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KAYROS — exact & anytime solver for duration-minimization time-dependent vehicle routing (TDVRPTW / TDVRP)

Project description

KAYROS

PyPI SWH

KAYROS is an exact & anytime solver for duration-minimization time-dependent vehicle routing problems, TDVRPTW (with time windows) and TDVRP, benchmarked on the canonical MAMUT-routing TD instance families.

The name is a nod to Kairos, the ancient Greek notion of the right, opportune moment, fitting for a time-dependent solver where when each route departs is itself a decision. It is also a recursive acronym: Kayros Anytime-Yielding Routing Optimization Solver.

Status: beta, developed as part of a PhD. Two solving modes on one exact time-dependent engine: an anytime time-dependent iterated local search that produced the large majority of the MAMUT store's best-known solutions, and an audited exact branch-price-and-cut component (kayros.lera) whose multi-gate certification protocol stands behind the store's 468 proven-optimal solutions, 170 of them checker-valid strict improvements. Every run ends with an honest verdict (optimum, time limit, or resource limit), never a silent kill.

Install

pip install kayros    # or: uv add kayros / uv pip install kayros

This pulls everything, including the benchmark loaders and the reference checker (mamut-routing-lib). For development:

git clone https://github.com/0nyr/kayros && cd kayros
pip install -e . --group dev    # pip >= 25.1 (or: uv pip install -e . --group dev)

Requirements: Python ≥ 3.11. Building from source (sdist or checkout) additionally needs a C++23 compiler, CMake ≥ 3.26 (fetched automatically by the build backend when missing) and Boost.Graph headers+library; the HiGHS LP solver is fetched and built statically by CMake when no install is found.

Usage

Anytime heuristic solve: iterated local search over granular candidate lists, streaming every new incumbent:

import kayros

# Any MAMUT-routing TD instance (.vrp.json with its .atf.json sidecar next to it)
instance_path = "benchmarks/TDVRPTW/Dabia2013/n=25/C101.vrp.json"
solution = kayros.solve(instance_path, time_limit=10.0, seed=42)
print(solution.duration, solution.num_routes, solution.status)

# Anytime: react to every new incumbent while the solve keeps running
def on_incumbent(incumbent, routes):
    print(f"[{incumbent.seconds:7.2f}s] {incumbent.value:.6f} ({incumbent.origin})")

solution = kayros.solve(instance_path, time_limit=60.0, on_incumbent=on_incumbent)

The default strategy is "ils" (single-trajectory iterated local search), picked over the alternatives in a 20,808-run head-to-head across five TD families at n=10..1000, with the margin growing with instance size. A MAX-MIN TD ant colony remains available as Params(strategy="aco"), and Params(num_neighbours=0) restores exhaustive (non-granular) local-search enumeration; both are alternatives for experimentation, not defaults.

Exact solve: branch-price-and-cut with checker-exact certificates, optionally warm-started from a known solution (the fast path when certifying near-optimal solutions, e.g. stored best-known ones):

from mamut_routing_lib.td import load_td_instance
from kayros.lera import solve_duration

loaded = load_td_instance(instance_path)
result = solve_duration(loaded, time_limit_s=600.0,
                        initial_routes=[list(r) for r in solution.routes])
print(result["exact_log"]["status"], result["value"])
# status == "Optimum" with routes == [] means: the warm-start solution itself
# is proven optimal. On a time limit, result["exact_log"]["best_bound"] is a
# valid global lower bound when the root relaxation finished (absent otherwise).

solution.duration and result["value"] are always values computed by the reference checker (mamut_routing_lib.td.check_td_solution), never an internal approximation.

Resource limits are verdicts, not crashes: besides the hard time-limit deadline, the exact solve carries a memory self-guard: an RSS watermark polled at the same interruption points as the deadline. When pricing would outgrow the machine (full-horizon TDVRP labeling can exceed any node's RAM), the solve unwinds cleanly with exact_log.status == "MemoryLimitReached", honest bounds, and no certificate. The default limit is resolved from the machine (own RSS + ~80% of available memory, capped by the cgroup limit); solve_duration(memory_limit_mb=...) overrides it, 0 disables.

Design

KAYROS is two solving modes on one exact time-dependent engine:

  • The engine (cpp/pwlf, cpp/core) represents arrival times as non-decreasing continuous piecewise-linear functions (NDCPWLF) and evaluates routes by exact function composition: a bit-identical C++ port of the reference checker's arithmetic (gated by an equivalence suite over the full benchmark set).
  • The anytime stack (kayros.solve): greedy construction and a single-trajectory TD iterated local search (granular ruin-and-recreate kicks, late-acceptance hill climbing, restart-to-best), with a TD ant colony as an alternative strategy, over one time-dependent local-search layer using LCA-BST move evaluation (Blauth et al. 2024) with granular candidate lists: tree-ranked relocate/swap/2-opt* where every accepted move is repriced by the checker-identical fold before it counts.
  • The exact component (kayros.lera): the branch-price-and-cut solver of Lera-Romero, Miranda Bront & Soulignac (2020), vendored under cpp/lera/ (see its NOTICE.md) on the open-source HiGHS LP backend, extended with deadline-compliant anytime behavior, warm starts through columns, TDVRP support, honest time-limit gap reporting, and the memory self-guard. Every column entering the master problem is repriced in the checker's arithmetic, so reported values (and optimality certificates) are checker-exact: optimal under checker-exact route costs and standard LP/pricing tolerances, completeness modulo the search engine's epsilon dominance. On stepwise (value-jump) travel-time functions the labeling switches automatically to an exact value-jump path: the steps' verticals travel through the piecewise-linear machinery as tagged first-class objects (jump vs departure-choice verticals, attained values preserved) instead of being smoothed into steep bridges, so pricing stays complete and stepwise certificates are single-run checker-exact certificates like any other. This path was promoted after a validation ladder ending in a 1444-run four-solve re-certification campaign that re-confirmed 93 stored certificates at their exact stored values with zero checker-infeasible priced columns (cpp/lera/NOTICE.md item 9 records the full history). Turning the LP dual bounds themselves into rigorous certificates (safe bounding) is future work.

Core principles

  • The checker is the referee. Every solution and every certificate is priced by the reference checker of mamut-routing-lib; the checker's value is the value.
  • Exact arithmetic. Plain IEEE-754 doubles, no epsilon comparisons in the engine, no FMA contraction (-ffp-contract=off); results are bit-reproducible across machines.
  • Anytime first. Time budgets are hard deadlines honored by every component (heuristics and exact search alike), and incumbents stream out as they are found; a solver that only answers at the end is not a solver you can interrupt.
  • Honest verdicts. A run ends with an answer: optimum, time limit, or resource limit, with valid bounds where they exist. The solver is never OOM-killed mid-certificate, and it never claims more than its arithmetic supports.
  • One-command install, no proprietary dependency. The default build, including the exact component, is pure open source; HiGHS is built statically into the wheels. The faster CPLEX backend for the BPC remains strictly a source-build opt-in (-DLERA_LP_BACKEND=cplex) and never ships in wheels.
  • One run is one thread. No intra-run parallelism; parallelism belongs to the experiment layer above.
  • POD core. The fresh C++ is plain structs, flat arrays and free functions: optimization-kernel style, no framework (the vendored BPC keeps its upstream style, contained under cpp/lera/).

Archival and reproducibility

kayros is archived by Software Heritage; the badge above tracks the archive status of the GitHub origin (archived origin, archival visits). For academic referencing, prefer Software Heritage identifiers (SWHIDs) of the exact archived revision or release tag over the moving repository origin; when reporting computational results, cite both the kayros release used and the MAMUT-routing benchmark artifacts it was run on.

Branches

Development happens on main. One long-lived branch is deliberately not merged: td-time-warp prototypes penalised exploration of the time-infeasible region (time-warp moves in the local search). A controlled head-to-head found it a no-go for the default solver (parity at best, worse on several families at equal time budgets), so it is kept reachable behind Params for reproducibility rather than merged; the negative result is written up in full as a thesis appendix.

Provenance

KAYROS is developed by Florian Rascoussier (Onyr) as part of a PhD in operations research (IMT Atlantique / INSA Lyon), under the supervision of Romain Billot, Christine Solnon and Lina Fahed. The NDCPWLF composition engine follows Visser & Spliet (2020)'s move-evaluation theorems; the local-search move evaluation follows Blauth et al. (2024); the exact component vendors the branch-price-and-cut solver of Lera-Romero, Miranda Bront & Soulignac (2020, MIT-licensed; provenance and local modifications documented in cpp/lera/NOTICE.md); the TD-ACO is a rewrite of the author's heuristic layer originally built on that same solver. MIT license.

References

  • Gonzalo Lera-Romero, Juan J. Miranda Bront, Francisco J. Soulignac. Linear edge costs and labeling algorithms: The case of the time-dependent vehicle routing problem with time windows. Networks 76(1):24–53, 2020. doi:10.1002/net.21937. Companion code: gleraromero/networks2020 by Gonzalo Lera-Romero, the solver vendored under cpp/lera/. As of 2026-07-18 its only GitHub star is ours: sadly little recognition for such an important project in the time-dependent routing world. Go give it a second one.
  • Thomas R. Visser, Remy Spliet. Efficient move evaluations for time-dependent vehicle routing problems. Transportation Science 54(4):1091–1112, 2020. doi:10.1287/trsc.2019.0938
  • Jannis Blauth, Stephan Held, Dirk Müller, Niklas Schlomberg, Vera Traub, Thorben Tröbst, Jens Vygen. Vehicle routing with time-dependent travel times: Theory, practice, and benchmarks. Discrete Optimization 53:100848, 2024. doi:10.1016/j.disopt.2024.100848

Acknowledgements

  • Romain Billot, Christine Solnon and Lina Fahed, who supervise the PhD this solver is built for.
  • Romain Fontaine, for his help with Grid'5000, where every KAYROS validation and certification campaign runs. This PhD is a multi-vehicle follow-up to his TDTSPTW thesis and its dynamic-programming solver, tdtsptw-ejor23.
  • Gonzalo Lera-Romero, who made his branch-price-and-cut solver open source: a major milestone on the road to this thesis and the direct inspiration for KAYROS's exact component.

Funding

This work is funded by the French National Research Agency (ANR) as part of the MAMUT project, ANR-22-CE22-0016 "Machine learning et matheuristiques pour le transport urbain" (Machine learning And Matheuristics algorithms for Urban Transportation).

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