gtars
Über
Gtars ist ein leistungsstarkes Rust-Toolkit mit Python-Bindungen für die Analyse genomischer Intervalle. Es bietet spezialisierte Funktionen für Überlappungserkennung, die Erzeugung von Coverage-Tracks und Tokenisierung für ML-Modelle. Verwenden Sie es bei der Arbeit mit BED-Dateien, in der Computer-Genomik oder bei der Vorverarbeitung genomischer Daten für maschinelles Lernen.
Schnellinstallation
Claude Code
Empfohlennpx skills add K-Dense-AI/claude-scientific-skills -a claude-code/plugin add https://github.com/K-Dense-AI/claude-scientific-skillsgit clone https://github.com/K-Dense-AI/claude-scientific-skills.git ~/.claude/skills/gtarsKopieren Sie diesen Befehl und fügen Sie ihn in Claude Code ein, um diese Fähigkeit zu installieren
Dokumentation
Gtars: Genomic Tools and Algorithms in Rust
Overview
Gtars is a high-performance Rust toolkit for manipulating, analyzing, and processing genomic interval data. It provides specialized tools for overlap detection, coverage analysis, tokenization for machine learning, and reference sequence management.
Use this skill when working with:
- Genomic interval files (BED format)
- Overlap detection between genomic regions
- Coverage track generation (WIG, BigWig)
- Genomic ML preprocessing and tokenization
- Fragment analysis in single-cell genomics
- Reference sequence retrieval and validation
Installation
Python Installation
Install gtars Python bindings:
uv pip install gtars
CLI Installation
Install command-line tools (requires Rust/Cargo):
# Install with all features
cargo install gtars-cli --features "uniwig overlaprs igd bbcache scoring fragsplit"
# Or install specific features only
cargo install gtars-cli --features "uniwig overlaprs"
Rust Library
Add to Cargo.toml for Rust projects:
[dependencies]
gtars = { version = "0.1", features = ["tokenizers", "overlaprs"] }
Core Capabilities
Gtars is organized into specialized modules, each focused on specific genomic analysis tasks:
1. Overlap Detection and IGD Indexing
Efficiently detect overlaps between genomic intervals using the Integrated Genome Database (IGD) data structure.
When to use:
- Finding overlapping regulatory elements
- Variant annotation
- Comparing ChIP-seq peaks
- Identifying shared genomic features
Quick example:
import gtars
# Build IGD index and query overlaps
igd = gtars.igd.build_index("regions.bed")
overlaps = igd.query("chr1", 1000, 2000)
See references/overlap.md for comprehensive overlap detection documentation.
2. Coverage Track Generation
Generate coverage tracks from sequencing data with the uniwig module.
When to use:
- ATAC-seq accessibility profiles
- ChIP-seq coverage visualization
- RNA-seq read coverage
- Differential coverage analysis
Quick example:
# Generate BigWig coverage track
gtars uniwig generate --input fragments.bed --output coverage.bw --format bigwig
See references/coverage.md for detailed coverage analysis workflows.
3. Genomic Tokenization
Convert genomic regions into discrete tokens for machine learning applications, particularly for deep learning models on genomic data.
When to use:
- Preprocessing for genomic ML models
- Integration with geniml library
- Creating position encodings
- Training transformer models on genomic sequences
Quick example:
from gtars.tokenizers import TreeTokenizer
tokenizer = TreeTokenizer.from_bed_file("training_regions.bed")
token = tokenizer.tokenize("chr1", 1000, 2000)
See references/tokenizers.md for tokenization documentation.
4. Reference Sequence Management
Handle reference genome sequences and compute digests following the GA4GH refget protocol.
When to use:
- Validating reference genome integrity
- Extracting specific genomic sequences
- Computing sequence digests
- Cross-reference comparisons
Quick example:
# Load reference and extract sequences
store = gtars.RefgetStore.from_fasta("hg38.fa")
sequence = store.get_subsequence("chr1", 1000, 2000)
See references/refget.md for reference sequence operations.
5. Fragment Processing
Split and analyze fragment files, particularly useful for single-cell genomics data.
When to use:
- Processing single-cell ATAC-seq data
- Splitting fragments by cell barcodes
- Cluster-based fragment analysis
- Fragment quality control
Quick example:
# Split fragments by clusters
gtars fragsplit cluster-split --input fragments.tsv --clusters clusters.txt --output-dir ./by_cluster/
See references/cli.md for fragment processing commands.
6. Fragment Scoring
Score fragment overlaps against reference datasets.
When to use:
- Evaluating fragment enrichment
- Comparing experimental data to references
- Quality metrics computation
- Batch scoring across samples
Quick example:
# Score fragments against reference
gtars scoring score --fragments fragments.bed --reference reference.bed --output scores.txt
Common Workflows
Workflow 1: Peak Overlap Analysis
Identify overlapping genomic features:
import gtars
# Load two region sets
peaks = gtars.RegionSet.from_bed("chip_peaks.bed")
promoters = gtars.RegionSet.from_bed("promoters.bed")
# Find overlaps
overlapping_peaks = peaks.filter_overlapping(promoters)
# Export results
overlapping_peaks.to_bed("peaks_in_promoters.bed")
Workflow 2: Coverage Track Pipeline
Generate coverage tracks for visualization:
# Step 1: Generate coverage
gtars uniwig generate --input atac_fragments.bed --output coverage.wig --resolution 10
# Step 2: Convert to BigWig for genome browsers
gtars uniwig generate --input atac_fragments.bed --output coverage.bw --format bigwig
Workflow 3: ML Preprocessing
Prepare genomic data for machine learning:
from gtars.tokenizers import TreeTokenizer
import gtars
# Step 1: Load training regions
regions = gtars.RegionSet.from_bed("training_peaks.bed")
# Step 2: Create tokenizer
tokenizer = TreeTokenizer.from_bed_file("training_peaks.bed")
# Step 3: Tokenize regions
tokens = [tokenizer.tokenize(r.chromosome, r.start, r.end) for r in regions]
# Step 4: Use tokens in ML pipeline
# (integrate with geniml or custom models)
Python vs CLI Usage
Use Python API when:
- Integrating with analysis pipelines
- Need programmatic control
- Working with NumPy/Pandas
- Building custom workflows
Use CLI when:
- Quick one-off analyses
- Shell scripting
- Batch processing files
- Prototyping workflows
Reference Documentation
Comprehensive module documentation:
references/python-api.md- Complete Python API reference with RegionSet operations, NumPy integration, and data exportreferences/overlap.md- IGD indexing, overlap detection, and set operationsreferences/coverage.md- Coverage track generation with uniwigreferences/tokenizers.md- Genomic tokenization for ML applicationsreferences/refget.md- Reference sequence management and digestsreferences/cli.md- Command-line interface complete reference
Integration with geniml
Gtars serves as the foundation for the geniml Python package, providing core genomic interval operations for machine learning workflows. When working on geniml-related tasks, use gtars for data preprocessing and tokenization.
Performance Characteristics
- Native Rust performance: Fast execution with low memory overhead
- Parallel processing: Multi-threaded operations for large datasets
- Memory efficiency: Streaming and memory-mapped file support
- Zero-copy operations: NumPy integration with minimal data copying
Data Formats
Gtars works with standard genomic formats:
- BED: Genomic intervals (3-column or extended)
- WIG/BigWig: Coverage tracks
- FASTA: Reference sequences
- Fragment TSV: Single-cell fragment files with barcodes
Error Handling and Debugging
Enable verbose logging for troubleshooting:
import gtars
# Enable debug logging
gtars.set_log_level("DEBUG")
# CLI verbose mode
gtars --verbose <command>
GitHub Repository
Verwandte Skills
llamaguard
AndereLlamaGuard ist Metas 7-8B-Parameter-Modell zur Moderation von LLM-Eingaben und -Ausgaben in sechs Sicherheitskategorien wie Gewalt und Hassrede. Es bietet eine Genauigkeit von 94-95 % und kann mit vLLM, Hugging Face oder Amazon SageMaker eingesetzt werden. Nutzen Sie diese Skill, um Inhaltsfilterung und Sicherheitsguardrails einfach in Ihre KI-Anwendungen zu integrieren.
cost-optimization
AndereDiese Claude Skill unterstützt Entwickler bei der Optimierung von Cloud-Kosten durch Ressourcen-Dimensionierung, Tagging-Strategien und Ausgabenanalysen. Sie bietet einen Rahmen zur Senkung von Cloud-Ausgaben und zur Implementierung von Kosten-Governance für AWS, Azure und GCP. Nutzen Sie sie, wenn Sie Infrastrukturkosten analysieren, Ressourcen richtig dimensionieren oder Budgetvorgaben einhalten müssen.
quantizing-models-bitsandbytes
AndereDiese Fähigkeit quantisiert LLMs auf 8-Bit- oder 4-Bit-Präzision mittels bitsandbytes und erreicht dabei eine Speicherreduzierung von 50–75 % bei minimalem Genauigkeitsverlust. Sie ist ideal für den Betrieb größerer Modelle mit begrenztem GPU-Speicher oder zur Beschleunigung von Inferenzvorgängen und unterstützt Formate wie INT8, NF4 und FP4. Die Fähigkeit integriert sich in HuggingFace Transformers und ermöglicht QLoRA-Training sowie 8-Bit-Optimierer.
dispatching-parallel-agents
AndereDiese Claude-Fähigkeit verteilt mehrere Agenten, um drei oder mehr unabhängige Probleme gleichzeitig zu untersuchen und zu beheben. Sie ist für Szenarien konzipiert, die unabhängige Fehler umfassen, die ohne gemeinsamen Zustand oder Abhängigkeiten gelöst werden können. Die Kernfähigkeit ist die parallele Problemlösung, bei der pro unabhängigem Problembereich ein Agent zugewiesen wird, um die Effizienz zu maximieren.