latchbio-integration
О программе
Этот навык Claude позволяет разработчикам создавать и развертывать бессерверные биоинформатические рабочие процессы с использованием Latch SDK. Он позволяет создавать конвейеры с помощью декораторов Python (@workflow/@task), управлять облачными данными через LatchFile/LatchDir и интегрировать существующие рабочие процессы Nextflow или Snakemake. Используйте его для автоматической контейнеризации и развертывания воспроизводимых, масштабируемых биоинформатических конвейеров с автоматически генерируемыми пользовательскими интерфейсами.
Быстрая установка
Claude Code
Рекомендуетсяnpx 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/latchbio-integrationСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
LatchBio Integration
Overview
Latch is a Python framework for building and deploying bioinformatics workflows as serverless pipelines. Built on Flyte, create workflows with @workflow/@task decorators, manage cloud data with LatchFile/LatchDir, configure resources, and integrate Nextflow/Snakemake pipelines.
Core Capabilities
The Latch platform provides four main areas of functionality:
1. Workflow Creation and Deployment
- Define serverless workflows using Python decorators
- Support for native Python, Nextflow, and Snakemake pipelines
- Automatic containerization with Docker
- Auto-generated no-code user interfaces
- Version control and reproducibility
2. Data Management
- Cloud storage abstractions (LatchFile, LatchDir)
- Structured data organization with Registry (Projects → Tables → Records)
- Type-safe data operations with links and enums
- Automatic file transfer between local and cloud
- Glob pattern matching for file selection
3. Resource Configuration
- Pre-configured task decorators (@small_task, @large_task, @small_gpu_task, @large_gpu_task)
- Custom resource specifications (CPU, memory, GPU, storage)
- GPU support (K80, V100, A100)
- Timeout and storage configuration
- Cost optimization strategies
4. Verified Workflows
- Production-ready pre-built pipelines
- Bulk RNA-seq, DESeq2, pathway analysis
- AlphaFold and ColabFold for protein structure prediction
- Single-cell tools (ArchR, scVelo, emptyDropsR)
- CRISPR analysis, phylogenetics, and more
Quick Start
Installation and Setup
# Install Latch SDK
uv pip install latch
# Login to Latch
latch login
# Initialize a new workflow
latch init my-workflow
# Register workflow to platform
latch register my-workflow
Prerequisites:
- Docker installed and running
- Latch account credentials
- Python 3.8+
Basic Workflow Example
from latch import workflow, small_task
from latch.types import LatchFile
@small_task
def process_file(input_file: LatchFile) -> LatchFile:
"""Process a single file"""
# Processing logic
return output_file
@workflow
def my_workflow(input_file: LatchFile) -> LatchFile:
"""
My bioinformatics workflow
Args:
input_file: Input data file
"""
return process_file(input_file=input_file)
When to Use This Skill
This skill should be used when encountering any of the following scenarios:
Workflow Development:
- "Create a Latch workflow for RNA-seq analysis"
- "Deploy my pipeline to Latch"
- "Convert my Nextflow pipeline to Latch"
- "Add GPU support to my workflow"
- Working with
@workflow,@taskdecorators
Data Management:
- "Organize my sequencing data in Latch Registry"
- "How do I use LatchFile and LatchDir?"
- "Set up sample tracking in Latch"
- Working with
latch:///paths
Resource Configuration:
- "Configure GPU for AlphaFold on Latch"
- "My task is running out of memory"
- "How do I optimize workflow costs?"
- Working with task decorators
Verified Workflows:
- "Run AlphaFold on Latch"
- "Use DESeq2 for differential expression"
- "Available pre-built workflows"
- Using
latch.verifiedmodule
Detailed Documentation
This skill includes comprehensive reference documentation organized by capability:
references/workflow-creation.md
Read this for:
- Creating and registering workflows
- Task definition and decorators
- Supporting Python, Nextflow, Snakemake
- Launch plans and conditional sections
- Workflow execution (CLI and programmatic)
- Multi-step and parallel pipelines
- Troubleshooting registration issues
Key topics:
latch initandlatch registercommands@workflowand@taskdecorators- LatchFile and LatchDir basics
- Type annotations and docstrings
- Launch plans with preset parameters
- Conditional UI sections
references/data-management.md
Read this for:
- Cloud storage with LatchFile and LatchDir
- Registry system (Projects, Tables, Records)
- Linked records and relationships
- Enum and typed columns
- Bulk operations and transactions
- Integration with workflows
- Account and workspace management
Key topics:
latch:///path format- File transfer and glob patterns
- Creating and querying Registry tables
- Column types (string, number, file, link, enum)
- Record CRUD operations
- Workflow-Registry integration
references/resource-configuration.md
Read this for:
- Task resource decorators
- Custom CPU, memory, GPU configuration
- GPU types (K80, V100, A100)
- Timeout and storage settings
- Resource optimization strategies
- Cost-effective workflow design
- Monitoring and debugging
Key topics:
@small_task,@large_task,@small_gpu_task,@large_gpu_task@custom_taskwith precise specifications- Multi-GPU configuration
- Resource selection by workload type
- Platform limits and quotas
references/verified-workflows.md
Read this for:
- Pre-built production workflows
- Bulk RNA-seq and DESeq2
- AlphaFold and ColabFold
- Single-cell analysis (ArchR, scVelo)
- CRISPR editing analysis
- Pathway enrichment
- Integration with custom workflows
Key topics:
latch.verifiedmodule imports- Available verified workflows
- Workflow parameters and options
- Combining verified and custom steps
- Version management
Common Workflow Patterns
Complete RNA-seq Pipeline
from latch import workflow, small_task, large_task
from latch.types import LatchFile, LatchDir
@small_task
def quality_control(fastq: LatchFile) -> LatchFile:
"""Run FastQC"""
return qc_output
@large_task
def alignment(fastq: LatchFile, genome: str) -> LatchFile:
"""STAR alignment"""
return bam_output
@small_task
def quantification(bam: LatchFile) -> LatchFile:
"""featureCounts"""
return counts
@workflow
def rnaseq_pipeline(
input_fastq: LatchFile,
genome: str,
output_dir: LatchDir
) -> LatchFile:
"""RNA-seq analysis pipeline"""
qc = quality_control(fastq=input_fastq)
aligned = alignment(fastq=qc, genome=genome)
return quantification(bam=aligned)
GPU-Accelerated Workflow
from latch import workflow, small_task, large_gpu_task
from latch.types import LatchFile
@small_task
def preprocess(input_file: LatchFile) -> LatchFile:
"""Prepare data"""
return processed
@large_gpu_task
def gpu_computation(data: LatchFile) -> LatchFile:
"""GPU-accelerated analysis"""
return results
@workflow
def gpu_pipeline(input_file: LatchFile) -> LatchFile:
"""Pipeline with GPU tasks"""
preprocessed = preprocess(input_file=input_file)
return gpu_computation(data=preprocessed)
Registry-Integrated Workflow
from latch import workflow, small_task
from latch.registry.table import Table
from latch.registry.record import Record
from latch.types import LatchFile
@small_task
def process_and_track(sample_id: str, table_id: str) -> str:
"""Process sample and update Registry"""
# Get sample from registry
table = Table.get(table_id=table_id)
records = Record.list(table_id=table_id, filter={"sample_id": sample_id})
sample = records[0]
# Process
input_file = sample.values["fastq_file"]
output = process(input_file)
# Update registry
sample.update(values={"status": "completed", "result": output})
return "Success"
@workflow
def registry_workflow(sample_id: str, table_id: str):
"""Workflow integrated with Registry"""
return process_and_track(sample_id=sample_id, table_id=table_id)
Best Practices
Workflow Design
- Use type annotations for all parameters
- Write clear docstrings (appear in UI)
- Start with standard task decorators, scale up if needed
- Break complex workflows into modular tasks
- Implement proper error handling
Data Management
- Use consistent folder structures
- Define Registry schemas before bulk entry
- Use linked records for relationships
- Store metadata in Registry for traceability
Resource Configuration
- Right-size resources (don't over-allocate)
- Use GPU only when algorithms support it
- Monitor execution metrics and optimize
- Design for parallel execution when possible
Development Workflow
- Test locally with Docker before registration
- Use version control for workflow code
- Document resource requirements
- Profile workflows to determine actual needs
Troubleshooting
Common Issues
Registration Failures:
- Ensure Docker is running
- Check authentication with
latch login - Verify all dependencies in Dockerfile
- Use
--verboseflag for detailed logs
Resource Problems:
- Out of memory: Increase memory in task decorator
- Timeouts: Increase timeout parameter
- Storage issues: Increase ephemeral storage_gib
Data Access:
- Use correct
latch:///path format - Verify file exists in workspace
- Check permissions for shared workspaces
Type Errors:
- Add type annotations to all parameters
- Use LatchFile/LatchDir for file/directory parameters
- Ensure workflow return type matches actual return
Additional Resources
- Official Documentation: https://docs.latch.bio
- GitHub Repository: https://github.com/latchbio/latch
- Slack Community: Join Latch SDK workspace
- API Reference: https://docs.latch.bio/api/latch.html
- Blog: https://blog.latch.bio
Support
For issues or questions:
- Check documentation links above
- Search GitHub issues
- Ask in Slack community
- Contact [email protected]
GitHub репозиторий
Frequently asked questions
What is the latchbio-integration skill?
latchbio-integration is a Claude Skill by K-Dense-AI. Skills package instructions and resources that Claude loads on demand, so Claude can perform latchbio-integration-related tasks without extra prompting.
How do I install latchbio-integration?
Use the install commands on this page: add latchbio-integration to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does latchbio-integration belong to?
latchbio-integration is in the Meta category, tagged automation and design.
Is latchbio-integration free to use?
Yes. latchbio-integration is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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