Gemini Watermark Tool

📌 Original Author Notice (Reverse Alpha Blending)

I am the original author of GeminiWatermarkTool and the reverse alpha-blending restoration method used to remove the visible "Gemini" watermark while preserving image detail (Allen Kuo / allenk).

This project achieves high-precision restoration by using my calibrated 48×48 and 96×96 Reverse-Alpha Masks to invert the blending equation. Since I published this work and these assets, many derivative tools (desktop apps, websites, browser extensions, etc.) have appeared using the same approach and/or directly reusing the masks produced by this project — because the method is deterministic and highly effective.

✅ MIT License reminder
This project is released under the MIT License. Commercial use and ports are allowed.
However, if you redistribute any substantial portion of this project (including code or mask assets), you must:

Preserve the original copyright notice

Include the full MIT license text

(Recommended) Provide attribution with a link back to this repository

📖 For the full technical write-up (including how the Reverse-Alpha Masks were derived and calibrated), see:
Removing Gemini AI Watermarks: A Deep Dive into Reverse Alpha Blending
https://allenkuo.medium.com/removing-gemini-ai-watermarks-a-deep-dive-into-reverse-alpha-blending-bbbd83af2a3f

Gemini Watermark Tool removes Gemini visible watermarks from images using a mathematically accurate reverse alpha blending algorithm.
Unlike many tools that rely entirely on generative inpainting, this project focuses on deterministic reconstruction combined with lightweight AI-assisted cleanup.

The design philosophy is simple:
small, standalone, fast, and reliable.

The entire toolkit is distributed as a portable executable with zero runtime dependencies, making it easy to install, automate, and integrate into scripts or pipelines without complex setup.

Key capabilities include:

Fast & offline: single executable, no external services or dependencies
Standalone & portable: small footprint, easy to deploy and use anywhere
GUI + CLI: drag-and-drop desktop workflow or command-line automation
Deterministic watermark reconstruction: reverse alpha blending algorithm designed specifically for Gemini watermark overlays
AI-assisted cleanup: optional GPU-accelerated FDnCNN denoise (NCNN + Vulkan) for residual artifacts
Smart detection: three-stage NCC detection with confidence scoring to automatically skip non-watermarked images
Batch processing: process entire directories with preview and progress tracking
Cross-platform: Windows / Linux / macOS / Android (CLI)
AI Agent ready: Claude Code Skill + MCP Server for automation and agent workflows

🎬 Veo Video Watermark Removal — Demo Available

NEW: GeminiWatermarkTool now supports removing Google Veo video watermarks. The same reverse alpha blending engine, now for video — direct mp4-to-mp4, with audio preserved.

A standalone demo build (Windows x64) is available for testing:

VeoWatermarkRemover — Download Demo

Drag & drop your Veo .mp4 file onto the exe — done
36 MB standalone, zero dependencies
720p ~50 fps, 1080p ~18 fps
AI denoise + audio passthrough included

Cross-platform support and GUI integration are coming soon. This Veo feature will be merged into GeminiWatermarkTool when stable.

🖥️ GUI Application — Major Update

GeminiWatermarkTool now comes with a full graphical desktop application. No command line needed — just open, drag & drop, and process. Supports single-image editing with real-time preview, and batch processing with smart watermark detection.

The desktop GUI provides an interactive workflow for both single-image and batch operations.

GUI Demo

AI Agent - Integration (New in v0.2.5)

GeminiWatermarkTool can now be integrated into AI-agent workflows via MCP server and Claude Code skills. This enables automated watermark processing inside agent-based pipelines.

gwt-integrations — Claude Code Skill + MCP Server for GeminiWatermarkTool

Enable AI coding agents (Claude Code, Cursor, Windsurf, etc.) to use GeminiWatermarkTool directly:

Component	Description
Claude Code Skill	Teaches AI agents GWT's full CLI syntax, region/snap/denoise options, and best practices — agents can remove watermarks from images without manual guidance
MCP Server	Exposes GWT as 4 tools via Model Context Protocol — `remove_watermark`, `detect_watermark`, `batch_process`, `get_tool_info` — any MCP-compatible client can call them
install.py	Cross-platform installer (stdlib only) — auto-detects GWT binary, configures Claude Code skill and MCP server in one command

AI MCP Skill

Single Image Editing

GUI Single Image

Drag & drop or open any supported image
Auto-detect watermark size (48×48 / 96×96) or select manually
Custom watermark mode: draw a search region interactively, resize with 8-point anchors, fine-tune position with WASD keys
Multi-scale guided detection (Snap Engine): coarse-to-fine NCC template matching auto-locks to the exact watermark position within your drawn region — supports variable sizes from 16–320px with adjustable Min Size and Max Size sliders (Min Size default 16px covers Gemini preview-tier watermarks ~28px)
Real-time before/after comparison (press V)
One-key processing (X) and revert (Z)
Zoom, pan (Space/Alt + drag, mouse wheel), and fit-to-window

Software Inpainting Cleanup (New in v0.2.3)

Software Inpainting

Reverse alpha blending is mathematically exact — but only when the image hasn't been resized, recompressed, or processed after watermarking. In practice, many images go through post-processing that breaks the pixel-perfect math, leaving faint residual artifacts after removal.

Software Inpainting addresses this by applying a lightweight cleanup pass after the reverse blending step. It uses gradient-weighted masks derived from the watermark's own alpha channel to target only the residual pixels, leaving the rest of the image untouched.

Three built-in methods are available:

Method	Description	Best for
NS	Navier-Stokes based inpainting — propagates surrounding pixel flow into the damaged region	General-purpose cleanup with smooth results
TELEA	Fast marching method — fills inward from boundary pixels based on distance weighting	Quick processing, good for small residuals
Soft Inpaint	Gradient-weighted Gaussian blend — uses the watermark alpha as a soft mask for weighted blending	Preserving fine texture in photographic content

The cleanup controls appear automatically in Custom mode under the Detected Info panel. You can adjust the method, strength (0–100%), and inpaint radius (1–25 px) to fine-tune the result.

AI Denoise — FDnCNN Neural Network (New in v0.2.5)

AI Denoise

AI Denoise uses a GPU-accelerated neural network (FDnCNN) to clean up watermark residuals that conventional inpainting methods struggle with — particularly the faint sparkle edges and corner artifacts left after reverse alpha blending on resized images.

Unlike NS/TELEA which require a binary mask to know which pixels are damaged, AI Denoise examines a 41×41 pixel neighborhood around each point and learns from training data what "normal" image content looks like. Combined with gradient-masked blending from the alpha map, it repairs only the artifact pixels while preserving clean background detail.

Parameter	Range	Default	Description
Strength	0–300%	120%	Controls mask coverage — values above 100% expand repair to weaker gradient edges
Sigma	1–150	50	Noise level estimation — higher values denoise more aggressively

Technical details:

Model: FDnCNN Color, 20-layer Conv+ReLU, FP16 (~1.3 MB embedded in executable)
Inference: NCNN with Vulkan GPU acceleration, automatic CPU fallback
Pipeline: gradient mask from alpha map → NCNN inference on padded ROI → per-pixel masked blend
Performance: < 5 ms per region on modern GPUs, ~20 ms on CPU

AI Denoise is the recommended default when available. The GPU device name is displayed below the controls. If GPU initialization fails, the tool automatically falls back to NS inpainting.

Batch Processing

GUI Batch Processing

Drag & drop multiple files or an entire folder to enter batch mode
Thumbnail atlas preview with filename labels and status overlays (OK / SKIP / FAIL)
Detection threshold slider (0–100%, 5% steps, 25% recommended) — automatically skip images without watermarks
Confirmation dialog before overwriting originals
Non-blocking processing with progress bar and scrollable result log
Thumbnails refresh after completion to show processed results

Keyboard Shortcuts

Key	Action
X	Process image
V	Compare with original
Z	Revert to original
C (hold)	Hide overlay
W A S D	Move custom watermark region
Space / Alt	Pan (hold + drag)
Scroll	Zoom to cursor
Ctrl +/-	Zoom in / out
Ctrl 0	Zoom fit
Ctrl+W	Close / exit batch mode

Render Backends (Windows)

The GUI supports multiple render backends for maximum compatibility:

Backend	Description	Use Case
D3D11 (default)	Direct3D 11 with WARP fallback	Best for Windows — works in Hyper-V, Docker, RDP
OpenGL	OpenGL 3.3 Core	Cross-platform, requires GPU drivers

Why D3D11?

Native Windows API — no additional drivers needed
WARP fallback — software rendering when no GPU available
Works in Hyper-V, Docker, Remote Desktop, and other virtualized environments
Better stability in Windows sandbox configurations

# Auto-select (D3D11 on Windows, OpenGL elsewhere) GeminiWatermarkTool Force specific backend

GeminiWatermarkTool --backend=d3d11 GeminiWatermarkTool --backend=opengl

CLI — What's New

In addition to the GUI, the command line has been significantly enhanced.

Simple Mode — Now Supports Multiple Files

# Process multiple files at once (new!)
GeminiWatermarkTool img1.jpg img2.png img3.webp

Watermark detection is enabled by default in simple mode — images without a detectable watermark are automatically skipped to prevent accidental damage.

# Force processing without detection GeminiWatermarkTool --force image.jpg Custom detection threshold (default: 25%)

GeminiWatermarkTool --threshold 0.40 image.jpg

Standard Mode

# Single file with explicit output GeminiWatermarkTool -i input.jpg -o output.jpg Batch directory processing

GeminiWatermarkTool -i ./watermarked_images/ -o ./clean_images/

Watermark Detection

Inspired by @dannycreations's contribution on watermark presence detection. We took the concept further with a production-grade three-stage algorithm deeply integrated into both CLI and GUI workflows.

Batch processing watermark-free images can cause unnecessary pixel damage. The tool now uses a three-stage NCC (Normalized Cross-Correlation) algorithm to detect watermarks before processing, ensuring only watermarked images are modified:

Spatial NCC — correlates the image region with the known alpha map (50% weight, with circuit breaker at 0.25 to short-circuit obvious non-matches)
Gradient NCC — Sobel edge matching to detect the star-shaped structural pattern (30% weight)
Statistical Variance — texture dampening analysis to distinguish real watermarks from white/flat regions (20% weight)

A combined confidence score determines whether a watermark is present. The default threshold is 25% — images below this score are skipped. This eliminates false positives from white backgrounds or similar-looking content that plagued simpler correlation-based approaches.

Flag	Effect
`--force`	Skip detection, process all images unconditionally
`--threshold 0.40`	Set custom confidence threshold (0.0–1.0)
`--no-banner`	Hide ASCII banner (for scripts and AI agents)
`--banner`	Force show ASCII banner

Detection is enabled by default in simple/drag-and-drop mode and disabled by default in standard (-i / -o) mode. In the GUI, the threshold is adjustable via a slider (0–100%, 5% steps) with a recommended 25% default.

Demo

Comparison

Side by Side Comparison

Comparison Best for: slides, documents, UI screenshots, diagrams, logos.

Focus on the bottom example (text-heavy slide).
Generative inpainting often breaks text: warped edges, wrong spacing, invented strokes.
GeminiWatermarkTool reverses the blending equation to recover pixels, keeping text crisp.

⚠️ About SynthID (Invisible Watermark)

Important: This tool removes visible watermarks only. It does NOT remove SynthID.

What is SynthID?

SynthID is Google DeepMind's invisible watermarking technology embedded in AI-generated images. Unlike visible watermarks:

Invisible to human eyes
Integrated during generation (not added afterward)
Extremely robust against common image manipulations

Why Can't SynthID Be Removed?

Our extensive research revealed a fundamental truth:

SynthID is not a watermark added to an image — it IS the image.

SynthID operates as a Statistical Bias during generation. Every pixel choice is subtly influenced by Google's private key using Tournament Sampling. The watermark and visual content are inseparably bound.

Visible Watermark:  Image + Overlay = Result     ✓ Removable (this tool)
SynthID:            Biased Generation = Image    ✗ Cannot separate

Potential Removal Approaches

Approach	Trade-off	Feasibility
Extreme Quantization (binarization)	Image becomes unusable skeleton	✓ Works
AI Repaint (Stable Diffusion, etc.)	Style changes significantly	✓ Works
White-box Adversarial Attack	Requires detector model	✗ Not available

Conclusion: Removing SynthID while preserving image quality is currently not feasible.

📄 Full SynthID Research Report →

SynthID Image Watermark Research Report

Download

Download the latest release from the Releases page.

Platform	File	Architecture
Windows	`GeminiWatermarkTool-Windows-x64.exe`	x64
Linux	`GeminiWatermarkTool-Linux-x64`	x64
macOS	`GeminiWatermarkTool-macOS-Universal`	Intel + Apple Silicon
Android	`GeminiWatermarkTool-Android-arm64`	ARM64

First Run — OS Security Prompts

Downloaded binaries are not code-signed, so your OS may show a security warning on first launch. This is normal for open-source software distributed outside app stores.

macOS — "Apple cannot check it for malicious software"

Option A (recommended): Right-click the binary → Open → click Open in the dialog. You only need to do this once.

Option B (terminal):

xattr -dr com.apple.quarantine GeminiWatermarkTool
chmod +x GeminiWatermarkTool

Windows — SmartScreen "Windows protected your PC"

Option A: Click More info → Run anyway.

Option B (PowerShell):

Unblock-File .\GeminiWatermarkTool.exe

Linux — No security prompt

Linux does not quarantine downloaded binaries. Just ensure the file is executable:

chmod +x GeminiWatermarkTool
./GeminiWatermarkTool

⚠️ Disclaimer

USE AT YOUR OWN RISK

This tool modifies image files. While it is designed to work reliably, unexpected results may occur due to:

Variations in Gemini's watermark implementation

Corrupted or unusual image formats

Edge cases not covered by testing

Always back up your original images before processing.

The author assumes no responsibility for any data loss, image corruption, or unintended modifications. By using this tool, you acknowledge that you understand these risks.

CLI — Quick Start

Don't need the GUI? The CLI is designed for maximum simplicity — one drag, one drop, done.

Drag & Drop (Windows) — The Easiest Way

Download GeminiWatermarkTool-Windows-x64.exe
Drag an image file onto the executable
✅ Done! The watermark is removed in-place — no terminal, no arguments

Preview

Command Line

# Simple mode - just provide a filename GeminiWatermarkTool watermarked.jpg Specify output file (preserves original) GeminiWatermarkTool -i watermarked.jpg -o clean.jpg Batch processing - entire directory

GeminiWatermarkTool -i ./input_folder/ -o ./output_folder/

Supported formats: .jpg, .jpeg, .png, .webp, .bmp

⚠️ Warning: Simple mode overwrites the original file permanently. Always back up important images before processing.

Command Line Options

Option	Short	Description
`--input <path>`	`-i`	Input image file or directory
`--output <path>`	`-o`	Output image file or directory
`--remove`	`-r`	Remove watermark (default behavior)
`--force`	`-f`	Force processing (skip watermark detection)
`--threshold <val>`	`-t`	Detection confidence threshold, 0.0–1.0 (default: 0.25)
`--force-small`		Force 48×48 watermark size
`--force-large`		Force 96×96 watermark size
`--verbose`	`-v`	Enable verbose output
`--quiet`	`-q`	Suppress all output except errors
`--banner`	`-b`	Show full ASCII banner
`--version`	`-V`	Show version information
`--help`	`-h`	Show help message

Advanced Options (v0.2.5)

Option	Description
`--region <spec>`	Explicit watermark region (see Region Syntax below)
`--fallback-region <spec>`	Search region when standard detection fails
`--snap`	Enable multi-scale snap search within region
`--snap-max-size <N>`	Max snap search size, 16–320 (default: 160)
`--snap-threshold <N>`	Min snap confidence to accept, 0.0–1.0 (default: 0.60)
`--denoise <method>`	Cleanup after removal: `ai`, `ns`, `telea`, `soft`, `off`
`--sigma <N>`	AI denoise noise level, 1–150 (default: 50)
`--strength <N>`	Denoise strength %, 0–300 (default: 120 for AI, 85 for others)
`--radius <N>`	Inpaint radius for NS/TELEA/Soft, 1–25 (default: 10)

Region syntax:

Format	Description
`x,y,w,h`	Absolute coordinates
`br:mx,my,w,h`	Bottom-right corner (margin_x, margin_y, width, height)
`bl:mx,my,w,h`	Bottom-left corner
`tr:mx,my,w,h`	Top-right corner
`tl:mx,my,w,h`	Top-left (same as absolute)
`br:auto`	Use Gemini default position based on image size

Examples:

# Standard removal with AI denoise cleanup GeminiWatermarkTool -i input.jpg -o clean.jpg --denoise ai Batch with AI denoise (all files) GeminiWatermarkTool -i ./photos/ -o ./clean/ --denoise ai Fallback for images that fail detection: search bottom-right area with snap GeminiWatermarkTool -i ./photos/ -o ./clean/ --fallback-region br:auto --snap --denoise ai Resized watermarks: expand snap search to 320px GeminiWatermarkTool -i ./photos/ -o ./clean/ --fallback-region br:80,80,200,200 --snap --snap-max-size 320 --denoise ai Gemini preview images (small ~28px watermark): use lower snap-threshold GeminiWatermarkTool -i preview.jpg -o clean.jpg --fallback-region br:auto --snap --snap-threshold 0.30 --denoise ai --sigma 13 --strength 175 Force process at explicit region (all images have watermark at same spot)

GeminiWatermarkTool -i ./photos/ -o ./clean/ --force --region 500,800,160,160 --snap --denoise ai --sigma 75

Note: When no --denoise is specified, the CLI behaves identically to previous versions (no cleanup pass). All existing scripts and agent integrations continue to work unchanged.

Watermark Size Detection

The tool automatically detects the appropriate watermark size based on image dimensions:

Image Size	Watermark	Position
W ≤ 1024 or H ≤ 1024	48×48	Bottom-right, 32px margin
W > 1024 and H > 1024	96×96	Bottom-right, 64px margin

Use --force-small or --force-large to override automatic detection.

System Requirements

Platform	Requirements
Windows	Windows 10/11 x64
Linux	x64, glibc 2.35+ (Ubuntu 22.04+, Debian 12+)
macOS	macOS 11.0+ (Intel or Apple Silicon)
Android	ARM64, Android 10+ (API 29+)

All binaries are statically linked with no external runtime dependencies.

AI Denoise uses Vulkan for GPU acceleration. Most modern GPUs (NVIDIA, AMD, Intel) with up-to-date drivers support Vulkan. If no Vulkan GPU is detected, inference automatically falls back to CPU (OpenMP multi-threaded).

Troubleshooting

"The image doesn't look different after processing"

The watermark is semi-transparent. If the original background was similar to the watermark color, the difference may be subtle. Try viewing at 100% zoom in the watermark area (bottom-right corner).

"Wrong watermark size detected"

Use --force-small or --force-large to manually specify:

GeminiWatermarkTool -i image.jpg -o output.jpg --force-small

"File access denied"

Make sure the output path is writable and the file isn't open in another program.

Limitations

Only removes Gemini visible watermarks (the semi-transparent logo in bottom-right)
Does NOT remove SynthID invisible watermarks — see why
Designed for Gemini's current watermark pattern (as of 2025)

Building from Source

Prerequisites

Tool	Version	Notes
CMake	3.21+	For CMakePresets support
C++ Compiler	C++20	MSVC 2022, GCC 12+, Clang 14+
vcpkg	Latest	Package manager
Ninja	Latest	Recommended build system

Setup vcpkg

# Clone vcpkg git clone https://github.com/microsoft/vcpkg.git cd vcpkg Bootstrap ./bootstrap-vcpkg.sh # Linux/macOS .\bootstrap-vcpkg.bat # Windows Set environment variable

export VCPKG_ROOT="$HOME/vcpkg" # Linux/macOS (add to .bashrc) $env:VCPKG_ROOT = "C:\vcpkg" # Windows PowerShell

Build with CMake Presets

The project uses CMakePresets.json for cross-platform configuration.

# Clone with submodules (NCNN source) git clone --recursive https://github.com/allenk/GeminiWatermarkTool.git Or if already cloned: git submodule update --init --recursive List available presets

cmake --list-presets

Windows

cmake --preset windows-x64-Release
cmake --build --preset windows-x64-Release

Linux

cmake --preset linux-x64-Release
cmake --build --preset linux-x64-Release

macOS (Universal Binary)

macOS requires separate builds for each architecture:

# Build x64 cmake -B build-x64 -G Ninja \ -DCMAKE_BUILD_TYPE=Release \ -DCMAKE_TOOLCHAIN_FILE=$VCPKG_ROOT/scripts/buildsystems/vcpkg.cmake \ -DVCPKG_TARGET_TRIPLET=x64-osx \ -DCMAKE_OSX_ARCHITECTURES=x86_64 cmake --build build-x64 Build arm64 cmake -B build-arm64 -G Ninja -DCMAKE_BUILD_TYPE=Release -DCMAKE_TOOLCHAIN_FILE=$VCPKG_ROOT/scripts/buildsystems/vcpkg.cmake -DVCPKG_TARGET_TRIPLET=arm64-osx -DCMAKE_OSX_ARCHITECTURES=arm64 cmake --build build-arm64 Create Universal Binary

lipo -create build-x64/GeminiWatermarkTool build-arm64/GeminiWatermarkTool -output GeminiWatermarkTool

Android

Requires Android NDK:

export ANDROID_NDK_HOME="/path/to/android-ndk"

cmake --preset android-arm64-Release cmake --build --preset android-arm64-Release

Build Presets

Preset	Platform	Backend	Notes
`windows-x64-Release`	Windows	D3D11 + OpenGL	Default, includes AI Denoise
`windows-x64-OpenGL-Release`	Windows	OpenGL only	Includes AI Denoise
`linux-x64-Release`	Linux	OpenGL	Includes AI Denoise
`mac-universal-Release`	macOS	OpenGL	Intel + Apple Silicon, includes AI Denoise
`android-arm64-Release`	Android	—	CLI only, includes AI Denoise

All presets enable ENABLE_AI_DENOISE=ON by default. To build without AI, set -DENABLE_AI_DENOISE=OFF manually.

Manual Build (without presets)

cmake -B build -G Ninja \ -DCMAKE_BUILD_TYPE=Release \ -DCMAKE_TOOLCHAIN_FILE=$VCPKG_ROOT/scripts/buildsystems/vcpkg.cmake \ -DVCPKG_TARGET_TRIPLET=x64-linux

cmake --build build

Project Structure

gemini-watermark-tool/
├── CMakeLists.txt              # Main build configuration
├── CMakePresets.json           # Cross-platform build presets
├── vcpkg.json                  # Dependencies manifest
├── src/
│   ├── core/                   # Core engine (CLI + GUI shared)
│   │   ├── watermark_engine.hpp/cpp
│   │   ├── watermark_detector.hpp/cpp
│   │   ├── blend_modes.hpp/cpp
│   │   ├── ai_denoise.hpp/cpp         # NCNN FDnCNN denoiser
│   │   ├── ai_denoise_model.cpp       # Embedded model weights (isolated TU)
│   │   ├── ncnn_shim.hpp              # Vulkan loader shim for NCNN
│   │   └── types.hpp
│   ├── cli/                    # CLI application
│   │   └── cli_app.hpp/cpp
│   ├── utils/                  # Utilities
│   │   ├── ascii_logo.hpp
│   │   └── path_formatter.hpp
│   ├── main.cpp                # Entry point (CLI/GUI dispatcher)
│   └── gui/                    # Desktop GUI (ImGui + SDL3)
│       ├── gui_app.hpp/cpp           # GUI entry point
│       ├── app/
│       │   ├── app_state.hpp         # Application state
│       │   └── app_controller.hpp/cpp # Logic controller
│       ├── widgets/
│       │   ├── main_window.hpp/cpp   # Main window + menus
│       │   └── image_preview.hpp/cpp # Image viewer + batch view
│       ├── backend/
│       │   ├── render_backend.hpp/cpp  # Backend interface + factory
│       │   ├── opengl_backend.hpp/cpp  # OpenGL 3.3 implementation
│       │   └── d3d11_backend.hpp/cpp   # Direct3D 11 implementation (Windows)
│       └── resources/
│           └── style.hpp             # Theme and layout constants
├── external/
│   └── ncnn/                         # NCNN source (git submodule)
│       └── model-convert/output/     # Converted FDnCNN model headers
├── report/
│   └── synthid_research.md     # SynthID research documentation
└── resources/
    ├── app.ico                 # Windows application icon
    └── app.rc.in               # Windows resource template

Dependencies

All dependencies are managed via vcpkg and statically linked:

Package	Purpose
OpenCV	Image I/O and pixel operations
fmt	Modern string formatting
CLI11	Command line argument parsing
spdlog	Logging framework
SDL3	Window management and input (GUI)
Dear ImGui	Immediate mode GUI framework (GUI)
ImPlot	Plotting widgets (GUI)
glad	OpenGL loader (GUI)
nativefiledialog-extended	Native file dialogs (GUI)
WIL	Windows Implementation Libraries (D3D11 backend, Windows only)
NCNN	Neural network inference runtime (AI Denoise, git submodule)
volk	Vulkan meta-loader for dynamic dispatch (AI Denoise, vcpkg)

How It Works

Gemini Watermark Analysis

Gemini applies visible watermarks using alpha blending:

watermarked = α × logo + (1 - α) × original

Alpha Reconstruction

By statistically analyzing and comparing values related to Alpha, we can reconstruct an Alpha Map that is either correct or very close to it.

Removal Algorithm (Reverse Alpha Blending)

Solving for the original pixel:

original = (watermarked - α × logo) / (1 - α)
         = (watermarked - alpha_map) / (1 - α)

This mathematical inversion produces exact restoration of the original pixels.

Residual Cleanup (Software Inpainting + AI Denoise)

When images have been resized or recompressed after watermarking, the exact math no longer holds perfectly. Two approaches are available for cleaning up residual artifacts:

Software Inpainting (NS / TELEA / Gaussian):

1. Compute gradient magnitude from watermark alpha channel
2. Build soft weight mask: stronger where alpha gradient is high
3. Apply selected inpainting method (NS / TELEA / Gaussian blend)
4. Blend result using weight mask — only affected pixels are modified

AI Denoise (FDnCNN, recommended):

1. Compute gradient mask from alpha map (locate sparkle edges)
2. Run FDnCNN inference on padded ROI (Vulkan GPU or CPU)
   Input:  [R, G, B, sigma/255] → Output: denoised clean image
3. Per-pixel masked blend: mask × denoised + (1-mask) × original
   → Only edge artifacts repaired, clean background untouched

Legal Disclaimer

This tool is provided for personal and educational use only.

The removal of watermarks may have legal implications depending on your jurisdiction and the intended use of the images. Users are solely responsible for ensuring their use of this tool complies with applicable laws, terms of service, and intellectual property rights.

The author does not condone or encourage the misuse of this tool for copyright infringement, misrepresentation, or any other unlawful purposes.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY CLAIM, DAMAGES, OR OTHER LIABILITY ARISING FROM THE USE OF THIS SOFTWARE.

License

MIT License

Author

Allen Kuo (@allenk)

GitHub: https://github.com/allenk
LinkedIn: https://www.linkedin.com/in/allen-kuo-7b513a45/
Medium: https://allenkuo.medium.com

Quick start:

# Install the integration (after GeminiWatermarkTool is on PATH)
git clone https://github.com/allenk/gwt-integrations.git
cd gwt-integrations
python install.py

After installation, AI agents can process watermarks conversationally:

"Remove the Gemini watermark from screenshot.png using AI denoise"
"Batch process all images in ./photos/ with fallback snap detection"

See gwt-integrations README for full setup instructions and MCP configuration.

Removing Gemini AI Watermarks: A Deep Dive into Reverse Alpha Blending
SynthID Image Watermark Research Report
SynthID Research Report — Why invisible watermarks cannot be removed
gwt-integrations — Claude Code Skill + MCP Server for AI agent automation

Third-Party Licenses

This project incorporates the following open-source components:

Component	License	Usage
NCNN	BSD-3-Clause	Neural network inference runtime (Vulkan GPU + CPU)
FDnCNN model weights (KAIR)	MIT	Pre-trained denoising model (embedded FP16 weights)
volk	MIT	Vulkan meta-loader for dynamic dispatch

Full license texts for these components are available in their respective repositories.

If this tool helped you, consider giving it a ⭐

NAME

SYNOPSIS

INFO

DESCRIPTION

README