dspy-custom-module-design
This skill should be used when the user asks to "create custom DSPy module", "design a DSPy module", "extend dspy.Module", "build reusable DSPy component", mentions "custom module patterns", "module serialization", "stateful modules", "module testing", or needs to design production-quality custom DSPy modules with proper architecture, state management, and testing.
git clone --depth 1 https://github.com/OmidZamani/dspy-skills /tmp/dspy-custom-module-design && cp -r /tmp/dspy-custom-module-design/skills/dspy-custom-module-design ~/.claude/skills/dspy-custom-module-designSKILL.md
# DSPy Custom Module Design
## Goal
Design production-quality custom DSPy modules with proper architecture, state management, serialization, and testing patterns.
## When to Use
- Building reusable DSPy components
- Complex logic beyond built-in modules
- Need custom state management
- Sharing modules across projects
- Production deployment requirements
## Related Skills
- Module composition: [dspy-advanced-module-composition](../dspy-advanced-module-composition/SKILL.md)
- Signature design: [dspy-signature-designer](../dspy-signature-designer/SKILL.md)
- Optimization: [dspy-miprov2-optimizer](../dspy-miprov2-optimizer/SKILL.md)
## Inputs
| Input | Type | Description |
|-------|------|-------------|
| `task_description` | `str` | What the module should do |
| `components` | `list` | Sub-modules or predictors |
| `state` | `dict` | Stateful attributes |
## Outputs
| Output | Type | Description |
|--------|------|-------------|
| `custom_module` | `dspy.Module` | Production-ready module |
## Workflow
### Phase 1: Basic Module Structure
All custom modules inherit from `dspy.Module`:
```python
import dspy
class BasicQA(dspy.Module):
"""Simple question answering module."""
def __init__(self):
super().__init__()
self.predictor = dspy.Predict("question -> answer")
def forward(self, question):
"""Entry point for module execution."""
return self.predictor(question=question)
# Usage
dspy.configure(lm=dspy.LM("openai/gpt-4o-mini"))
qa = BasicQA()
result = qa(question="What is Python?")
print(result.answer)
```
### Phase 2: Stateful Modules
Modules can maintain state across calls:
```python
import dspy
import logging
logger = logging.getLogger(__name__)
class StatefulRAG(dspy.Module):
"""RAG with query caching."""
def __init__(self, cache_size=100):
super().__init__()
self.retrieve = dspy.Retrieve(k=3)
self.generate = dspy.ChainOfThought("context, question -> answer")
self.cache = {}
self.cache_size = cache_size
def forward(self, question):
# Check cache
if question in self.cache:
return self.cache[question]
# Retrieve and generate
passages = self.retrieve(question).passages
result = self.generate(context=passages, question=question)
# Update cache with size limit
if len(self.cache) >= self.cache_size:
self.cache.pop(next(iter(self.cache)))
self.cache[question] = result
return result
```
### Phase 3: Error Handling and Validation
Production modules need robust error handling:
```python
import dspy
from typing import Optional
import logging
logger = logging.getLogger(__name__)
class RobustClassifier(dspy.Module):
"""Classifier with validation."""
def __init__(self, valid_labels: list[str]):
super().__init__()
self.valid_labels = set(valid_labels)
self.classify = dspy.Predict("text -> label: str, confidence: float")
def forward(self, text: str) -> dspy.Prediction:
if not text or not text.strip():
return dspy.Prediction(label="unknown", confidence=0.0, error="Empty input")
try:
result = self.classify(text=text)
# Validate label
if result.label not in self.valid_labels:
result.label = "unknown"
result.confidence = 0.0
return result
except Exception as e:
logger.error(f"Classification failed: {e}")
return dspy.Prediction(label="unknown", confidence=0.0, error=str(e))
```
### Phase 4: Serialization
Modules support save/load:
```python
import dspy
# Save module state
module = MyCustomModule()
module.save("my_module.json")
# Load requires creating instance first, then loading state
loaded = MyCustomModule()
loaded.load("my_module.json")
# For loading entire programs (dspy>=2.6.0)
module.save("./my_module/", save_program=True)
loaded = dspy.load("./my_module/")
```
## Production Example
```python
import dspy
from typing import List, Optional
import logging
logger = logging.getLogger(__name__)
class ProductionRAG(dspy.Module):
"""Production-ready RAG with all best practices."""
def __init__(
self,
retriever_k: int = 5,
cache_enabled: bool = True,
cache_size: int = 1000
):
super().__init__()
# Configuration
self.retriever_k = retriever_k
self.cache_enabled = cache_enabled
self.cache_size = cache_size
# Components
self.retrieve = dspy.Retrieve(k=retriever_k)
self.generate = dspy.ChainOfThought("context, question -> answer")
# State
self.cache = {} if cache_enabled else None
self.call_count = 0
def forward(self, question: str) -> dspy.Prediction:
"""Execute RAG pipeline with caching."""
self.call_count += 1
# Validation
if not question or not question.strip():
return dspy.Prediction(
answer="Please provide a valid question.",
error="Invalid input"
)
# Cache check
if self.cache_enabled and question in self.cache:
logger.info(f"Cache hit (call #{self.call_count})")
return self.cache[question]
# Execute pipeline
try:
passages = self.retrieve(question).passages
if not passages:
logger.warning("No passages retrieved")
return dspy.Prediction(
answer="No relevant information found.",
passages=[]
)
result = self.generate(context=passages, question=question)
result.passages = passages
# Update cache
if self.cache_enabled:
self._update_cache(question, result)
return result
except Exception as e:
logger.error(f"RAG executUse this skill when you need to QA audit and fix a plugin skill file. Provides a methodology for verifying skill content against official documentation, fixing issues in-place, and producing verification reports.
This skill should be used when the user asks to "choose a DSPy adapter", "use JSONAdapter", "use XMLAdapter", "enable native function calling", "send images, audio, or files to DSPy", mentions `dspy.ChatAdapter`, `dspy.JSONAdapter`, `dspy.XMLAdapter`, `dspy.Image`, `dspy.Audio`, `dspy.File`, structured outputs, or multimodal DSPy signatures.
This skill should be used when the user asks to "compose DSPy modules", "use Ensemble optimizer", "combine multiple programs", "use dspy.MultiChainComparison", mentions "ensemble voting", "module composition", "sequential pipelines", or needs to build complex multi-module DSPy programs with ensemble patterns or multi-chain comparison.
This skill should be used when the user asks to "use BetterTogether", "combine prompt optimization and fine-tuning", "sequence DSPy optimizers", "run prompt then weight optimization", mentions `dspy.BetterTogether`, strategy strings such as "p -> w -> p", or needs to compose multiple DSPy teleprompters into an evaluated optimization sequence.
This skill should be used when the user asks to "bootstrap few-shot examples", "generate demonstrations", "use BootstrapFewShot", "optimize with limited data", "create training demos automatically", mentions "teacher model for few-shot", "10-50 training examples", or wants automatic demonstration generation for a DSPy program without extensive compute.
This skill should be used when the user asks to "debug DSPy programs", "trace LLM calls", "monitor production DSPy", "use MLflow with DSPy", mentions "inspect_history", "custom callbacks", "observability", "production monitoring", "cost tracking", or needs to debug, trace, and monitor DSPy applications in development and production.
This skill should be used when the user asks to "build local DSPy retrieval", "use dspy.Embedder", "use dspy.Embeddings", "save an embeddings index", "add FAISS retrieval", mentions semantic search, hosted embeddings, local embedding models, `EmbeddingsWithScores`, or needs a DSPy retriever over an application-owned text corpus.
This skill should be used when the user asks to "evaluate a DSPy program", "test my DSPy module", "measure performance", "create evaluation metrics", "use answer_exact_match or SemanticF1", mentions "Evaluate class", "comparing programs", "establishing baselines", or needs to systematically test and measure DSPy program quality with custom or built-in metrics.