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@@ -20,15 +20,15 @@ pipeline_tag: any-to-any
20
  <b>License</b>: <a href="https://ai.google.dev/gemma/docs/gemma_4_license" target="_blank">Apache 2.0</a> | <b>Authors</b>: <a href="https://deepmind.google/models/gemma/" target="_blank">Google DeepMind</a>
21
  </p>
22
 
23
- Gemma is a family of open models built by Google DeepMind. Gemma 4 models are multimodal, handling text and image input (with audio supported on small models) and generating text output. This release includes open-weights models in both pre-trained and instruction-tuned variants. Gemma 4 features a context window of up to 256K tokens and maintains multilingual support in over 140 languages.
24
 
25
- Featuring both Dense and Mixture-of-Experts (MoE) architectures, Gemma 4 is well-suited for tasks like text generation, coding, and reasoning. The models are available in four distinct sizes: **E2B**, **E4B**, **26B A4B**, and **31B**. Their diverse sizes make them deployable in environments ranging from high-end phones to laptops and servers, democratizing access to state-of-the-art AI.
26
 
27
  Gemma 4 introduces key **capability and architectural advancements**:
28
 
29
  * **Reasoning** – All models in the family are designed as highly capable reasoners, with configurable thinking modes.
30
 
31
- * **Extended Multimodalities** – Processes Text, Image with variable aspect ratio and resolution support (all models), Video, and Audio (featured natively on the E2B and E4B models).
32
 
33
  * **Diverse & Efficient Architectures** – Offers Dense and Mixture-of-Experts (MoE) variants of different sizes for scalable deployment.
34
 
@@ -42,25 +42,27 @@ Gemma 4 introduces key **capability and architectural advancements**:
42
 
43
  ## **Models Overview**
44
 
45
- Gemma 4 models are designed to deliver frontier-level performance at each size, targeting deployment scenarios from mobile and edge devices (E2B, E4B) to consumer GPUs and workstations (26B A4B, 31B). They are well-suited for reasoning, agentic workflows, coding, and multimodal understanding.
46
 
47
  The models employ a hybrid attention mechanism that interleaves local sliding window attention with full global attention, ensuring the final layer is always global. This hybrid design delivers the processing speed and low memory footprint of a lightweight model without sacrificing the deep awareness required for complex, long-context tasks. To optimize memory for long contexts, global layers feature unified Keys and Values, and apply Proportional RoPE (p-RoPE).
48
 
49
  ### Dense Models
50
 
51
- | Property | E2B | E4B | 31B Dense |
52
- | :---- | :---- | :---- | :---- |
53
- | **Total Parameters** | 2.3B effective (5.1B with embeddings) | 4.5B effective (8B with embeddings) | 30.7B |
54
- | **Layers** | 35 | 42 | 60 |
55
- | **Sliding Window** | 512 tokens | 512 tokens | 1024 tokens |
56
- | **Context Length** | 128K tokens | 128K tokens | 256K tokens |
57
- | **Vocabulary Size** | 262K | 262K | 262K |
58
- | **Supported Modalities** | Text, Image, Audio | Text, Image, Audio | Text, Image |
59
- | **Vision Encoder Parameters** | *~150M* | *~150M* | *~550M* |
60
- | **Audio Encoder Parameters** | *~300M* | *~300M* | No Audio |
61
 
62
  The "E" in E2B and E4B stands for "effective" parameters. The smaller models incorporate Per-Layer Embeddings (PLE) to maximize parameter efficiency in on-device deployments. Rather than adding more layers or parameters to the model, PLE gives each decoder layer its own small embedding for every token. These embedding tables are large but are only used for quick lookups, which is why the effective parameter count is much smaller than the total.
63
 
 
 
64
  ### Mixture-of-Experts (MoE) Model
65
 
66
  | Property | 26B A4B MoE |
@@ -81,42 +83,44 @@ The "A" in 26B A4B stands for "active parameters" in contrast to the total numbe
81
 
82
  These models were evaluated against a large collection of different datasets and metrics to cover different aspects of text generation. Evaluation results marked in the table are for instruction-tuned models.
83
 
84
- | | Gemma 4 31B | Gemma 4 26B A4B | Gemma 4 E4B | Gemma 4 E2B | Gemma 3 27B (no think) |
85
- | :---- | :---- | :---- | :---- | :---- | :---- |
86
- | MMLU Pro | 85.2% | 82.6% | 69.4% | 60.0% | 67.6% |
87
- | AIME 2026 no tools | 89.2% | 88.3% | 42.5% | 37.5% | 20.8% |
88
- | LiveCodeBench v6 | 80.0% | 77.1% | 52.0% | 44.0% | 29.1% |
89
- | Codeforces ELO | 2150 | 1718 | 940 | 633 | 110 |
90
- | GPQA Diamond | 84.3% | 82.3% | 58.6% | 43.4% | 42.4% |
91
- | Tau2 (average over 3) | 76.9% | 68.2% | 42.2% | 24.5% | 16.2% |
92
- | HLE no tools | 19.5% | 8.7% | - | - | - |
93
- | HLE with search | 26.5% | 17.2% | - | - | - |
94
- | BigBench Extra Hard | 74.4% | 64.8% | 33.1% | 21.9% | 19.3% |
95
- | MMMLU | 88.4% | 86.3% | 76.6% | 67.4% | 70.7% |
96
- | **Vision** | | | | | |
97
- | MMMU Pro | 76.9% | 73.8% | 52.6% | 44.2% | 49.7% |
98
- | OmniDocBench 1.5 (average edit distance, lower is better) | 0.131 | 0.149 | 0.181 | 0.290 | 0.365 |
99
- | MATH-Vision | 85.6% | 82.4% | 59.5% | 52.4% | 46.0% |
100
- | MedXPertQA MM | 61.3% | 58.1% | 28.7% | 23.5% | - |
101
- | **Audio** | | | | | |
102
- | CoVoST | - | - | 35.54 | 33.47 | - |
103
- | FLEURS (lower is better) | - | - | 0.08 | 0.09 | - |
104
- | **Long Context** | | | | | |
105
- | MRCR v2 8 needle 128k (average) | 66.4% | 44.1% | 25.4% | 19.1% | 13.5% |
 
 
106
 
107
  ## **Core Capabilities**
108
 
109
  Gemma 4 models handle a broad range of tasks across text, vision, and audio. Key capabilities include:
110
 
111
  * **Thinking** – Built-in reasoning mode that lets the model think step-by-step before answering.
112
- * **Long Context** – Context windows of up to 128K tokens (E2B/E4B) and 256K tokens (26B A4B/31B).
113
  * **Image Understanding** – Object detection, Document/PDF parsing, screen and UI understanding, chart comprehension, OCR (including multilingual), handwriting recognition, and pointing. Images can be processed at variable aspect ratios and resolutions.
114
  * **Video Understanding** – Analyze video by processing sequences of frames.
115
  * **Interleaved Multimodal Input** – Freely mix text and images in any order within a single prompt.
116
  * **Function Calling** – Native support for structured tool use, enabling agentic workflows.
117
  * **Coding** – Code generation, completion, and correction.
118
  * **Multilingual** – Out-of-the-box support for 35+ languages, pre-trained on 140+ languages.
119
- * **Audio** (E2B and E4B only) – Automatic speech recognition (ASR) and speech-to-translated-text translation across multiple languages.
120
 
121
  ## Getting Started
122
 
@@ -127,13 +131,13 @@ You can use all Gemma 4 models with the latest version of Transformers. To get s
127
  Once you have everything installed, you can proceed to load the model with the code below:
128
 
129
  ```python
130
- from transformers import AutoProcessor, AutoModelForCausalLM
131
 
132
  MODEL_ID = "google/gemma-4-E4B-it"
133
 
134
  # Load model
135
  processor = AutoProcessor.from_pretrained(MODEL_ID)
136
- model = AutoModelForCausalLM.from_pretrained(
137
  MODEL_ID,
138
  dtype="auto",
139
  device_map="auto"
@@ -150,13 +154,14 @@ messages = [
150
  ]
151
 
152
  # Process input
153
- text = processor.apply_chat_template(
154
- messages,
155
- tokenize=False,
156
- add_generation_prompt=True,
 
 
157
  enable_thinking=False
158
- )
159
- inputs = processor(text=text, return_tensors="pt").to(model.device)
160
  input_len = inputs["input_ids"].shape[-1]
161
 
162
  # Generate output
@@ -169,13 +174,12 @@ processor.parse_response(response)
169
 
170
  To enable reasoning, set `enable_thinking=True` and the `parse_response` function will take care of parsing the thinking output.
171
 
172
- Below, you will also find snippets for processing audio (E2B and E4B only), images, and video alongside text:
173
 
174
  <details>
175
  <summary>Code for processing Audio</summary>
176
 
177
- Instead of using `AutoModelForCausalLM`, you can use `AutoModelForMultimodalLM` to process audio. To use it, make sure to install the following packages:
178
-
179
 
180
  `pip install -U transformers torch torchvision librosa accelerate`
181
 
@@ -233,7 +237,7 @@ processor.parse_response(response)
233
  <details>
234
  <summary>Code for processing Images</summary>
235
 
236
- Instead of using `AutoModelForCausalLM`, you can use `AutoModelForMultimodalLM` to process images. To use it, make sure to install the following packages:
237
 
238
 
239
  `pip install -U transformers torch torchvision accelerate`
@@ -292,7 +296,7 @@ processor.parse_response(response)
292
  <details>
293
  <summary>Code for processing Videos</summary>
294
 
295
- Instead of using `AutoModelForCausalLM`, you can use `AutoModelForMultimodalLM` to process videos. To use it, make sure to install the following packages:
296
 
297
  `pip install -U transformers torch torchvision librosa accelerate`
298
 
@@ -348,6 +352,7 @@ processor.parse_response(response)
348
  </details>
349
 
350
 
 
351
  ## **Best Practices**
352
 
353
  For the best performance, use these configurations and best practices:
@@ -375,7 +380,7 @@ Compared to Gemma 3, the models use standard `system`, `assistant`, and `user` r
375
 
376
  ### 3. Multi-Turn Conversations
377
 
378
- * **No Thinking Content in History**: In multi-turn conversations, the historical model output should only include the final response. Thoughts from previous model turns must *not be added* before the next user turn begins.
379
 
380
  ### 4. Modality order
381
 
@@ -415,7 +420,7 @@ When formatting the answer, first output the transcription in {SOURCE_LANGUAGE},
415
 
416
  ### 7. Audio and Video Length
417
 
418
- All models support image inputs and can process videos as frames whereas the E2B and E4B models also support audio inputs. Audio supports a maximum length of 30 seconds. Video supports a maximum of 60 seconds assuming the images are processed at one frame per second.
419
 
420
  ## **Model Data**
421
 
@@ -471,7 +476,7 @@ Multimodal models (capable of processing vision, language, and/or audio) have a
471
  * **Chatbots and Conversational AI**: Power conversational interfaces for customer service, virtual assistants, or interactive applications.
472
  * **Text Summarization**: Generate concise summaries of a text corpus, research papers, or reports.
473
  * **Image Data Extraction**: These models can be used to extract, interpret, and summarize visual data for text communications.
474
- * **Audio Processing and Interaction**: The smaller models (E2B and E4B) can analyze and interpret audio inputs, enabling voice-driven interactions and transcriptions.
475
  * **Research and Education**
476
  * **Natural Language Processing (NLP) and VLM Research**: These models can serve as a foundation for researchers to experiment with VLM and NLP techniques, develop algorithms, and contribute to the advancement of the field.
477
  * **Language Learning Tools**: Support interactive language learning experiences, aiding in grammar correction or providing writing practice.
 
20
  <b>License</b>: <a href="https://ai.google.dev/gemma/docs/gemma_4_license" target="_blank">Apache 2.0</a> | <b>Authors</b>: <a href="https://deepmind.google/models/gemma/" target="_blank">Google DeepMind</a>
21
  </p>
22
 
23
+ Gemma is a family of open models built by Google DeepMind. Gemma 4 models are multimodal, handling text and image input (with audio supported on E2B, E4B, and 12B) and generating text output. This release includes open-weights models in both pre-trained and instruction-tuned variants. Gemma 4 features a context window of up to 256K tokens and maintains multilingual support in over 140 languages.
24
 
25
+ Featuring both Dense and Mixture-of-Experts (MoE) architectures, Gemma 4 is well-suited for tasks like text generation, coding, and reasoning. The models are available in five distinct sizes: **E2B**, **E4B**, **12B**, **26B A4B**, and **31B**. Their diverse sizes make them deployable in environments ranging from high-end phones to laptops and servers, democratizing access to state-of-the-art AI.
26
 
27
  Gemma 4 introduces key **capability and architectural advancements**:
28
 
29
  * **Reasoning** – All models in the family are designed as highly capable reasoners, with configurable thinking modes.
30
 
31
+ * **Extended Multimodalities** – Processes Text, Image with variable aspect ratio and resolution support (all models), Video, and Audio (featured natively on the E2B, E4B, and 12B models).
32
 
33
  * **Diverse & Efficient Architectures** – Offers Dense and Mixture-of-Experts (MoE) variants of different sizes for scalable deployment.
34
 
 
42
 
43
  ## **Models Overview**
44
 
45
+ Gemma 4 models are designed to deliver frontier-level performance at each size, targeting deployment scenarios from mobile and edge devices (E2B, E4B) to consumer GPUs and workstations (12B, 26B A4B, 31B). They are well-suited for reasoning, agentic workflows, coding, and multimodal understanding.
46
 
47
  The models employ a hybrid attention mechanism that interleaves local sliding window attention with full global attention, ensuring the final layer is always global. This hybrid design delivers the processing speed and low memory footprint of a lightweight model without sacrificing the deep awareness required for complex, long-context tasks. To optimize memory for long contexts, global layers feature unified Keys and Values, and apply Proportional RoPE (p-RoPE).
48
 
49
  ### Dense Models
50
 
51
+ | Property | E2B | E4B | 12B Unified | 31B Dense |
52
+ | :---- | :---- | :---- | :---- | :---- |
53
+ | **Total Parameters** | 2.3B effective <br> (5.1B with embeddings) | 4.5B effective <br> (8B with embeddings) | 11.95B | 30.7B |
54
+ | **Layers** | 35 | 42 | 48 | 60 |
55
+ | **Sliding Window** | 512 tokens | 512 tokens | 1024 tokens | 1024 tokens |
56
+ | **Context Length** | 128K tokens | 128K tokens | 256K tokens | 256K tokens |
57
+ | **Vocabulary Size** | 262K | 262K | 262K | 262K |
58
+ | **Supported Modalities** | Text, Image, Audio | Text, Image, Audio | Text, Image, Audio | Text, Image |
59
+ | **Vision Encoder Parameters** | *~150M* | *~150M* | - | *~550M* |
60
+ | **Audio Encoder Parameters** | *~300M* | *~300M* | - | No Audio |
61
 
62
  The "E" in E2B and E4B stands for "effective" parameters. The smaller models incorporate Per-Layer Embeddings (PLE) to maximize parameter efficiency in on-device deployments. Rather than adding more layers or parameters to the model, PLE gives each decoder layer its own small embedding for every token. These embedding tables are large but are only used for quick lookups, which is why the effective parameter count is much smaller than the total.
63
 
64
+ The "Unified" in Gemma 4 12B Unified refers to its encoder-free architecture. Other Gemma 4 models use dedicated encoders to process multimodal data before passing it to the LLM. Gemma 4 12B eliminates these encoders entirely, projecting raw image patches and audio waveforms directly into the LLM's embedding space through lightweight linear layers. This unified approach means all modalities flow straight into a single decoder-only transformer, reducing multimodal latency and allowing the entire model to be fine-tuned in one pass.
65
+
66
  ### Mixture-of-Experts (MoE) Model
67
 
68
  | Property | 26B A4B MoE |
 
83
 
84
  These models were evaluated against a large collection of different datasets and metrics to cover different aspects of text generation. Evaluation results marked in the table are for instruction-tuned models.
85
 
86
+ | | Gemma 4 31B | Gemma 4 26B A4B | Gemma 4 12B Unified | Gemma 4 E4B | Gemma 4 E2B | Gemma 3 27B (no think) |
87
+ | :---- | :---- | :---- | :---- | :---- | :---- | :---- |
88
+ | MMLU Pro | 85.2% | 82.6% | 77.2% | 69.4% | 60.0% | 67.6% |
89
+ | AIME 2026 no tools | 89.2% | 88.3% | 77.5% | 42.5% | 37.5% | 20.8% |
90
+ | LiveCodeBench v6 | 80.0% | 77.1% | 72.0% | 52.0% | 44.0% | 29.1% |
91
+ | Codeforces ELO | 2150 | 1718 | 1659 | 940 | 633 | 110 |
92
+ | GPQA Diamond | 84.3% | 82.3% | 78.8% | 58.6% | 43.4% | 42.4% |
93
+ | Tau2 (average over 3) | 76.9% | 68.2% | 69.0% | 42.2% | 24.5% | 16.2% |
94
+ | HLE no tools | 19.5% | 8.7% | 5.2% | - | - | - |
95
+ | HLE with search | 26.5% | 17.2% | - | - | - | - |
96
+ | BigBench Extra Hard | 74.4% | 64.8% | 53.0% | 33.1% | 21.9% | 19.3% |
97
+ | MMMLU | 88.4% | 86.3% | 83.4% | 76.6% | 67.4% | 70.7% |
98
+ | **Vision** | | | | | | |
99
+ | MMMU Pro | 76.9% | 73.8% | 69.1% | 52.6% | 44.2% | 49.7% |
100
+ | OmniDocBench 1.5 (average edit distance, lower is better) | 0.131 | 0.149 | 0.164 | 0.181 | 0.290 | 0.365 |
101
+ | MATH-Vision | 85.6% | 82.4% | 79.7% | 59.5% | 52.4% | 46.0% |
102
+ | MedXPertQA MM | 61.3% | 58.1% | 48.7% | 28.7% | 23.5% | - |
103
+ | **Audio** | | | | | | |
104
+ | CoVoST | - | - | 38.5<sup>*</sup> | 35.54 | 33.47 | - |
105
+ | FLEURS (lower is better) | - | - | 0.069<sup>*</sup> | 0.08 | 0.09 | - |
106
+ | **Long Context** | | | | | | |
107
+ | MRCR v2 8 needle 128k (average) | 66.4% | 44.1% | 43.4% | 25.4% | 19.1% | 13.5% |
108
+
109
+ <sup>*</sup>Excluding Chinese language.
110
 
111
  ## **Core Capabilities**
112
 
113
  Gemma 4 models handle a broad range of tasks across text, vision, and audio. Key capabilities include:
114
 
115
  * **Thinking** – Built-in reasoning mode that lets the model think step-by-step before answering.
116
+ * **Long Context** – Context windows of up to 128K tokens (E2B/E4B) and 256K tokens (12B, 26B A4B/31B).
117
  * **Image Understanding** – Object detection, Document/PDF parsing, screen and UI understanding, chart comprehension, OCR (including multilingual), handwriting recognition, and pointing. Images can be processed at variable aspect ratios and resolutions.
118
  * **Video Understanding** – Analyze video by processing sequences of frames.
119
  * **Interleaved Multimodal Input** – Freely mix text and images in any order within a single prompt.
120
  * **Function Calling** – Native support for structured tool use, enabling agentic workflows.
121
  * **Coding** – Code generation, completion, and correction.
122
  * **Multilingual** – Out-of-the-box support for 35+ languages, pre-trained on 140+ languages.
123
+ * **Audio** (E2B, E4B, and 12B only) – Automatic speech recognition (ASR) and speech-to-translated-text translation across multiple languages.
124
 
125
  ## Getting Started
126
 
 
131
  Once you have everything installed, you can proceed to load the model with the code below:
132
 
133
  ```python
134
+ from transformers import AutoProcessor, AutoModelForMultimodalLM
135
 
136
  MODEL_ID = "google/gemma-4-E4B-it"
137
 
138
  # Load model
139
  processor = AutoProcessor.from_pretrained(MODEL_ID)
140
+ model = AutoModelForMultimodalLM.from_pretrained(
141
  MODEL_ID,
142
  dtype="auto",
143
  device_map="auto"
 
154
  ]
155
 
156
  # Process input
157
+ inputs = processor.apply_chat_template(
158
+ messages,
159
+ tokenize=True,
160
+ return_dict=True,
161
+ return_tensors="pt",
162
+ add_generation_prompt=True,
163
  enable_thinking=False
164
+ ).to(model.device)
 
165
  input_len = inputs["input_ids"].shape[-1]
166
 
167
  # Generate output
 
174
 
175
  To enable reasoning, set `enable_thinking=True` and the `parse_response` function will take care of parsing the thinking output.
176
 
177
+ Below, you will also find snippets for processing audio (E2B, E4B, 12B only), images, and video alongside text:
178
 
179
  <details>
180
  <summary>Code for processing Audio</summary>
181
 
182
+ Make sure to install the following packages:
 
183
 
184
  `pip install -U transformers torch torchvision librosa accelerate`
185
 
 
237
  <details>
238
  <summary>Code for processing Images</summary>
239
 
240
+ Make sure to install the following packages:
241
 
242
 
243
  `pip install -U transformers torch torchvision accelerate`
 
296
  <details>
297
  <summary>Code for processing Videos</summary>
298
 
299
+ Make sure to install the following packages:
300
 
301
  `pip install -U transformers torch torchvision librosa accelerate`
302
 
 
352
  </details>
353
 
354
 
355
+
356
  ## **Best Practices**
357
 
358
  For the best performance, use these configurations and best practices:
 
380
 
381
  ### 3. Multi-Turn Conversations
382
 
383
+ * **No Thinking Content in History**: In multi-turn conversations, the historical model output should only include the final response. Thoughts from previous model turns must *not be added* before the next user turn begins, with the exception of tool call turns where thinking content should be preserved.
384
 
385
  ### 4. Modality order
386
 
 
420
 
421
  ### 7. Audio and Video Length
422
 
423
+ All models support image inputs and can process videos as frames whereas the E2B, E4B, and 12B models also support audio inputs. Audio supports a maximum length of 30 seconds. Video supports a maximum of 60 seconds assuming the images are processed at one frame per second.
424
 
425
  ## **Model Data**
426
 
 
476
  * **Chatbots and Conversational AI**: Power conversational interfaces for customer service, virtual assistants, or interactive applications.
477
  * **Text Summarization**: Generate concise summaries of a text corpus, research papers, or reports.
478
  * **Image Data Extraction**: These models can be used to extract, interpret, and summarize visual data for text communications.
479
+ * **Audio Processing and Interaction**: The E2B, E4B, and 12B models can analyze and interpret audio inputs, enabling voice-driven interactions and transcriptions.
480
  * **Research and Education**
481
  * **Natural Language Processing (NLP) and VLM Research**: These models can serve as a foundation for researchers to experiment with VLM and NLP techniques, develop algorithms, and contribute to the advancement of the field.
482
  * **Language Learning Tools**: Support interactive language learning experiences, aiding in grammar correction or providing writing practice.