English

Stateful Inference for Low-Latency Multi-Agent Tool Calling

Machine Learning 2026-05-27 v1

Abstract

Multi-agent tool calling is becoming the dominant interaction pattern for LLM-based systems, yet existing inference frameworks treat each tool call as an independent request, re-processing the entire conversation from scratch even though 85-95% of the prompt is unchanged from the previous turn. We present a stateful inference architecture that converts the O(nt)O(n_t) per-turn cost of conventional serving into an O(Δt)O(\Delta_t) delta-only cost: a persistent KV cache lives across turns and advances by ingesting only the new tokens, while a radix prefix cache extends this across interleaved multi-agent traffic and a prompt-lookup speculative decoder accelerates structured output. Against vLLM and SGLang on novel, fully-generated workloads, the reference implementation is 2.1×2.1\times faster per turn on a 6-turn agentic workflow and 4.2×4.2\times on the median turn of a 35-turn one, halving end-to-end wall time. The advantage comes from stateful reuse and speculation, not caching.

Keywords

Cite

@article{arxiv.2605.26289,
  title  = {Stateful Inference for Low-Latency Multi-Agent Tool Calling},
  author = {Victor Norgren},
  journal= {arXiv preprint arXiv:2605.26289},
  year   = {2026}
}