InternVL3_5-1B-Pretrained

[📂 GitHub] [📜 InternVL 1.0] [📜 InternVL 1.5] [📜 InternVL 2.5] [📜 InternVL2.5-MPO] [📜 InternVL3] [📜 InternVL3.5]

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Introduction

We introduce InternVL3.5, a new family of open-source multimodal models that significantly advances versatility, reasoning capability, and inference efficiency along the InternVL series. A key innovation is the Cascade Reinforcement Learning (Cascade RL) framework, which enhances reasoning through a two-stage process: offline RL for stable convergence and online RL for refined alignment. This coarse-to-fine training strategy leads to substantial improvements on downstream reasoning tasks, e.g., MMMU and MathVista. To optimize efficiency, we propose a Visual Resolution Router (ViR) that dynamically adjusts the resolution of visual tokens without compromising performance. Coupled with ViR, our Decoupled Vision-Language Deployment (DvD) strategy separates the vision encoder and language model across different GPUs, effectively balancing computational load. These contributions collectively enable InternVL3.5 to achieve up to a +16.0% gain in overall reasoning performance and a 4.05 $\times \backslash times$ inference speedup compared to its predecessor, i.e., InternVL3. In addition, InternVL3.5 supports novel capabilities such as GUI interaction and embodied agency. Notably, our largest model, i.e., InternVL3.5-241B-A28B, attains state-of-the-art results among open-source MLLMs across general multimodal, reasoning, text, and agentic tasks—narrowing the performance gap with leading commercial models like GPT-5. All models and code are publicly released.

Hatched bars represent closed-source commercial models. We report average scores on a set of multimodal general, reasoning, text, and agentic benchmarks: MMBench v1.1 (en), MMStar,BLINK, HallusionBench, AI2D, OCRBench, MMVet, MME-RealWorld (en), MVBench, VideoMME, MMMU, MathVista, MathVision, MathVerse, DynaMath, WeMath, LogicVista, MATH500, AIME24, AIME25, GPQA, MMLU-Pro, GAOKAO, IFEval, SGP-Bench, VSI-Bench, ERQA, SpaCE-10, and OmniSpatial.

See quick start for how to use our model.

InternVL3.5 Family

In the following table, we provide an overview of the InternVL3.5 series. To maintain consistency with earlier generations, we provide two model formats: the GitHub format, consistent with prior releases, and the HF format, aligned with the official Transformers standard.

If you want to convert the checkpoint between these two formats, please refer to the scripts about custom2hf and hf2custom.

Model	#Vision Param	#Language Param	#Total Param	HF Link	ModelScope Link
InternVL3.5-1B	0.3B	0.8B	1.1B	🤗 link	🤖 link
InternVL3.5-2B	0.3B	2.0B	2.3B	🤗 link	🤖 link
InternVL3.5-4B	0.3B	4.4B	4.7B	🤗 link	🤖 link
InternVL3.5-8B	0.3B	8.2B	8.5B	🤗 link	🤖 link
InternVL3.5-14B	0.3B	14.8B	15.1B	🤗 link	🤖 link
InternVL3.5-38B	5.5B	32.8B	38.4B	🤗 link	🤖 link
InternVL3.5-20B-A4B	0.3B	20.9B	21.2B-A4B	🤗 link	🤖 link
InternVL3.5-30B-A3B	0.3B	30.5B	30.8B-A3B	🤗 link	🤖 link
InternVL3.5-241B-A28B	5.5B	235.1B	240.7B-A29B	🤗 link	🤖 link

We conduct the evaluation with VLMEvalkit. To enable the Thinking mode of our model, please set the system prompt to R1_SYSTEM_PROMPT. When enabling Thinking mode, we recommend setting do_sample=True and temperature=0.6 to mitigate undesired repetition.

Our training pipeline comprises four stages: Multimodal Continual Pre-Training (CPT), Supervised Fine-Tuning (SFT), and Cascade Reinforcement Learning (CascadeRL). In CascadeRL, we first fine-tune the model using Mixed Preference Optimization (MPO) under an offline RL setting, followed by GSPO under an oneline RL setting. For the Flash version of InternVL3.5, we additionally introduce a lightweight training stage, termed Visual Consistency Learning (ViCO), which reduces the token cost required to represent an image patch.

Here, we also open-source the model weights after different training stages for potential research usage. If you're unsure which version to use, please select the one without any suffix, as it has completed the full training pipeline.

Model	Training Pipeline	HF Link	ModelScope Link
InternVL3.5-1B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-1B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-1B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-1B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-2B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-2B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-2B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-2B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-4B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-4B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-4B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-4B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-8B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-8B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-8B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-8B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-14B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-14B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-14B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-14B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-30B-A3B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-30B-A3B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-30B-A3B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-30B-A3B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-38B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-38B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-38B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-38B	CPT + SFT + CascadeRL	🤗 link	🤖 link
InternVL3.5-241B-A28B-Pretrained	CPT	🤗 link	🤖 link
InternVL3.5-241B-A28B-Instruct	CPT + SFT	🤗 link	🤖 link
InternVL3.5-241B-A28B-MPO	CPT + SFT + MPO	🤗 link	🤖 link
InternVL3.5-241B-A28B	CPT + SFT + CascadeRL	🤗 link	🤖 link

The Flash version of our model will be released as soon as possible.

Model Architecture

InternVL3.5: This series of models follow the "ViT–MLP–LLM" paradigm adopted in previous versions of InternVL. We initialize the language model using the Qwen3 series and GPT-OSS, and the vision encoder using InternViT-300M and InternViT-6B. The Dynamic High Resolution strategy introduced in InternVL1.5 is also retained in our design.

InternVL3.5-Flash: Compared to InternVL3.5, InternVL3.5-Flash further integrates the Visual Resolution Router (ViR), thus yielding a series of efficient variants friendly suitable for resource-constrained scenarios. Specifically, in InternVL3.5, each image patch is initially represented as 1024 visual tokens for the vision encoder, which are then compressed into 256 tokens via a pixel shuffle module before being passed to the Large Language Model (LLM). In InternVL3.5-Flash, as shown in the Figure below, an additional pixel shuffle module with a higher compression rate is included, enabling the compression of visual tokens down to 64 tokens. For each patch, the patch router determines the appropriate compression rate by assessing its semantic richness, and routes it to the corresponding pixel shuffle module accordingly. Benefiting from this patch-aware compression mechanism, InternVL3.5-Flash is able to reduce the number of visual tokens by 50% while maintaining nearly 100% of the performance of InternVL3.5.

Training and Deployment Strategy

Pre-Training

During the pre-training stage, we update all model parameters jointly using the combination of large-scale text and multimodal corpora. Specifically, given an arbitrary training sample consisting of a multimodal token sequence $\mathbf{x}=(x_1,x_2,\dots ,x_L)\backslash mathbf\{x\}=\backslash left(x\_1,\; x\_2,\; \backslash ldots,\; x\_L\backslash right)$, the next token prediction (NTP) loss is calculated on each text token as follows:

$${\mathcal{L}}_i=-\log p_{\theta }(x_i\mid x_1,\dots ,x_{i-1}),\backslash mathcal\{L\}\_\{i\}=-\backslash log\; p\_\backslash theta\backslash left(x\_i\; \backslash mid\; x\_1,\; \backslash ldots,\; x\_\{i-1\}\backslash right),$$

where $x_{i}x\_i$ is the predicted token and prefix tokens in $\{x_1,x_2,\dots ,x_{i-1}\}\backslash \{x\_1,\; x\_2,\; \backslash ldots,\; x\_\{i-1\}\backslash \}$ can be either text tokens or image tokens. Notably, for conversation samples, only response tokens are included for the calculation of the loss. Additionally, to mitigate bias toward either longer or shorter responses during training, we adopt the square averaging to re-weight the NTP loss as follows:

$${\mathcal{L}}_i^{{}^{\mathrm{\prime }}}=\frac{w_i}{\sum _j{w}_j}\cdot {\mathcal{L}}_i,w_i=\frac{1}{N^{0.5}},\backslash mathcal\{L\}\_\{i\}^\{\text{'}\}\; =\; \backslash frac\{w\_i\}\{\backslash sum\_j\; w\_j\}\; \backslash cdot\; \backslash mathcal\{L\}\_i,\; \backslash quad\; w\_i\; =\; \backslash frac\{1\}\{N^\{0.5\}\},$$

where $NN$ denotes the number of tokens in the training sample on which the loss needs to be calculated. The random JPEG compression is also included to enhance the model's real-world performance.

Supervised Fine-Tuning

During the SFT phase, we adopt the same objective as in the pre-training stage and use the square-root averaging strategy to calculate the final loss. In this stage, the context window is set to 32K tokens to adapt long-context information. Compared to InternVL3, the SFT stage of InternVL3.5 contains more high-quality and diverse training data derived from three sources:

(1) Instruction-following data from InternVL3, which are reused to preserve broad coverage of vision–language tasks.

(2) Multimodal reasoning data in the "Thinking" mode, which are included to instill long-thinking capabilities in the model. To construct such data, we first use InternVL3-78B to describe the image and then input the description into DeepSeek-R1 to sample rollouts with detailed reasoning processes. Rollouts with an incorrect final answer are filtered out. The questions in these datasets cover various expert domains, such as mathematics and scientific disciplines, thereby strengthening performance on different reasoning tasks.

(3) Capability-expansion datasets, which endow InternVL3.5 with new skills, including GUI-based interaction, embodied interaction, and scalable vect

Cascade Reinforcement Learning

Cascade RL aims to combine the benefits of offline RL and online RL to progressively facilitate the post-training of MLLMs in an efficient manner. Specifically, we first fine-tune the model using an offline RL algorithm as an efficient warm-up stage to reach a satisfied results, which can guarantee the high-quality rollouts for the latter stage. Subsequently, we employ an online RL algorithm to further refine the output distribution based on rollouts generated by the model itself. Compared to the single offline or online RL stage, our cascaded RL achieves significant performance improvements at a fraction of the GPU time cost.

During the offline RL stage, we employ mixed preference optimization (MPO) to fine-tune the model. Specifically, the training objective of MPO is a combination of preference loss ${\mathcal{L}}_p\backslash mathcal\{L\}\_\{p\}$, quality loss ${\mathcal{L}}_q\backslash mathcal\{L\}\_\{q\}$, and generation loss ${\mathcal{L}}_g\backslash mathcal\{L\}\_\{g\}$, which can be formulated as follows:

$${\mathcal{L}}_{\text{MPO}}=w_p{\mathcal{L}}_p+w_q{\mathcal{L}}_q+w_g{\mathcal{L}}_g,\backslash mathcal\{L\}\_\{\backslash text\{MPO\}\}=\; w\_\{p\}\; \backslash mathcal\{L\}\_\{p\}\; +\; w\_\{q\}\; \backslash mathcal\{L\}\_\{q\}\; +\; w\_\{g\}\; \backslash mathcal\{L\}\_\{g\}\; ,$$

where $w_{\ast }w\_\{*\}$ represents the weight assigned to each loss component. The DPO loss, BCO loss, and LM loss serve as the preference loss, quality loss, and generation loss, respectively.

During the online RL stage, we employ GSPO, without reference model constraints, as our online RL algorithm, which we find more effective in training both dense and mixture-of-experts (MoE) models. Similar to GRPO, the advantage is defined as the normalized reward across responses sampled from the same query. The training objective of GSPO is given by:

$${\mathcal{L}}_{\mathrm{G}\mathrm{S}\mathrm{P}\mathrm{O}}(\theta )={\mathbb{E}}_{x\sim \mathcal{D},{\left\{y_i\right\}}_{i=1}^G\sim {\pi }_{\theta \text{ old }}(\cdot \mid x)}[\frac{1}{G}\sum _{i=1}^G\min (s_i(\theta ){\widehat{A}}_i,\mathrm{clip}(s_i(\theta ),1-\epsilon ,1+\epsilon ){\widehat{A}}_i)],\backslash mathcal\{L\}\_\{\backslash mathrm\{GSPO\}\}(\backslash theta)=\backslash mathbb\{E\}\_\{x\; \backslash sim\; \backslash mathcal\{D\},\backslash left\backslash \{y\_i\backslash right\backslash \}\_\{i=1\}^G\; \backslash sim\; \backslash pi\_\{\backslash theta\; \backslash text\; \{\; old\; \}\}(\backslash cdot\; \backslash mid\; x)\}\backslash left[\backslash frac\{1\}\{G\}\; \backslash sum\_\{i=1\}^G\; \backslash min\; \backslash left(s\_i(\backslash theta)\; \backslash widehat\{A\}\_i,\; \backslash operatorname\{clip\}\backslash left(s\_i(\backslash theta),\; 1-\backslash varepsilon,\; 1+\backslash varepsilon\backslash right)\; \backslash widehat\{A\}\_i\backslash right)\backslash right],$$

where the importance sampling ratio is defined as the geometric mean of the per-token ratios.

Please see our paper for more technical and experimental details.

Visual Consistency Learning

We further include ViCO as an additional training stage to integrate the visual resolution router (ViR) into InternVL3.5, thereby reducing the inference cost of InternVL3.5. The obtained efficient version of InternVL3.5 are termed as InternVL3.5-Flash. In particular, ViCO comprises two stages:

Consistency training: In this stage, the entire model is trained to minimize the divergence between response distributions conditioned on visual tokens with different compression rates. In practice, we introduce an extra reference model, which is frozen and initialized with InternVL3.5. Given a sample, each image patch is represented as either 256 or 64 tokens, and the training objective is defined as follows:

where \(\mathrm{KL}) denotes the KL divergence and (\xi) denotes the compression rate, which is uniformly sampled from ({\frac{1}{4},\frac{1}{16}}). The image (I_\xi) is represented as 256 tokens when (\xi=\frac{1}{4}) and 64 tokens when (\xi=\frac{1}{16}). Notably, the reference model always performs inference with (\xi=\frac{1}{4}).

Router training: This stage aims to train the ViR to select an appropriate trade-off resolution for different inputs. ViR is formulated as a binary classifier and trained using standard cross-entropy loss. To construct the route targets, we first compute the KL divergence between the model outputs conditioned on uncompressed visual tokens (i.e., 256 tokens per patch) and those conditioned on compressed visual tokens (i.e., 64 tokens per patch). During this stage, the main MLLM (ViT, MLP and LLM) is kept frozen, and only the ViR is trained. Specifically, we first compute the loss ratio for each patch:

$$r_i=\frac{{\mathcal{L}}_{\text{ViCO}}(y_i\mid I_{\frac{1}{16}})}{{\mathcal{L}}_{\text{ViCO}}(y_i\mid I_{\frac{1}{4}})},r\_i\; =\; \backslash frac\{\backslash mathcal\{L\}\_\backslash text\{ViCO\}\backslash big(y\_i\; \backslash mid\; I\_\{\backslash frac\{1\}\{16\}\}\backslash big)\}\{\backslash mathcal\{L\}\_\backslash text\{ViCO\}\backslash big(y\_i\; \backslash mid\; I\_\{\backslash frac\{1\}\{4\}\}\backslash big)\},$$

which quantifies the relative increase in loss caused by compressing the visual tokens. Based on this ratio, the binary ground-truth label for the patch router is defined as:

where (y_i^{\text{router}}=0) and (y_i^{\text{router}}=1) indicate that the compression rate (\xi) is set to (\tfrac{1}{16}) and (\tfrac{1}{4}), respectively.

Please see our paper for more technical and experimental details.

Test-Time Scaling

Test-time scaling (TTS) has been empirically demonstrated as an effective approach to enhance the reasoning capabilities of LLMs and MLLMs, particularly for complex tasks necessitating multi-step inference. In this work, we implement a comprehensive test-time scaling approach that simultaneously improves reasoning depth (i.e., deep thinking) and breadth (i.e., parallel thinking).

Deep Thinking: By activating the Thinking mode, we guide the model to deliberately engage in step-by-step reasoning (i.e., decomposing complex problems into logical steps and validating intermediate conclusions) prior to generating the final answer. This approach systematically improves the logical structure of solutions for complex problems, particularly those requiring multi-step inference, and enhances reasoning depth.

Parallel Thinking: Following InternVL3, for reasoning tasks, we adopt the Best-of-N (BoN) strategy by employing VisualPRM-v1.1 as the critic model to select the optimal response from multiple reasoning candidates. This approach improves reasoning breadth.

Notably, unless otherwise specified, the experimental results reported in our paper are obtained without applying TTS. Thus far, we have only applied TTS to reasoning benchmarks, since we found that the model already exhibits strong perception and understanding capabilities, and initiating TTS yields no significant improvement.

Decoupled Vision-Language Deployment

In multimodal inference, the vision encoder and language model have distinct computational characteristics. The vision encoder that transforms images into semantic features is highly parallelizable and does not rely on long-term history state. In contrast, the language model adopts the inference in an autoregressive manner, which requires previous states to compute the next one. This sequential property makes the language part more sensitive to memory bandwidth and latency. When MLLMs are deployed online at scale, the vision and language models often block each other, thus incurring additional inference cost. This effect becomes more pronounced with larger vision models or higher-resolution images.

As shown in the Figure above, we propose decoupled vision-language deployment (DvD) to address this issue by separating vision and language processing, with a particular focus on optimizing the prefilling stage. The vision subsystem batches and processes images to produce compact feature embeddings, which are then transmitted to the language subsystem for fusion with the text context prior to decoding. This separation alleviates blocking and brings multimodal prefilling performance closer to that of pure language models. In our system implementation, the ViT and MLP (and ViR for InternVL3.5-Flash) are deployed on the vision server, while the language server executes only the LLM. The communication is unidirectional, transmitting BF16 visual features over TCP, with RDMA optionally employed to achieve higher transmission speed. Vision processing, feature transmission, and language processing are organized into an asynchronous three-stage pipeline, enabling overlapped execution and minimizing pipeline stalls.

DvD increases GPU utilization and processing efficiency on the vision side, while enabling the language server to focus exclusively on the LLM’s prefilling and decoding without being blocked by vision computation. This design leads to improved throughput and responsiveness. Moreover, the architecture supports independent hardware cost optimization for the vision and language modules, and facilitates the seamless integration of new modules without requiring modifications to the language server deployment.

Evaluation on Multimodal Capability

Multimodal Reasoning and Mathematics

OCR, Chart, and Document Understanding

Multi-Image Understanding & Real-World Comprehension

Comprehensive Multimodal Understanding & Multimodal Hallucination Evaluation

Visual Grounding

Multimodal Multilingual Understanding

Video Understanding

GUI Tasks

Embodied Tasks

SVG Tasks

Evaluation on Language Capability

Ablation Study

Cascade Reinforcement Learning

Decoupled Vision-Language Deployment

Quick Start

We provide an example code to run InternVL3.5-8B using transformers. Please note that our models with up to 30B parameters can be deployed on a single A100 GPU, while the 38B model requires two A100 GPUs and the 235B model requires eight A100 GPUs.

In most cases, both LMDeploy and vLLM can be used for model deployment. However, for InternVL3.5-20B-A4B, we recommend using vLLM since lmdeploy has not yet supported GPT-OSS.

Please use transformers>=4.52.1 to ensure the model works normally. For the 20B version of our model, transformers>=4.55.0 is required.

Model Loading

16-bit (bf16 / fp16)

import torch
from transformers import AutoTokenizer, AutoModel
path = "OpenGVLab/InternVL3_5-8B"
model = AutoModel.from_pretrained(
    path,
    torch_dtype=torch.bfloat16,
    low_cpu_mem_usage=True,
    use_flash_attn=True,
    trust_remote_code=True).eval().cuda()

BNB 8-bit Quantization

import torch
from transformers import AutoTokenizer, AutoModel
path = "OpenGVLab/InternVL3_5-8B"
model = AutoModel.from_pretrained(
    path,
    torch_dtype=torch.bfloat16,
    load_in_8bit=True,
    low_cpu_mem_usage=True,
    use_flash_attn=True,
    trust_remote_code=True).eval()

Multiple GPUs

import math
import torch
from transformers import AutoTokenizer, AutoModel

path = "OpenGVLab/InternVL3_5-8B"
model = AutoModel.from_pretrained(
    path,
    torch_dtype=torch.bfloat16,
    low_cpu_mem_usage=True,
    use_flash_attn=True,
    trust_remote_code=True,
    device_map="auto").eval()

Thinking Mode

To enable thinking mode, please set the system prompt to our Thinking System Prompt. When enabling Thinking mode, we recommend setting do_sample=True and temperature=0.6 to mitigate undesired repetition.

R1_SYSTEM_PROMPT = """
You are an AI assistant that rigorously follows this response protocol:

1. First, conduct a detailed analysis of the question. Consider different angles, potential solutions, and reason through the problem step-by-step. Enclose this entire thinking process within <think> and </think> tags.

2. After the thinking section, provide a clear, concise, and direct answer to the user's question. Separate the answer from the think section with a newline.

Ensure that the thinking process is thorough but remains focused on the query. The final answer should be standalone and not reference the thinking section.
""".strip()

model.system_message = R1_SYSTEMP_PROMPT

Inference with Transformers

import math
import numpy as np
import torch
import torchvision.transforms as T
from decord import VideoReader, cpu
from PIL import Image
from torchvision.transforms.functional import InterpolationMode
from transformers import AutoModel, AutoTokenizer

IMAGENET_MEAN = (0.485, 0.456, 0.406)
IMAGENET_STD = (0.229, 0.224, 0.225)

def build_transform(input_size):
    MEAN, STD = IMAGENET_MEAN, IMAGENET_STD
    transform = T.Compose([
        T.Lambda(lambda img: img.convert('RGB') if img.mode != 'RGB' else img),
        T.Resize((input_size, input_size), interpolation=InterpolationMode.BICUBIC),
        T.ToTensor(),
        T.Normalize(mean=MEAN, std=STD)
    ])
    return transform

def find_closest_aspect_ratio(aspect_ratio, target_ratios, width, height, image_size):
    best_ratio_diff = float('inf')
    best_ratio = (1, 1)
    area = width * height
    for ratio in target_ratios:
        target_aspect_ratio = ratio[0] / ratio[1]
        ratio_diff = abs(aspect_ratio - target_aspect_ratio)
        if ratio_diff < best_ratio_diff:
            best_ratio_diff = ratio_diff
            best_ratio = ratio
        elif ratio_diff == best_ratio_diff:
            if area > 0.5 * image_size * image_size * ratio[0] * ratio[1]:
                best_ratio = ratio
    return best_ratio

def dynamic_preprocess(image, min_num=1, max_num=12, image_size=448, use_thumbnail=False):
    orig_width, orig_height = image.size
    aspect_ratio = orig_width / orig_height

    # calculate the existing image aspect ratio
    target_ratios = set(
        (i, j) for n in range(min_num, max_num + 1) for i in range(1, n + 1) for j in range(1, n + 1) if
        i * j <= max_num and i * j >= min_num)
    target_ratios = sorted(target_ratios, key=lambda x: x[0] * x[1])

    # find the closest aspect ratio to the target
    target_aspect_ratio = find_closest_aspect_ratio(
        aspect_ratio, target_ratios, orig_width, orig_height, image_size)

    # calculate the target width and height
    target_width = image_size * target_aspect_ratio[0]
    target_height = image_size * target_aspect_ratio[1]
    blocks = target_aspect_ratio[0] * target_aspect_ratio[1]

    # resize the image
    resized_img = image.resize((target_width, target_height))
    processed_images = []
    for i in range(blocks):
        box = (
            (i % (target_width // image_size)) * image_size,
            (i // (target_width // image_size)) * image_size,
            ((i % (target_width // image_size)) + 1) * image_size,
            ((i // (target_width // image_size)) + 1) * image_size
        )
        # split the image
        split_img = resized_img.crop(box)
        processed_images.append(split_img)
    assert len(processed_images) == blocks
    if use_thumbnail and len(processed_images) != 1:
        thumbnail_img = image.resize((image_size, image_size))
        processed_images.append(thumbnail_img)
    return processed_images

def load_image(image_file, input_size=448, max_num=12):
    image = Image.open(image_file).convert('RGB')
    transform = build_transform(input_size=input_size)
    images = dynamic_preprocess(image, image_size=input_size, use_thumbnail=True, max_num=max_num)
    pixel_values = [transform(image) for image in images]
    pixel_values = torch.stack(pixel_values)
    return pixel_values

path = 'OpenGVLab/InternVL3_5-8B'
model = AutoModel.from_pretrained(
    path,
    torch_dtype=torch.bfloat16,
    load_in_8bit=False,
    low_cpu_mem_usage=True,
    use_flash_attn=True,
    trust_remote_code=True,
    device_map="auto").eval()
tokenizer = AutoTokenizer.from_pretrained(path, trust_remote_code=True, use_fast=False)

# set the max number of tiles in `max_num`
pixel_values = load_image('./examples/image1.jpg', max_num=12).to(torch.bfloat16).cuda()
generation_config = dict(max_new_tokens=1024, do_sample=True)

# pure-text conversation (纯文本对话)
question = 'Hello, who are you?'
response, history = model.chat(tokenizer, None, question, generation_config, history=None, return_history=True)
print(f'User: {question}\nAssistant: {response}')

question = 'Can you tell me a story?'
response, history = model.chat(tokenizer, None, question, generation_config, history=history, return_history=True)
print(f'User: {question}\nAssistant: {response}')

# single-image single-round conversation (单图单轮对话)
question = '<image>\nPlease describe the image shortly.'
response = model.chat(tokenizer, pixel_values, question, generation_config)
print(f'User: {question}\nAssistant: {response}')

# single-image multi-round conversation (单图多轮对话)
question = '<image>\nPlease describe the image in detail.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config, history=None, return_history=True)
print(f'User: {question}\nAssistant: {response}')

question = 'Please write a poem according to the image.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config, history=history, return_history=True)
print(f'User: {question}\nAssistant: {response}')

# multi-image multi-round conversation, combined images (多图多轮对话，拼接图像)
pixel_values1 = load_image('./examples/image1.jpg', max_num=12).to(torch.bfloat16).cuda()
pixel_values2 = load_image('./examples/image2.jpg', max_num=12).to(torch.bfloat16).cuda()
pixel_values = torch.cat((pixel_values1, pixel_values2), dim=0)

question = '<image>\nDescribe the two images in detail.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               history=None, return_history=True)
print(f'User: {question}\nAssistant: {response}')

question = 'What are the similarities and differences between these two images.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               history=history, return_history=True)
print(f'User: {question}\nAssistant: {response}')

# multi-image multi-round conversation, separate images (多图多轮对话，独立图像)
pixel_values1 = load_image('./examples/image1.jpg', max_num=12).to(torch.bfloat16).cuda()
pixel_values2 = load_image('./examples/image2.jpg', max_num=12).to(torch.bfloat16).cuda()
pixel_values = torch.cat((pixel_values1, pixel_values2), dim=0)
num_patches_list = [pixel_values1.size(0), pixel_values2.size(0)]

question = 'Image-1: <image>\nImage-2: <image>\nDescribe the two images in detail.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               num_patches_list=num_patches_list,
                               history=None, return_history=True)
print(f'User: {question}\nAssistant: {response}')

question = 'What are the similarities and differences between these two images.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               num_patches_list=num_patches_list,
                               history=history, return_history=True)
print(f'User: {question}\nAssistant: {response}')

# batch inference, single image per sample (单图批处理)
pixel_values1 = load_image('./examples/image1.jpg', max_num=12).to(torch.bfloat16).cuda()
pixel_values2 = load_image('./examples/image2.jpg', max_num=12).to(torch.bfloat16).cuda()
num_patches_list = [pixel_values1.size(0), pixel_values2.size(0)]
pixel_values = torch.cat((pixel_values1, pixel_values2), dim=0)

questions = ['<image>\nDescribe the image in detail.'] * len(num_patches_list)
responses = model.batch_chat(tokenizer, pixel_values,
                             num_patches_list=num_patches_list,
                             questions=questions,
                             generation_config=generation_config)
for question, response in zip(questions, responses):
    print(f'User: {question}\nAssistant: {response}')

# video multi-round conversation (视频多轮对话)
def get_index(bound, fps, max_frame, first_idx=0, num_segments=32):
    if bound:
        start, end = bound[0], bound[1]
    else:
        start, end = -100000, 100000
    start_idx = max(first_idx, round(start * fps))
    end_idx = min(round(end * fps), max_frame)
    seg_size = float(end_idx - start_idx) / num_segments
    frame_indices = np.array([
        int(start_idx + (seg_size / 2) + np.round(seg_size * idx))
        for idx in range(num_segments)
    ])
    return frame_indices

def load_video(video_path, bound=None, input_size=448, max_num=1, num_segments=32):
    vr = VideoReader(video_path, ctx=cpu(0), num_threads=1)
    max_frame = len(vr) - 1
    fps = float(vr.get_avg_fps())

    pixel_values_list, num_patches_list = [], []
    transform = build_transform(input_size=input_size)
    frame_indices = get_index(bound, fps, max_frame, first_idx=0, num_segments=num_segments)
    for frame_index in frame_indices:
        img = Image.fromarray(vr[frame_index].asnumpy()).convert('RGB')
        img = dynamic_preprocess(img, image_size=input_size, use_thumbnail=True, max_num=max_num)
        pixel_values = [transform(tile) for tile in img]
        pixel_values = torch.stack(pixel_values)
        num_patches_list.append(pixel_values.shape[0])
        pixel_values_list.append(pixel_values)
    pixel_values = torch.cat(pixel_values_list)
    return pixel_values, num_patches_list

video_path = './examples/red-panda.mp4'
pixel_values, num_patches_list = load_video(video_path, num_segments=8, max_num=1)
pixel_values = pixel_values.to(torch.bfloat16).cuda()
video_prefix = ''.join([f'Frame{i+1}: <image>\n' for i in range(len(num_patches_list))])
question = video_prefix + 'What is the red panda doing?'
# Frame1: <image>\nFrame2: <image>\n...\nFrame8: <image>\n{question}
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               num_patches_list=num_patches_list, history=None, return_history=True)
print(f'User: {question}\nAssistant: {response}')

question = 'Describe this video in detail.'
response, history = model.chat(tokenizer, pixel_values, question, generation_config,
                               num_patches_list=num_patches_list, history=history, return_history=True)
print(f'User: {question}\nAssistant: {response}')

Streaming Output

Besides this method, you can also use the following code to get streamed output.

from transformers import TextIteratorStreamer
from threading import Thread

# Initialize the streamer
streamer = TextIteratorStreamer(tokenizer, skip_prompt=True, skip_special_tokens=True, timeout=10)
# Define the generation configuration
generation_config = dict(max_new_tokens=1024, do_sample=False, streamer=streamer)
# Start the model chat in a separate thread
thread = Thread(target=model.chat, kwargs=dict(
    tokenizer=tokenizer, pixel_values=pixel_values, question=question,
    history=None, return_history=False, generation_config=generation_config,
))
thread.start()

# Initialize an empty string to store the generated text
generated_text = ''
# Loop through the streamer to get the new text as it is generated
for new_text in streamer:
    if new_text == model.conv_template.sep:
        break
    generated_text += new_text
    print(new_text, end='', flush=True)  # Print each new chunk of generated text on the same line

Finetune

Many repositories now support fine-tuning of the InternVL series models, including InternVL, SWIFT, XTuner, and others. Please refer to their documentation for more details on fine-tuning.

Deployment

LMDeploy

LMDeploy is a toolkit for compressing, deploying, and serving LLMs & VLMs.

pip install lmdeploy>=0.9.1

LMDeploy abstracts the complex inference process of multi-modal Vision-Language Models (VLM) into an easy-to-use pipeline, similar to the Large Language Model (LLM) inference pipeline.

A 'Hello, world' Example

from lmdeploy import pipeline, PytorchEngineConfig
from lmdeploy.vl import load_image

image = load_image('https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/tests/data/tiger.jpeg')

# Please set tp=2 for the 38B version and tp=8 for the 241B-A28B version.
model = 'OpenGVLab/InternVL3_5-8B'
pipe = pipeline(model, backend_config=PytorchEngineConfig(session_len=32768, tp=1))

response = pipe(('describe this image', image))
print(response.text)

Multi-images Inference

When dealing with multiple images, you can put them all in one list. Keep in mind that multiple images will lead to a higher number of input tokens, and as a result, the size of the context window typically needs to be increased.

from lmdeploy import pipeline, PytorchEngineConfig
from lmdeploy.vl import load_image
from lmdeploy.vl.constants import IMAGE_TOKEN

# Please set tp=2 for the 38B version and tp=8 for the 241B-A28B version.
model = 'OpenGVLab/InternVL3_5-8B'
pipe = pipeline(model, backend_config=PytorchEngineConfig(session_len=32768, tp=1))

image_urls=[
    'https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/demo/resources/human-pose.jpg',
    'https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/demo/resources/det.jpg'
]

images = [load_image(img_url) for img_url in image_urls]
# Numbering images improves multi-image conversations
response = pipe((f'Image-1: {IMAGE_TOKEN}\nImage-2: {IMAGE_TOKEN}\ndescribe these two images', images))
print(response.text)

Batch Prompts Inference

Conducting inference with batch prompts is quite straightforward; just place them within a list structure:

from lmdeploy import pipeline, PytorchEngineConfig
from lmdeploy.vl import load_image

# Please set tp=2 for the 38B version and tp=8 for the 241B-A28B version.
model = 'OpenGVLab/InternVL3_5-8B'
pipe = pipeline(model, backend_config=PytorchEngineConfig(session_len=32768, tp=1))

image_urls=[
    "https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/demo/resources/human-pose.jpg",
    "https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/demo/resources/det.jpg"
]
prompts = [('describe this image', load_image(img_url)) for img_url in image_urls]
response = pipe(prompts)
print(response)

Multi-turn Conversation

There are two ways to do the multi-turn conversations with the pipeline. One is to construct messages according to the format of OpenAI and use above introduced method, the other is to use the pipeline.chat interface.

from lmdeploy import pipeline, PytorchEngineConfig, GenerationConfig
from lmdeploy.vl import load_image

# Please set tp=2 for the 38B version and tp=8 for the 241B-A28B version.
model = 'OpenGVLab/InternVL3_5-8B'
pipe = pipeline(model, backend_config=PytorchEngineConfig(session_len=32768, tp=1))

image = load_image('https://raw.githubusercontent.com/open-mmlab/mmdeploy/main/demo/resources/human-pose.jpg')
gen_config = GenerationConfig(top_k=50, top_p=0.95, temperature=0.6, max_new_tokens=8192)
sess = pipe.chat(('describe this image', image), gen_config=gen_config)
print(sess.response.text)
sess = pipe.chat('What is the woman doing?', session=sess, gen_config=gen_config)
print(sess.response.text)

Service

LMDeploy's api_server enables models to be easily packed into services with a single command. The provided RESTful APIs are compatible with OpenAI's interfaces. Below are an example of service startup:

lmdeploy serve api_server OpenGVLab/InternVL3_5-8B --server-port 23333 --tp 1

To use the OpenAI-style interface, you need to install OpenAI:

pip install openai

Then, use the code below to make the API call:

from openai import OpenAI

client = OpenAI(api_key='YOUR_API_KEY', base_url='http://0.0.0.0:23333/v1')
model_name = client.models.list().data[0].id
response = client.chat.completions.create(
    model=model_name,
    messages=[{
        'role':
        'user',
        'content': [{
            'type': 'text',
            'text': 'describe this image',
        }, {
            'type': 'image_url',
            'image_url': {
                'url':
                'https://modelscope.oss-cn-beijing.aliyuncs.com/resource/tiger.jpeg',
            },
        }],
    }],
    temperature=0.8,
    top_p=0.8)
print(response)

License

This project is released under the apache-2.0 License. This project uses the pre-trained Qwen3 as a component, which is licensed under the apache-2.0 License.

Citation

If you find this project useful in your research, please consider citing:

@article{chen2024expanding,
  title={Expanding Performance Boundaries of Open-Source Multimodal Models with Model, Data, and Test-Time Scaling},
  author={Chen, Zhe and Wang, Weiyun and Cao, Yue and Liu, Yangzhou and Gao, Zhangwei and Cui, Erfei and Zhu, Jinguo and Ye, Shenglong and Tian, Hao and Liu, Zhaoyang and others},
  journal={arXiv preprint arXiv:2412.05271},
  year={2024}
}
@article{wang2024mpo,
  title={Enhancing the Reasoning Ability of Multimodal Large Language Models via Mixed Preference Optimization},
  author={Wang, Weiyun and Chen, Zhe and Wang, Wenhai and Cao, Yue and Liu, Yangzhou and Gao, Zhangwei and Zhu, Jinguo and Zhu, Xizhou and Lu, Lewei and Qiao, Yu and Dai, Jifeng},
  journal={arXiv preprint arXiv:2411.10442},
  year={2024}
}
@article{chen2024far,
  title={How Far Are We to GPT-4V? Closing the Gap to Commercial Multimodal Models with Open-Source Suites},
  author={Chen, Zhe and Wang, Weiyun and Tian, Hao and Ye, Shenglong and Gao, Zhangwei and Cui, Erfei and Tong, Wenwen and Hu, Kongzhi and Luo, Jiapeng and Ma, Zheng and others},
  journal={arXiv preprint arXiv:2404.16821},
  year={2024}
}
@inproceedings{chen2024internvl,
  title={Internvl: Scaling up vision foundation models and aligning for generic visual-linguistic tasks},
  author={Chen, Zhe and Wu, Jiannan and Wang, Wenhai and Su, Weijie and Chen, Guo and Xing, Sen and Zhong, Muyan and Zhang, Qinglong and Zhu, Xizhou and Lu, Lewei and others},
  booktitle={Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition},
  pages={24185--24198},
  year={2024}
}