Gemini 2.5 Pro is a groundbreaking AI model that has demonstrated exceptional performance across a wide range of benchmarks. According to the provided information, this model is currently ranked number one in the LM arena, a benchmark that relies on human voters to assess the results.

Gemini 2.5 Pro has outperformed other top models, such as Gro 3 Preview 1443, on various tasks. It has achieved impressive scores on benchmarks like Humanity's Last Exam, GPTQA Diamond, AMY 2025, AMY 2024, Live Codebench, Ader Polyglot, MMU, and MRCR. Notably, it has demonstrated the ability to handle contexts up to a million tokens, showcasing its capacity to work with large amounts of information.

The model's coding performance has been a particular highlight, with the provided information stating that Gemini 2.5 Pro "excels at creating visually compelling web apps and agentic code applications along with code transformation and editing." On the SweetBench, a standard for agentic code evaluation, Gemini 2.5 Pro scored an impressive 63.8% with a custom agent setup.

The model's versatility is further demonstrated by its ability to tackle a wide range of tasks, from solving Rubik's Cubes of various sizes to creating interactive Lego building simulations, snake games with unique visual effects, simple flight simulators, and even a 3D Torus knot simulation. The model's ability to generate these complex and visually stunning applications with a single prompt is truly remarkable.

Overall, the benchmarks and capabilities of Gemini 2.5 Pro suggest that it is a groundbreaking AI model that has set a new standard in the field of language models and their practical applications.

The Gemini 2.5 Pro model showcases its impressive capabilities by effortlessly solving Rubik's Cubes of various sizes. Starting with a standard 3D Rubik's Cube, the model is able to scramble and then solve the puzzle, preserving the colors and rotation with precision.

Moving on to a 4x4 Rubik's Cube, the model once again demonstrates its prowess, solving the puzzle in real-time and allowing the user to witness the entire process. To further push the boundaries, the model is tasked with solving a massive 10x10 Rubik's Cube. Despite the increased complexity, the model handles the challenge with ease, accurately solving the puzzle while maintaining the integrity of the colors and rotation.

This remarkable performance highlights the Gemini 2.5 Pro's exceptional problem-solving abilities and its mastery of spatial reasoning and manipulation. The model's ability to handle Rubik's Cubes of any size with such consistency and accuracy is a testament to its advanced capabilities, setting a new standard in the field of AI-driven puzzle solving.

The Gemini 2.5 Pro model was able to create an impressive interactive Lego building simulation using 3JS, all contained within a single HTML file. The simulation allows users to place, move, and connect Lego bricks in a 3D environment, with the following core features:

• Realistic-looking set of Lego bricks with accurate dimensions, colors, and textures
• Implement a grid-based snapping system that allows bricks to connect properly
• Ensure proper collision detection so bricks cannot occupy the same space
• Create satisfying visual and audio feedback when bricks connect
• Use 3JS to make the simulation work in a modern web browser without additional dependencies
• Contain all code, styles, and assets in a single HTML file

The simulation demonstrates the model's ability to create visually compelling and interactive applications, with features such as clicking and dragging to move bricks in 3D space, rotation controls, camera controls, and highlighting of valid connection points. This showcases the model's strong performance in coding and creating agentic code applications.

The Gemini 2.5 Pro model demonstrated its impressive capabilities by creating a visually stunning and complex version of the classic snake game. Beyond the standard snake mechanics, the model implemented the following unique features:

• Dynamic visual effects: The snake leaves behind a glowing, fading trail, and the background pulses with subtle color gradients and transitions when food is eaten.
• Particle explosion effect: When food is eaten, a particle explosion effect is triggered.
• Different types of food: Each food type grants temporary powers, such as speed boost, reverse controls, double vision, and time slowdown, each with unique animations.
• Evolving snake: As the snake grows, its segments become biomechanical with animated textures or shifting color patterns, visually evolving the snake with shaders or layered sprite effects.
• Procedurally generated animated obstacles: The game includes terrain zones with varying friction or effects, as well as an AI snake opponent.

The model was able to create this visually impressive and feature-rich snake game with a single prompt, showcasing its exceptional capabilities in generating complex and engaging interactive simulations.

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The model was able to create a simple flight simulator with just a basic prompt. The simulation works decently well, allowing the user to accelerate, move in different directions, and slow down the aircraft. While the details are limited, the simulation includes some nice touches like a shimmering shadow and a bit of fogging effect.

The model was able to generate the flight simulator in a single HTML file, demonstrating its capability to create interactive 3D applications with minimal input. The simulation, though simple, provides a solid foundation that could be further expanded upon with additional features and refinements.

Overall, the model's ability to generate a functional flight simulator from a simple prompt highlights its impressive coding skills and versatility in creating interactive 3D experiences.

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The model was able to recreate a simple version of the Reddit website in a single HTML file. While it doesn't look exactly like the current Reddit website, the simulation includes the key features such as different posts, comments, and the ability to join different subreddits.

The HTML file contains the basic structure and styling to mimic the Reddit layout, including a header, sidebar, and main content area. The posts are displayed with titles, user information, and comment counts. Users can interact with the simulation by scrolling through the posts and navigating to different subreddits.

Overall, the model was able to generate a functional and visually representative Reddit website in a single HTML file, demonstrating its impressive capabilities in web development and user interface design.

This section demonstrates the creation of an interactive 3D Torus Knot simulation using Three.js in a single HTML file. The simulation allows users to explore and manipulate the Torus Knot geometry through various interactive controls.

The key features of this simulation include:

• Rendering a Torus Knot geometry in a WebGL scene
• Applying a Phong material with default color, ambient, and directional lighting
• Implementing interactive controls using GUI sliders for parameters such as:
  • Radius
  • Tube radius
  • Radial segments
  • P and Q windings
  • Rotation speeds
  • Color
  • Wireframe mode
  • Shininess
  • Opacity
  • Ambient and directional lighting settings
• Providing a smooth and responsive user experience with real-time updates to the Torus Knot visualization as the controls are adjusted.

This simulation showcases the versatility and power of the Gemini 2.5 Pro model in generating visually compelling and interactive 3D graphics within a single HTML file, without the need for additional dependencies.

The ant farm simulation created using 3JS in a single HTML file aims to mimic the classic toy ant farms from childhood. The simulation features a transparent side view, a flat 2D plane rendered in 3D for depth and beauty, resembling a clear plastic container filled with sand or gel.

The key features of this simulation include:

• Transparent Side View: The simulation provides a clear, side-view perspective, allowing users to observe the ants digging tunnels, moving food, and interacting within the simulated environment.
• Realistic Ant Behavior: The ants are animated to realistically dig tunnels, carry food, and interact with each other and the environment in real-time.
• Particle Effects: Subtle particle effects are used to enhance the realism of the simulation, such as simulating the movement of sand or gel as the ants dig.
• Smooth Animations: The animations of the ants and the environment are designed to be smooth and visually appealing.
• Interactive Controls: Users can adjust various parameters of the simulation, such as the number of ants, the digging speed, and the food rate, to observe the effects on the ant farm.
• Substrate Customization: The simulation allows users to adjust the substrate between sand and gel, changing the visual appearance and potentially affecting the ants' behavior.
• Time of Day Adjustment: Users can adjust the time of day, which can affect the lighting and overall atmosphere of the simulation.

This immersive ant farm simulation provides a captivating and interactive experience, allowing users to observe the intricate workings of an ant colony in a visually stunning 3D environment.

The simulation creates an interactive environment that visually represents the flow of blood, with red blood cells, white blood cells, and various types of viruses. The key features include:

• Red Blood Cells: Passive cells that the virus targets and destroys.
• White Blood Cells: Defensive units that detect and attack the viruses.
• Viruses: Aggressive, stealthy, and fast-replicating entities that infect and destroy the red blood cells.

The simulation allows users to adjust various settings, such as the number of viruses, virus replication rate, and virus type (standard, aggressive, stealthy, or fast-replicating). Users can also control the number of white blood cells, their movement speed, and detection radius to observe how the immune system responds to the viral attack.

Additionally, the simulation includes options to adjust the blood flow speed and the overall simulation speed, providing a dynamic and customizable experience. The 3D version of the simulation further enhances the visual representation, allowing users to explore the environment from different perspectives and observe the intricate interactions between the cellular components and the viruses.

The surgery simulator demonstrates the model's ability to create interactive 3D environments with precise control and visual fidelity. The simulation allows the user to perform virtual surgical procedures using a scalpel, making incisions and suturing the patient's skin.

The simulation tracks the user's precision and stability scores, providing feedback on the quality of the surgical technique. Making clean, controlled cuts and suturing the incisions properly are key to maintaining a high stability score and ensuring the patient's well-being.

The level of detail and interactivity in this simulation showcases the model's proficiency in generating visually compelling 3D applications, as well as its capacity for fine-grained control and responsiveness to user inputs. This surgical simulator represents a compelling example of the model's versatility in creating engaging, interactive experiences.