gluellm 1.1.28

A high-level Python SDK for Large Language Models with automatic tool execution, structured output support, multi-agent workflows, and evaluation data recording

GlueLLM

TL;DR: A high-level Python SDK for LLMs that handles the annoying stuff (tools, retries, structured output, batching) so you can ship features instead of glue code.

GlueLLM is opinionated in the “I’ve been burned by this in production” way. If you like sensible defaults, clear APIs, and fewer bespoke wrappers, you’ll feel at home.

What is this?

GlueLLM is a high-level SDK that makes working with LLMs actually pleasant:

• You call complete() or structured_complete() and get results.
• Tools are plain Python functions.
• Retries and error classification are built-in.
• Batching and rate limiting are first-class.
• Providers are unified via any-llm-sdk.

Why you might like it

• Zero ceremony: minimal code to get real results
• Tool execution loop: automatic tool calling orchestration
• Structured output: Pydantic models, validated (including streaming: parse on final chunk)
• Streaming: stream_complete() with optional structured output on the last chunk
• Process status events: optional on_status callback for LLM/tool/stream progress
• Provider-agnostic: one API for OpenAI, Anthropic, XAI, and others
• Embeddings: same ergonomics + error handling
• Batch processing: concurrency control, retry strategies, key pools
• Observability hooks: logging + optional tracing
• Context condensing (opt-in): compress completed tool rounds to reduce prompt tokens across long tool chains
• Dynamic tool routing (opt-in): route to relevant tools on demand instead of sending all schemas every call

Why you might not

• If you want a thin client that exposes every raw provider knob, GlueLLM isn’t trying to be that.
• If you hate opinions, you’ll hate opinions (mine included).

Installation

# Using uv (recommended)
uv pip install gluellm

# From source (dev)
uv pip install -e ".[dev]"

Quick start

Simple completion

import asyncio
from gluellm.api import complete

async def main():
    result = await complete(
        user_message="What is the capital of France?",
        system_prompt="You are a helpful geography assistant.",
    )
    print(result.final_response)

asyncio.run(main())

Tool calling (tools are just functions)

import asyncio
from gluellm.api import complete

def get_weather(location: str, unit: str = "celsius") -> str:
    """Get the current weather for a location."""
    return f"Weather in {location}: 22°{unit[0].upper()}, sunny"

async def main():
    result = await complete(
        user_message="What's the weather in Tokyo and Paris?",
        system_prompt="Use get_weather for weather queries.",
        tools=[get_weather],
    )
    print(result.final_response)

asyncio.run(main())

Structured output

import asyncio
from pydantic import BaseModel, Field
from typing import Annotated

from gluellm.api import structured_complete

class PersonInfo(BaseModel):
    name: Annotated[str, Field(description="Full name")]
    age: Annotated[int, Field(description="Age in years")]
    city: Annotated[str, Field(description="City of residence")]

async def main():
    person = await structured_complete(
        user_message="Extract info: John Smith, 35, lives in Seattle",
        response_format=PersonInfo,
    )
    print(person.model_dump())

asyncio.run(main())

Streaming

Stream token-by-token with stream_complete(). When tools are enabled, the final response after tool runs is returned as one chunk (streaming resumes between tool rounds).

import asyncio
from gluellm import stream_complete

async def main():
    async for chunk in stream_complete("Tell me a short joke."):
        print(chunk.content, end="", flush=True)
        if chunk.done:
            print(f"\nTool calls: {chunk.tool_calls_made}")

asyncio.run(main())

Streaming + structured output: Pass response_format to get a parsed Pydantic instance on the final chunk (the stream is plain text; we parse when the stream ends).

from pydantic import BaseModel, Field
from gluellm import stream_complete

class Answer(BaseModel):
    word: str

async for chunk in stream_complete(
    "Reply with JSON: {\"word\": \"hello\"}",
    response_format=Answer,
    tools=[],
):
    if chunk.done and chunk.structured_output:
        print(chunk.structured_output.word)  # hello

Context condensing (opt-in)

When a tool round completes, condense_tool_messages=True replaces the raw assistant(tool_calls) + tool(results) messages with a single compact summary. This keeps the prompt from growing linearly with every tool call — useful for long multi-step chains.

Off by default. Enable per-call or on the client:

# Per-call
result = await complete(
    "Do ten things with tools...",
    tools=[...],
    condense_tool_messages=True,  # opt-in
)

# On the client (applies to all calls)
client = GlueLLM(tools=[...], condense_tool_messages=True)
result = await client.complete("Do ten things with tools...")

Without condensing, context grows by 2 messages per tool round (assistant + tool). With condensing, each completed round collapses to 1 message regardless of how many tools ran in parallel.

Dynamic tool routing (opt-in)

In standard mode every LLM call sees the full list of tool schemas in the system prompt. With a large toolset this wastes tokens and increases latency. tool_mode="dynamic" replaces the upfront schema dump with a lightweight router call: the LLM is first asked which tools it needs, then only those schemas are injected for the actual tool execution.

Off by default (tool_mode="standard"). Enable per-call or on the client:

# Per-call
result = await complete(
    "Check the weather and search flights...",
    tools=[get_weather, search_flights, book_hotel, calculate, ...],
    tool_mode="dynamic",  # opt-in
)

# On the client
client = GlueLLM(
    tools=[...],
    tool_mode="dynamic",
    tool_route_model="openai:gpt-4o-mini",  # fast cheap model for routing
)
result = await client.complete("Check the weather and search flights...")

Dynamic routing is most effective when you have 6+ tools and the task only uses a few of them per call. For small toolsets or when every call uses most tools, standard mode is simpler and equally efficient.

Both condense_tool_messages and tool_mode can be combined:

result = await complete(
    "Plan a trip with 9 sequential steps...",
    tools=[...],
    condense_tool_messages=True,
    tool_mode="dynamic",
)

Parallel tool execution (opt-in)

By default, when the model returns multiple tool calls in a single round, they are executed sequentially. Use tool_execution_order="parallel" to run them concurrently (via asyncio.gather), which can reduce latency when tools are I/O-bound.

Off by default (tool_execution_order="sequential"). Enable globally, per client, or per call:

# Per-call
result = await complete("Get weather in Tokyo and Paris", tools=[get_weather], tool_execution_order="parallel")

# On the client
client = GlueLLM(tools=[...], tool_execution_order="parallel")

# Global default (env: GLUELLM_DEFAULT_TOOL_EXECUTION_ORDER)
import gluellm
gluellm.configure(default_tool_execution_order="parallel")

Process status events

Use the optional on_status callback to observe what’s happening (LLM call start/end, tool execution, stream start/chunk/end, completion). Handy for progress UIs or logging.

from gluellm import complete, ProcessEvent

def on_status(e: ProcessEvent) -> None:
    print(f"{e.kind}: {e.tool_name or e.iteration or ''}")

result = await complete(
    "What is 2+2?",
    on_status=on_status,
)
# llm_call_start, llm_call_end, complete (and tool_call_* if tools run)

on_status is supported on complete(), stream_complete(), and structured_complete() (and the GlueLLM client methods).

Timeouts

Two independent timeouts control how long GlueLLM waits for the network:

Parameter	What it governs	Default
connect_timeout	Time to establish the TCP connection	10s
request_timeout	Total time for the full LLM response	60s

Both can be set per-call or left at their defaults (configurable via environment variables):

from gluellm import complete

# Set both per-call
result = await complete(
    "Write a short story.",
    request_timeout=120.0,   # allow 2 minutes for a long generation
    connect_timeout=5.0,     # fail fast if we can't reach the API
)

# Or just one — the other uses its default
result = await complete("Hello", request_timeout=30.0)

On the GlueLLM client, set them per method call:

from gluellm import GlueLLM

client = GlueLLM()
result = await client.complete(
    "Summarise this document...",
    request_timeout=180.0,
    connect_timeout=10.0,
)

A connection timeout raises APIConnectionError; a request timeout raises APITimeoutError (subclass of APIConnectionError). Both are retried by default.

For full details and environment variable configuration, see docs/TIMEOUTS.md.

Retry configuration

Retries are enabled by default (exponential backoff for rate limits and connection errors). You can customise or disable them per client or per call with retry_config and retry_enabled:

from gluellm import complete, GlueLLM, RetryConfig

# Disable retries for a single call
result = await complete("What is 2+2?", retry_enabled=False)

# Or pass a RetryConfig
result = await complete(
    "What is 2+2?",
    retry_config=RetryConfig(retry_enabled=False),
)

# Per-client: disable retries for all calls
client = GlueLLM(retry_config=RetryConfig(retry_enabled=False))

# Filter by exception type (only retry RateLimitError)
from gluellm import RateLimitError
result = await complete(
    "...",
    retry_config=RetryConfig(retry_on=[RateLimitError]),
)

# Custom callback: decide per error and inject params for next attempt
def on_retry(err: Exception, attempt: int) -> tuple[bool, dict | None]:
    if attempt >= 2:
        return False, None  # stop retrying
    return True, {"temperature": 0.0}  # lower temp on retry

result = await complete(
    "...",
    retry_config=RetryConfig(callback=on_retry),
)

When callback is set, it takes precedence over retry_on; the callback receives (error, attempt) and returns (should_retry, next_params | None).

For full details (precedence rules, backoff formula, exception hierarchy), see docs/RETRY.md.

Embeddings

import asyncio
from gluellm import embed

async def main():
    result = await embed("Hello, world!")
    print(result.dimension, result.tokens_used)

    # Request a specific output dimension (OpenAI text-embedding-3-* only)
    result = await embed("Hello, world!", dimensions=512)
    print(result.dimension)  # 512

asyncio.run(main())

The dimensions parameter truncates the output vector — useful for reducing storage costs while preserving most of the semantic signal. You can also set a global default via GLUELLM_DEFAULT_EMBEDDING_DIMENSIONS or gluellm.configure(default_embedding_dimensions=512) so every call uses it without repeating the argument.

Configuration

Providers are configured via environment variables:

export OPENAI_API_KEY=sk-...
export ANTHROPIC_API_KEY=sk-ant-...
export XAI_API_KEY=xai-...

Models use provider:model strings:

• openai:gpt-4o-mini
• anthropic:claude-3-5-sonnet-20241022

Key GlueLLM-specific env vars:

Variable	Default	Description
GLUELLM_DEFAULT_MODEL	openai:gpt-4o-mini	Default model
GLUELLM_DEFAULT_EMBEDDING_MODEL	openai/text-embedding-3-small	Default embedding model
GLUELLM_DEFAULT_EMBEDDING_DIMENSIONS	(unset)	Default output dimensions for embeddings (e.g. 512)
GLUELLM_DEFAULT_REQUEST_TIMEOUT	60.0	Request timeout (seconds)
GLUELLM_MAX_REQUEST_TIMEOUT	300.0	Maximum allowed request timeout
GLUELLM_DEFAULT_CONNECT_TIMEOUT	10.0	Connection timeout (seconds)
GLUELLM_MAX_CONNECT_TIMEOUT	60.0	Maximum allowed connection timeout
GLUELLM_RETRY_MAX_ATTEMPTS	3	Max retry attempts
GLUELLM_RETRY_MIN_WAIT	2	Min backoff seconds
GLUELLM_RETRY_MAX_WAIT	30	Max backoff seconds
GLUELLM_LOG_LEVEL	INFO	Console log level
GLUELLM_LOG_CONSOLE_OUTPUT	false	Enable console output (off by default for library usage)
GLUELLM_DISABLE_LOGGING	false	Disable GlueLLM logging setup (use your app's config)

Docs (when you want the details)

GlueLLM keeps deeper docs in docs/ so the README stays readable:

• docs/ARCHITECTURE.md
• docs/BATCH_PROCESSING.md
• docs/RETRY.md — retry configuration, RetryConfig, callbacks
• docs/ERROR_HANDLING.md — exception hierarchy, classification, handling patterns
• docs/TIMEOUTS.md — connect_timeout, request_timeout, defaults, env vars
• docs/CONNECTION_POOLING.md
• docs/WORKFLOW_PATTERNS.md
• docs/CONTEXT_OPTIMIZATION.md — condensing + dynamic routing deep-dive

More runnable examples live in examples/.

Contributing

PRs welcome. Please read CONTRIBUTING.md.

License

MIT — see LICENSE.