {"image", "video"}):
self.visual = Glm4vVisionTransformer(
config.text_config,
config.vision_config,
norm_eps=getattr(config, "rms_norm_eps", 1e-5),
quant_config=quant_config,
prefix=maybe_prefix(prefix, "visual"),
)
if config.model_type in ("glm4v", "glm_ocr", "glmga"):
architectures = ["Glm4ForCausalLM"]
elif config.model_type == "glm4v_moe":
architectures = ["Glm4MoeForCausalLM"]
else:
architectures = None
with self._mark_language_model(vllm_config):
self.language_model = init_vllm_registered_model(
vllm_config=vllm_config,
hf_config=config.text_config,
prefix=maybe_prefix(prefix, "language_model"),
architectures=architectures,
)
self.make_empty_intermediate_tensors = (
self.language_model.make_empty_intermediate_tensors
)
def _parse_and_validate_image_input(
self, **kwargs: object
) -> Glm4vImageInputs | None:
pixel_values = kwargs.pop("pixel_values", None)
image_embeds = kwargs.pop("image_embeds", None)
image_grid_thw = kwargs.pop("image_grid_thw", None)
if pixel_values is None and image_embeds is None:
return None
if pixel_values is not None:
return Glm4vImagePixelInputs(
type="pixel_values",
pixel_values=pixel_values,
image_grid_thw=image_grid_thw,
)
if image_embeds is not None:
return Glm4vImageEmbeddingInputs(
type="image_embeds",
image_embeds=image_embeds,
image_grid_thw=image_grid_thw,
)
def _parse_and_validate_video_input(
self, **kwargs: object
) -> Glm4vVideoInputs | None:
pixel_values_videos = kwargs.pop("pixel_values_videos", None)
video_embeds = kwargs.pop("video_embeds", None)
video_grid_thw = kwargs.pop("video_grid_thw", None)
if pixel_values_videos is None and video_embeds is None:
return None
if pixel_values_videos is not None:
return Glm4vVideoPixelInputs(
type="pixel_values_videos",
pixel_values_videos=pixel_values_videos,
video_grid_thw=video_grid_thw,
)
if video_embeds is not None:
return Glm4vVideoEmbeddingInputs(
type="video_embeds",
video_embeds=video_embeds,
video_grid_thw=video_grid_thw,
)
def _process_image_input(
self, image_input: Glm4vImageInputs
) -> tuple[torch.Tensor, ...]:
grid_thw = image_input["image_grid_thw"]
assert grid_thw.ndim == 2
if image_input["type"] == "image_embeds":
image_embeds = image_input["image_embeds"].type(self.visual.dtype)
else:
pixel_values = image_input["pixel_values"].type(self.visual.dtype)
if self.use_data_parallel:
return run_dp_sharded_mrope_vision_model(
self.visual, pixel_values, grid_thw.tolist(), rope_type="rope_3d"
)
else:
image_embeds = self.visual(pixel_values, grid_thw=grid_thw)
merge_size = self.visual.spatial_merge_size
sizes = (grid_thw.prod(-1) // merge_size // merge_size).tolist()
return image_embeds.split(sizes)
def _process_video_input(
self, video_input: Glm4vVideoInputs
) -> tuple[torch.Tensor, ...]:
grid_thw = video_input["video_grid_thw"]
assert grid_thw.ndim == 2
if video_input["type"] == "video_embeds":
video_embeds = video_input["video_embeds"].type(self.visual.dtype)
else:
pixel_values_videos = video_input["pixel_values_videos"].type(
self.visual.dtype
)
if self.use_data_parallel:
return run_dp_sharded_mrope_vision_model(
self.visual,
pixel_values_videos,
grid_thw.tolist(),
rope_type="rope_3d",
)
else:
video_embeds = self.visual(pixel_values_videos, grid_thw=grid_thw)
# Split concatenated embeddings for each video item.
merge_size = self.visual.spatial_merge_size
sizes = (grid_thw.prod(-1) // merge_size // merge_size).tolist()
return video_embeds.split(sizes)
# -- SupportsEncoderCudaGraph protocol methods --
def get_encoder_cudagraph_config(self):
from vllm.v1.worker.encoder_cudagraph_defs import (
EncoderCudaGraphConfig,
)
# When EVS pruning is enabled, embed_multimodal post-processes both
# image and video embeddings (mrope positions are appended for image,
# prune+append for video). The encoder CUDA graph path bypasses that
# post-process, producing inconsistent embedding formats vs eager. So
# disable CUDA graph for all modalities when pruning is on.
modalities = [] if self.is_multimodal_pruning_enabled else ["image", "video"]
# Compute max_frames_per_video for budget sizing.
max_frames = self.get_max_frames_per_video() if "video" in modalities else 1
return EncoderCudaGraphConfig(
modalities=modalities,
buffer_keys=[
"pixel_values",
"pos_embeds",
"rotary_pos_emb_cos",
"rotary_pos_emb_sin",
"cu_seqlens",
"max_seqlen",
"sequence_lengths",
],
out_hidden_size=self.visual.out_hidden_size,
max_frames_per_video=max_frames,
)
def get_input_modality(
self,
mm_kwargs: dict[str, Any],
) -> str:
if "image_grid_thw" in mm_kwargs:
return "image"
elif "video_grid_thw" in mm_kwargs:
return "video"
raise AssertionError("This line should be unreachable.")
def get_max_frames_per_video(self) -> int:
mm_registry = MULTIMODAL_REGISTRY
info = mm_registry.get_processing_info(self.model_config)
max_frames_per_video = info.get_num_frames_with_most_features(
seq_len=self.model_config.max_model_len,
mm_counts={"video": self.multimodal_config.get_limit_per_prompt("video")},
)
# Small 'max_frames_per_video' will cause 'tensor mismatch' in PR#43403
# 16 is the default 'num_frames' of '_get_vision_info'
return max(max_frames_per_video, 16)
def get_encoder_cudagraph_budget_range(
self,
vllm_config,
) -> tuple[int, int]:
# Min: estimated smallest possible encoder input.
# 224x224 image → 16x16 patches (patch_size=14)
# spatial_merge_size=2 → 8x8 = 64 tokens
min_budget = 64
# Max: capped by max_num_batched_tokens
max_budget = min(
vllm_config.scheduler_config.max_num_batched_tokens,
vllm_config.model_config.max_model_len,
)
return (min_budget, max_budget)
def _get_pixel_values_by_modality(
self,
mm_kwargs: dict[str, Any],
) -> torch.Tensor:
if self.get_input_modality(mm_kwargs) == "image":
pixel_values = mm_kwargs["pixel_values"]
else:
pixel_values = mm_kwargs["pixel_values_videos"]
return pixel_values
def _get_grid_thw_by_modality(
self,
mm_kwargs: dict[str, Any],
) -> list[tuple[int, int, int]]:
grid_thw_key = f"{self.get_input_modality(mm_kwargs)}_grid_thw"
grid_thw = mm_kwargs[grid_thw_key]
if not isinstance(grid_thw, list):
grid_thw = grid_thw.tolist()
return grid_thw
def get_encoder_cudagraph_item_specs(
self,
mm_kwargs: dict[str, Any],
):
from vllm.v1.worker.encoder_cudagraph_defs import EncoderItemSpec
m = self.visual.spatial_merge_size
grid_thw = self._get_grid_thw_by_modality(mm_kwargs)
return [
EncoderItemSpec(
input_size=t * h * w,
output_tokens=t * (h // m) * (w // m),
)
for t, h, w in grid_thw
]
def select_encoder_cudagraph_items(
self,
mm_kwargs: dict[str, Any],
indices: list[int],
) -> dict[str, Any]:
grid_thw = self._get_grid_thw_by_modality(mm_kwargs)
pixel_values = self._get_pixel_values_by_modality(mm_kwargs)
if len(indices) == 0:
if self.get_input_modality(mm_kwargs) == "image":
return {
"pixel_values": pixel_values[:0],
"image_grid_thw": [],
}
else:
return {
"pixel_values_videos": pixel_values[:0],
"video_grid_thw": [],
}
# Compute cumulative patch offsets for slicing pixel_values
patches_per_item = [t * h * w for t, h, w in grid_thw]
cum_patches = [0]
for p in patches_per_item:
cum_patches.append(cum_patches[-1] + p)
selected_pv = torch.cat(
[pixel_values[cum_patches[i] : cum_patches[i + 1]] for i in indices]
)
selected_grid = [grid_thw[i] for i in indices]
if self.get_input_modality(mm_kwargs) == "image":
return {
"pixel_values": selected_pv,
"image_grid_thw": selected_grid,
}
else:
return {
"pixel_values_videos": selected_pv,
"video_grid_thw": selected_grid,
}
def prepare_encoder_cudagraph_capture_inputs(
self,
token_budget: int,
max_batch_size: int,
max_frames_per_batch: int,
device: torch.device,
dtype: torch.dtype,
path: str = "default",
):
from vllm.v1.worker.encoder_cudagraph_defs import (
EncoderCudaGraphCaptureInputs,
)
spatial_merge_size = self.visual.spatial_merge_size
per_mm_item_output = token_budget // max_batch_size
frames_per_item = max_frames_per_batch // max_batch_size
if frames_per_item > 1:
# Build the capture grid using a video-format layout so that
# cu_seqlens is sized for video replays from the start.
# cu_seqlens has one entry per attention sequence (one per frame),
# so using T > 1 per item makes the buffer large enough without
# relying solely on padding.
# Ceiling ensures frames_per_item * tokens_per_frame >= per_mm_item_output
# so the pixel_values buffer covers any valid single-item replay.
tokens_per_frame = (
per_mm_item_output + frames_per_item - 1
) // frames_per_item
# Video-format grid_config (T=frames_per_item).
grid_config = [
[
frames_per_item,
spatial_merge_size,
tokens_per_frame * spatial_merge_size,
]
for _ in range(max_batch_size)
]
else:
# Image-format grid_config (T=1).
grid_config = [
[1, spatial_merge_size, per_mm_item_output * spatial_merge_size]
for _ in range(max_batch_size)
]
# Create dummy pixel_values
patch_embed = self.visual.patch_embed
in_channels = patch_embed.proj.in_channels
patch_size = patch_embed.patch_size
temporal_patch_size = patch_embed.temporal_patch_size
total_patches = sum(t * h * w for t, h, w in grid_config)
flattened_patch_size = (
in_channels * temporal_patch_size * patch_size * patch_size
)
dummy_pixel_values = torch.randn(
total_patches, flattened_patch_size, device=device, dtype=dtype
)
# Override max_seqlen with a safe upper bound for capture.
# max_seqlen.item() gets baked into the CUDA graph (not replayed),
# so the capture value must cover any replay scenario.
# Worst case: 1 item consuming the full budget ->
# seq_len = token_budget * spatial_merge_size^2.
metadata = self.visual.prepare_encoder_metadata(
grid_config,
max_batch_size=max_batch_size,
max_frames_per_batch=max_frames_per_batch,
max_seqlen_override=token_budget * (spatial_merge_size**2),
device=device,
)
# Just use image-modality dummy input_buffer for capturing, since it's also
# compatible for video inputs (has the same shape: [num_patches, C*T*P*P]).
values = metadata | {
"pixel_values": dummy_pixel_values,
}
return EncoderCudaGraphCaptureInputs(
values=values,
)
def prepare_encoder_cudagraph_replay_buffers(
self,
mm_kwargs: dict[str, Any],
max_batch_size: int,
max_frames_per_batch: int,
path: str = "default",
):
modality = self.get_input_modality(mm_kwargs)
grid_thw_list = self._get_grid_thw_by_modality(mm_kwargs)
if modality == "image":
metadata = self.visual.prepare_encoder_metadata(
grid_thw_list,
max_batch_size=max_batch_size,
)
elif modality == "video":
metadata = self.visual.prepare_encoder_metadata(
grid_thw_list,
max_frames_per_batch=max_frames_per_batch,
)
else:
raise AssertionError("This line should be unreachable.")
values = metadata | {
"pixel_values": self._get_pixel_values_by_modality(mm_kwargs),
}
return EncoderCudaGraphReplayBuffers(values=values)
def encoder_cudagraph_forward(
self,
values: dict[str, torch.Tensor],
path: str = "default",
) -> torch.Tensor:
pixel_values = values.pop("pixel_values")
metadata = values
return self.visual(pixel_values, None, encoder_metadata=metadata)
def encoder_eager_forward(
self,
mm_kwargs: dict[str, Any],
path: str = "default",
) -> torch.Tensor:
pixel_values = self._get_pixel_values_by_modality(mm_kwargs)
grid_thw = self._get_grid_thw_by_modality(mm_kwargs)
return self.visual(pixel_values, grid_thw)
def _parse_and_validate_multimodal_inputs(self, **kwargs: object) -> dict:
mm_input_by_modality = {}
# Preserve the order of modalities if there are multiple of them
# from the order of kwargs.
for input_key in kwargs:
if (
input_key in ("pixel_values", "image_embeds")
and "image" not in mm_input_by_modality
):
mm_input_by_modality["image"] = self._parse_and_validate_image_input(
**kwargs
)
if (
input_key in ("pixel_values_videos", "video_embeds")
and "video" not in mm_input_by_modality
):
mm_input_by_modality["video"] = self._parse_and_validate_video_input(
**kwargs
)
return mm_input_by_modality
def embed_multimodal(self, **kwargs: object) -> MultiModalEmbeddings | None:
mm_input_by_modality = self._parse_and_validate_multimodal_inputs(**kwargs)
if not mm_input_by_modality:
return None
# The result multimodal_embeddings is tuple of tensors, with each
# tensor corresponding to a multimodal data item (image or video).
multimodal_embeddings: tuple[torch.Tensor, ...] = ()
# NOTE: It is important to iterate over the keys in this dictionary
# to preserve the order of the modalities.
for modality in mm_input_by_modality:
multimodal_input = mm_input_by_modality[modality]
if modality == "image":
image_embeddings = self._process_image_input(multimodal_input)
multimodal_embeddings += tuple(image_embeddings)
if modality == "video":
video_embeddings = self._process_video_input(multimodal_input)
multimodal_embeddings += tuple(video_embeddings)
return multimodal_embeddings
def iter_mm_grid_thw(
self, mm_features: list[MultiModalFeatureSpec]
) -> Iterator[tuple[int, int, int, int]]:
hf_config = self.config
spatial_merge_size = hf_config.vision_config.spatial_merge_size
for mm_feature in sorted(mm_features, key=lambda f: f.mm_position.offset):
embed_ranges = mm_feature.mm_position.extract_embeds_range()
if mm_feature.modality == "image":
t, h, w = mm_feature.data["image_grid_thw"].data.tolist()
assert t == 1, f"Image must have 1 frame, got {t}"
assert len(embed_ranges) == 1
offset, end = embed_ranges[0]
assert end - offset + 1 == h * w // spatial_merge_size**2
yield offset, t, h // spatial_merge_size, w // spatial_merge_size
elif mm_feature.modality == "video":
t, h, w = mm_feature.data["video_grid_thw"].data.tolist()
llm_grid_h = h // spatial_merge_size
llm_grid_w = w // spatial_merge_size
num_tokens_per_frame = llm_grid_h * llm_grid_w
if len(embed_ranges) == t:
for offset, end in embed_ranges:
assert end - offset + 1 == num_tokens_per_frame
yield offset, 1, llm_grid_h, llm_grid_w
else:
offset = mm_feature.mm_position.offset
yield offset, t, llm_grid_h, llm_grid_w
else:
raise ValueError(f"Unsupported modality: {mm_feature.modality}")
def get_mrope_input_positions(
self,
input_tokens: list[int],
mm_features: list[MultiModalFeatureSpec],
) -> tuple[torch.Tensor, int]:
llm_pos_ids_list: list = []
st = 0
for (
offset,
llm_grid_t,
llm_grid_h,
llm_grid_w,
) in self.iter_mm_grid_thw(mm_features):
text_len = offset - st
st_idx = llm_pos_ids_list[-1].max() + 1 if len(llm_pos_ids_list) > 0 else 0
llm_pos_ids_list.append(
np.broadcast_to(np.arange(text_len), (3, text_len)) + st_idx
)
grid_indices = np.indices((llm_grid_t, llm_grid_h, llm_grid_w)).reshape(
3, -1
)
llm_pos_ids_list.append(grid_indices + text_len + st_idx)
st = offset + llm_grid_t * llm_grid_h * llm_grid_w
if st < len(input_tokens):
text_len = len(input_tokens) - st
st_idx = llm_pos_ids_list[-1].max() + 1 if len(llm_pos_ids_list) > 0 else 0
llm_pos_ids_list.append(
np.broadcast_to(np.arange(text_len), (3, text_len)) + st_idx
)
llm_positions = np.concatenate(llm_pos_ids_list, axis=1).reshape(3, -1)
mrope_position_delta = (llm_positions.max() + 1 - len(input_tokens)).item()
return torch.from_numpy(llm_positions), mrope_position_delta
def forward(
self,
input_ids: torch.Tensor | None,
positions: torch.Tensor,
intermediate_tensors: IntermediateTensors | None = None,
inputs_embeds: torch.Tensor | None = None,
**kwargs: object,
) -> torch.Tensor | IntermediateTensors:
"""Run forward pass for GLM-4V.
Args:
input_ids: Flattened (concatenated) input_ids corresponding to a
batch.
positions: Flattened (concatenated) position ids corresponding to a
batch.
**NOTE**: If mrope is enabled (default setting for GLM-4V
opensource models), the shape will be `(3, seq_len)`,
otherwise it will be `(seq_len,).
intermediate_tensors: Optional intermediate tensors for pipeline
parallelism.
inputs_embeds: Optional pre-computed input embeddings.
**kwargs: Additional keyword arguments.
"""
if intermediate_tensors is not None:
inputs_embeds = None
hidden_states = self.language_model.model(
input_ids=input_ids,
positions=positions,
intermediate_tensors=intermediate_tensors,
inputs_embeds=inputs_embeds,
)
return hidden_states
def compute_logits(
self,
hidden_states: torch.Tensor,
) -> torch.Tensor | None:
return self.language_model.compute_logits(hidden_states)
def load_weights(self, weights: Iterable[tuple[str, torch.Tensor]]) -> set[str]:
loader = AutoWeightsLoader(self)
return loader.load_weights(weights, mapper=self.hf_to_vllm_mapper)
def get_mm_mapping(self) -> MultiModelKeys:
"""
Get the module prefix in multimodal models
"""
return MultiModelKeys.from_string_field(
language_model="language_model.model",
connector="visual.merger.",
tower_model="visual.",
)
def get_num_mm_encoder_tokens(
self,
num_image_tokens: int,
) -> int:
merge_size = self.config.vision_config.spatial_merge_size
return num_image_tokens * (merge_size**2)
def get_num_mm_connector_tokens(
self,
num_vision_tokens: int,
) -> int:
merge_size = self.config.vision_config.spatial_merge_size
return num_vision_tokens // (merge_size**2)
@MULTIMODAL_REGISTRY.register_processor(
Glm4vMultiModalProcessor,
info=Glm4vProcessingInfo,
dummy_inputs=Glm4vDummyInputsBuilder,
)
class Glm4vMoeForConditionalGeneration(Glm4vForConditionalGeneration):
packed_modules_mapping = {
"qkv_proj": [
"q_proj",
"k_proj",
"v_proj",
],
"gate_up_proj": [
"gate_proj",
"up_proj",
],
}