mirror of
https://github.com/NousResearch/hermes-agent.git
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289cc47631
Broad drift audit against origin/main (b52b63396).
Reference pages (most user-visible drift):
- slash-commands: add /busy, /curator, /footer, /indicator, /redraw, /steer
that were missing; drop non-existent /terminal-setup; fix /q footnote
(resolves to /queue, not /quit); extend CLI-only list with all 24
CLI-only commands in the registry
- cli-commands: add dedicated sections for hermes curator / fallback /
hooks (new subcommands not previously documented); remove stale
hermes honcho standalone section (the plugin registers dynamically
via hermes memory); list curator/fallback/hooks in top-level table;
fix completion to include fish
- toolsets-reference: document the real 52-toolset count; split browser
vs browser-cdp; add discord / discord_admin / spotify / yuanbao;
correct hermes-cli tool count from 36 to 38; fix misleading claim
that hermes-homeassistant adds tools (it's identical to hermes-cli)
- tools-reference: bump tool count 55 -> 68; add 7 Spotify, 5 Yuanbao,
2 Discord toolsets; move browser_cdp/browser_dialog to their own
browser-cdp toolset section
- environment-variables: add 40+ user-facing HERMES_* vars that were
undocumented (--yolo, --accept-hooks, --ignore-*, inference model
override, agent/stream/checkpoint timeouts, OAuth trace, per-platform
batch tuning for Telegram/Discord/Matrix/Feishu/WeCom, cron knobs,
gateway restart/connect timeouts); dedupe the Cron Scheduler section;
replace stale QQ_SANDBOX with QQ_PORTAL_HOST
User-guide (top level):
- cli.md: compression preserves last 20 turns, not 4 (protect_last_n: 20)
- configuration.md: display.platforms is the canonical per-platform
override key; tool_progress_overrides is deprecated and auto-migrated
- profiles.md: model.default is the config key, not model.model
- sessions.md: CLI/TUI session IDs use 6-char hex, gateway uses 8
- checkpoints-and-rollback.md: destructive-command list now matches
_DESTRUCTIVE_PATTERNS (adds rmdir, cp, install, dd)
- docker.md: the container runs as non-root hermes (UID 10000) via
gosu; fix install command (uv pip); add missing --insecure on the
dashboard compose example (required for non-loopback bind)
- security.md: systemctl danger pattern also matches 'restart'
- index.md: built-in tool count 47 -> 68
- integrations/index.md: 6 STT providers, 8 memory providers
- integrations/providers.md: drop fictional dashscope/qwen aliases
Features:
- overview.md: 9 image models (not 8), 9 TTS providers (not 5),
8 memory providers (Supermemory was missing)
- tool-gateway.md: 9 image models
- tools.md: extend common-toolsets list with search / messaging /
spotify / discord / debugging / safe
- fallback-providers.md: add 6 real providers from PROVIDER_REGISTRY
(lmstudio, kimi-coding-cn, stepfun, alibaba-coding-plan,
tencent-tokenhub, azure-foundry)
- plugins.md: Available Hooks table now includes on_session_finalize,
on_session_reset, subagent_stop
- built-in-plugins.md: add the 7 bundled plugins the page didn't
mention (spotify, google_meet, three image_gen providers, two
dashboard examples)
- web-dashboard.md: add --insecure and --tui flags
- cron.md: hermes cron create takes positional schedule/prompt, not
flags
Messaging:
- telegram.md: TELEGRAM_WEBHOOK_SECRET is now REQUIRED when
TELEGRAM_WEBHOOK_URL is set (gateway refuses to start without it
per GHSA-3vpc-7q5r-276h). Biggest user-visible drift in the batch.
- discord.md: HERMES_DISCORD_TEXT_BATCH_SPLIT_DELAY_SECONDS default
is 2.0, not 0.1
- dingtalk.md: document DINGTALK_REQUIRE_MENTION /
FREE_RESPONSE_CHATS / MENTION_PATTERNS / HOME_CHANNEL /
ALLOW_ALL_USERS that the adapter supports
- bluebubbles.md: drop fictional BLUEBUBBLES_SEND_READ_RECEIPTS env
var; the setting lives in platforms.bluebubbles.extra only
- qqbot.md: drop dead QQ_SANDBOX; add real QQ_PORTAL_HOST and
QQ_GROUP_ALLOWED_USERS
- wecom-callback.md: replace 'hermes gateway start' (service-only)
with 'hermes gateway' for first-time setup
Developer-guide:
- architecture.md: refresh tool/toolset counts (61/52), terminal
backend count (7), line counts for run_agent.py (~13.7k), cli.py
(~11.5k), main.py (~10.4k), setup.py (~3.5k), gateway/run.py
(~12.2k), mcp_tool.py (~3.1k); add yuanbao adapter, bump platform
adapter count 18 -> 20
- agent-loop.md: run_agent.py line count 10.7k -> 13.7k
- tools-runtime.md: add vercel_sandbox backend
- adding-tools.md: remove stale 'Discovery import added to
model_tools.py' checklist item (registry auto-discovery)
- adding-platform-adapters.md: mark send_typing / get_chat_info as
concrete base methods; only connect/disconnect/send are abstract
- acp-internals.md: ACP sessions now persist to SessionDB
(~/.hermes/state.db); acp.run_agent call uses
use_unstable_protocol=True
- cron-internals.md: gateway runs scheduler in a dedicated background
thread via _start_cron_ticker, not on a maintenance cycle; locking
is cross-process via fcntl.flock (Unix) / msvcrt.locking (Windows)
- gateway-internals.md: gateway/run.py ~12k lines
- provider-runtime.md: cron DOES support fallback (run_job reads
fallback_providers from config)
- session-storage.md: SCHEMA_VERSION = 11 (not 9); add migrations
10 and 11 (trigram FTS, inline-mode FTS5 re-index); add
api_call_count column to Sessions DDL; document messages_fts_trigram
and state_meta in the architecture tree
- context-compression-and-caching.md: remove the obsolete 'context
pressure warnings' section (warnings were removed for causing
models to give up early)
- context-engine-plugin.md: compress() signature now includes
focus_topic param
- extending-the-cli.md: _build_tui_layout_children signature now
includes model_picker_widget; add to default layout
Also fixed three pre-existing broken links/anchors the build warned
about (docker.md -> api-server.md, yuanbao.md -> cron-jobs.md and
tips#background-tasks, nix-setup.md -> #container-aware-cli).
Regenerated per-skill pages via website/scripts/generate-skill-docs.py
so catalog tables and sidebar are consistent with current SKILL.md
frontmatter.
docusaurus build: clean, no broken links or anchors.
16 KiB
16 KiB
title, sidebar_label, description
| title | sidebar_label | description |
|---|---|---|
| Dspy — DSPy: declarative LM programs, auto-optimize prompts, RAG | Dspy | DSPy: declarative LM programs, auto-optimize prompts, RAG |
{/* This page is auto-generated from the skill's SKILL.md by website/scripts/generate-skill-docs.py. Edit the source SKILL.md, not this page. */}
Dspy
DSPy: declarative LM programs, auto-optimize prompts, RAG.
Skill metadata
| Source | Bundled (installed by default) |
| Path | skills/mlops/research/dspy |
| Version | 1.0.0 |
| Author | Orchestra Research |
| License | MIT |
| Dependencies | dspy, openai, anthropic |
| Tags | Prompt Engineering, DSPy, Declarative Programming, RAG, Agents, Prompt Optimization, LM Programming, Stanford NLP, Automatic Optimization, Modular AI |
Reference: full SKILL.md
:::info The following is the complete skill definition that Hermes loads when this skill is triggered. This is what the agent sees as instructions when the skill is active. :::
DSPy: Declarative Language Model Programming
When to Use This Skill
Use DSPy when you need to:
- Build complex AI systems with multiple components and workflows
- Program LMs declaratively instead of manual prompt engineering
- Optimize prompts automatically using data-driven methods
- Create modular AI pipelines that are maintainable and portable
- Improve model outputs systematically with optimizers
- Build RAG systems, agents, or classifiers with better reliability
GitHub Stars: 22,000+ | Created By: Stanford NLP
Installation
# Stable release
pip install dspy
# Latest development version
pip install git+https://github.com/stanfordnlp/dspy.git
# With specific LM providers
pip install dspy[openai] # OpenAI
pip install dspy[anthropic] # Anthropic Claude
pip install dspy[all] # All providers
Quick Start
Basic Example: Question Answering
import dspy
# Configure your language model
lm = dspy.Claude(model="claude-sonnet-4-5-20250929")
dspy.settings.configure(lm=lm)
# Define a signature (input → output)
class QA(dspy.Signature):
"""Answer questions with short factual answers."""
question = dspy.InputField()
answer = dspy.OutputField(desc="often between 1 and 5 words")
# Create a module
qa = dspy.Predict(QA)
# Use it
response = qa(question="What is the capital of France?")
print(response.answer) # "Paris"
Chain of Thought Reasoning
import dspy
lm = dspy.Claude(model="claude-sonnet-4-5-20250929")
dspy.settings.configure(lm=lm)
# Use ChainOfThought for better reasoning
class MathProblem(dspy.Signature):
"""Solve math word problems."""
problem = dspy.InputField()
answer = dspy.OutputField(desc="numerical answer")
# ChainOfThought generates reasoning steps automatically
cot = dspy.ChainOfThought(MathProblem)
response = cot(problem="If John has 5 apples and gives 2 to Mary, how many does he have?")
print(response.rationale) # Shows reasoning steps
print(response.answer) # "3"
Core Concepts
1. Signatures
Signatures define the structure of your AI task (inputs → outputs):
# Inline signature (simple)
qa = dspy.Predict("question -> answer")
# Class signature (detailed)
class Summarize(dspy.Signature):
"""Summarize text into key points."""
text = dspy.InputField()
summary = dspy.OutputField(desc="bullet points, 3-5 items")
summarizer = dspy.ChainOfThought(Summarize)
When to use each:
- Inline: Quick prototyping, simple tasks
- Class: Complex tasks, type hints, better documentation
2. Modules
Modules are reusable components that transform inputs to outputs:
dspy.Predict
Basic prediction module:
predictor = dspy.Predict("context, question -> answer")
result = predictor(context="Paris is the capital of France",
question="What is the capital?")
dspy.ChainOfThought
Generates reasoning steps before answering:
cot = dspy.ChainOfThought("question -> answer")
result = cot(question="Why is the sky blue?")
print(result.rationale) # Reasoning steps
print(result.answer) # Final answer
dspy.ReAct
Agent-like reasoning with tools:
from dspy.predict import ReAct
class SearchQA(dspy.Signature):
"""Answer questions using search."""
question = dspy.InputField()
answer = dspy.OutputField()
def search_tool(query: str) -> str:
"""Search Wikipedia."""
# Your search implementation
return results
react = ReAct(SearchQA, tools=[search_tool])
result = react(question="When was Python created?")
dspy.ProgramOfThought
Generates and executes code for reasoning:
pot = dspy.ProgramOfThought("question -> answer")
result = pot(question="What is 15% of 240?")
# Generates: answer = 240 * 0.15
3. Optimizers
Optimizers improve your modules automatically using training data:
BootstrapFewShot
Learns from examples:
from dspy.teleprompt import BootstrapFewShot
# Training data
trainset = [
dspy.Example(question="What is 2+2?", answer="4").with_inputs("question"),
dspy.Example(question="What is 3+5?", answer="8").with_inputs("question"),
]
# Define metric
def validate_answer(example, pred, trace=None):
return example.answer == pred.answer
# Optimize
optimizer = BootstrapFewShot(metric=validate_answer, max_bootstrapped_demos=3)
optimized_qa = optimizer.compile(qa, trainset=trainset)
# Now optimized_qa performs better!
MIPRO (Most Important Prompt Optimization)
Iteratively improves prompts:
from dspy.teleprompt import MIPRO
optimizer = MIPRO(
metric=validate_answer,
num_candidates=10,
init_temperature=1.0
)
optimized_cot = optimizer.compile(
cot,
trainset=trainset,
num_trials=100
)
BootstrapFinetune
Creates datasets for model fine-tuning:
from dspy.teleprompt import BootstrapFinetune
optimizer = BootstrapFinetune(metric=validate_answer)
optimized_module = optimizer.compile(qa, trainset=trainset)
# Exports training data for fine-tuning
4. Building Complex Systems
Multi-Stage Pipeline
import dspy
class MultiHopQA(dspy.Module):
def __init__(self):
super().__init__()
self.retrieve = dspy.Retrieve(k=3)
self.generate_query = dspy.ChainOfThought("question -> search_query")
self.generate_answer = dspy.ChainOfThought("context, question -> answer")
def forward(self, question):
# Stage 1: Generate search query
search_query = self.generate_query(question=question).search_query
# Stage 2: Retrieve context
passages = self.retrieve(search_query).passages
context = "\n".join(passages)
# Stage 3: Generate answer
answer = self.generate_answer(context=context, question=question).answer
return dspy.Prediction(answer=answer, context=context)
# Use the pipeline
qa_system = MultiHopQA()
result = qa_system(question="Who wrote the book that inspired the movie Blade Runner?")
RAG System with Optimization
import dspy
from dspy.retrieve.chromadb_rm import ChromadbRM
# Configure retriever
retriever = ChromadbRM(
collection_name="documents",
persist_directory="./chroma_db"
)
class RAG(dspy.Module):
def __init__(self, num_passages=3):
super().__init__()
self.retrieve = dspy.Retrieve(k=num_passages)
self.generate = dspy.ChainOfThought("context, question -> answer")
def forward(self, question):
context = self.retrieve(question).passages
return self.generate(context=context, question=question)
# Create and optimize
rag = RAG()
# Optimize with training data
from dspy.teleprompt import BootstrapFewShot
optimizer = BootstrapFewShot(metric=validate_answer)
optimized_rag = optimizer.compile(rag, trainset=trainset)
LM Provider Configuration
Anthropic Claude
import dspy
lm = dspy.Claude(
model="claude-sonnet-4-5-20250929",
api_key="your-api-key", # Or set ANTHROPIC_API_KEY env var
max_tokens=1000,
temperature=0.7
)
dspy.settings.configure(lm=lm)
OpenAI
lm = dspy.OpenAI(
model="gpt-4",
api_key="your-api-key",
max_tokens=1000
)
dspy.settings.configure(lm=lm)
Local Models (Ollama)
lm = dspy.OllamaLocal(
model="llama3.1",
base_url="http://localhost:11434"
)
dspy.settings.configure(lm=lm)
Multiple Models
# Different models for different tasks
cheap_lm = dspy.OpenAI(model="gpt-3.5-turbo")
strong_lm = dspy.Claude(model="claude-sonnet-4-5-20250929")
# Use cheap model for retrieval, strong model for reasoning
with dspy.settings.context(lm=cheap_lm):
context = retriever(question)
with dspy.settings.context(lm=strong_lm):
answer = generator(context=context, question=question)
Common Patterns
Pattern 1: Structured Output
from pydantic import BaseModel, Field
class PersonInfo(BaseModel):
name: str = Field(description="Full name")
age: int = Field(description="Age in years")
occupation: str = Field(description="Current job")
class ExtractPerson(dspy.Signature):
"""Extract person information from text."""
text = dspy.InputField()
person: PersonInfo = dspy.OutputField()
extractor = dspy.TypedPredictor(ExtractPerson)
result = extractor(text="John Doe is a 35-year-old software engineer.")
print(result.person.name) # "John Doe"
print(result.person.age) # 35
Pattern 2: Assertion-Driven Optimization
import dspy
from dspy.primitives.assertions import assert_transform_module, backtrack_handler
class MathQA(dspy.Module):
def __init__(self):
super().__init__()
self.solve = dspy.ChainOfThought("problem -> solution: float")
def forward(self, problem):
solution = self.solve(problem=problem).solution
# Assert solution is numeric
dspy.Assert(
isinstance(float(solution), float),
"Solution must be a number",
backtrack=backtrack_handler
)
return dspy.Prediction(solution=solution)
Pattern 3: Self-Consistency
import dspy
from collections import Counter
class ConsistentQA(dspy.Module):
def __init__(self, num_samples=5):
super().__init__()
self.qa = dspy.ChainOfThought("question -> answer")
self.num_samples = num_samples
def forward(self, question):
# Generate multiple answers
answers = []
for _ in range(self.num_samples):
result = self.qa(question=question)
answers.append(result.answer)
# Return most common answer
most_common = Counter(answers).most_common(1)[0][0]
return dspy.Prediction(answer=most_common)
Pattern 4: Retrieval with Reranking
class RerankedRAG(dspy.Module):
def __init__(self):
super().__init__()
self.retrieve = dspy.Retrieve(k=10)
self.rerank = dspy.Predict("question, passage -> relevance_score: float")
self.answer = dspy.ChainOfThought("context, question -> answer")
def forward(self, question):
# Retrieve candidates
passages = self.retrieve(question).passages
# Rerank passages
scored = []
for passage in passages:
score = float(self.rerank(question=question, passage=passage).relevance_score)
scored.append((score, passage))
# Take top 3
top_passages = [p for _, p in sorted(scored, reverse=True)[:3]]
context = "\n\n".join(top_passages)
# Generate answer
return self.answer(context=context, question=question)
Evaluation and Metrics
Custom Metrics
def exact_match(example, pred, trace=None):
"""Exact match metric."""
return example.answer.lower() == pred.answer.lower()
def f1_score(example, pred, trace=None):
"""F1 score for text overlap."""
pred_tokens = set(pred.answer.lower().split())
gold_tokens = set(example.answer.lower().split())
if not pred_tokens:
return 0.0
precision = len(pred_tokens & gold_tokens) / len(pred_tokens)
recall = len(pred_tokens & gold_tokens) / len(gold_tokens)
if precision + recall == 0:
return 0.0
return 2 * (precision * recall) / (precision + recall)
Evaluation
from dspy.evaluate import Evaluate
# Create evaluator
evaluator = Evaluate(
devset=testset,
metric=exact_match,
num_threads=4,
display_progress=True
)
# Evaluate model
score = evaluator(qa_system)
print(f"Accuracy: {score}")
# Compare optimized vs unoptimized
score_before = evaluator(qa)
score_after = evaluator(optimized_qa)
print(f"Improvement: {score_after - score_before:.2%}")
Best Practices
1. Start Simple, Iterate
# Start with Predict
qa = dspy.Predict("question -> answer")
# Add reasoning if needed
qa = dspy.ChainOfThought("question -> answer")
# Add optimization when you have data
optimized_qa = optimizer.compile(qa, trainset=data)
2. Use Descriptive Signatures
# ❌ Bad: Vague
class Task(dspy.Signature):
input = dspy.InputField()
output = dspy.OutputField()
# ✅ Good: Descriptive
class SummarizeArticle(dspy.Signature):
"""Summarize news articles into 3-5 key points."""
article = dspy.InputField(desc="full article text")
summary = dspy.OutputField(desc="bullet points, 3-5 items")
3. Optimize with Representative Data
# Create diverse training examples
trainset = [
dspy.Example(question="factual", answer="...).with_inputs("question"),
dspy.Example(question="reasoning", answer="...").with_inputs("question"),
dspy.Example(question="calculation", answer="...").with_inputs("question"),
]
# Use validation set for metric
def metric(example, pred, trace=None):
return example.answer in pred.answer
4. Save and Load Optimized Models
# Save
optimized_qa.save("models/qa_v1.json")
# Load
loaded_qa = dspy.ChainOfThought("question -> answer")
loaded_qa.load("models/qa_v1.json")
5. Monitor and Debug
# Enable tracing
dspy.settings.configure(lm=lm, trace=[])
# Run prediction
result = qa(question="...")
# Inspect trace
for call in dspy.settings.trace:
print(f"Prompt: {call['prompt']}")
print(f"Response: {call['response']}")
Comparison to Other Approaches
| Feature | Manual Prompting | LangChain | DSPy |
|---|---|---|---|
| Prompt Engineering | Manual | Manual | Automatic |
| Optimization | Trial & error | None | Data-driven |
| Modularity | Low | Medium | High |
| Type Safety | No | Limited | Yes (Signatures) |
| Portability | Low | Medium | High |
| Learning Curve | Low | Medium | Medium-High |
When to choose DSPy:
- You have training data or can generate it
- You need systematic prompt improvement
- You're building complex multi-stage systems
- You want to optimize across different LMs
When to choose alternatives:
- Quick prototypes (manual prompting)
- Simple chains with existing tools (LangChain)
- Custom optimization logic needed
Resources
- Documentation: https://dspy.ai
- GitHub: https://github.com/stanfordnlp/dspy (22k+ stars)
- Discord: https://discord.gg/XCGy2WDCQB
- Twitter: @DSPyOSS
- Paper: "DSPy: Compiling Declarative Language Model Calls into Self-Improving Pipelines"
See Also
references/modules.md- Detailed module guide (Predict, ChainOfThought, ReAct, ProgramOfThought)references/optimizers.md- Optimization algorithms (BootstrapFewShot, MIPRO, BootstrapFinetune)references/examples.md- Real-world examples (RAG, agents, classifiers)