metadata
license: cc-by-4.0
language:
- en
tags:
- Large Language Models
- LLM Evaluation
- Sequential Reasoning
- Scaling Laws
- Synthetic Benchmarks
- Commonsense Reasoning
- Spatial Reasoning
- Knowledge Graphs
SeqBench: A Tunable Benchmark to Quantify Sequential Reasoning Limits of LLMs
Description
SeqBench is a programmatically generated benchmark designed to rigorously evaluate and analyze the sequential reasoning capabilities of language models. Task instances involve pathfinding in 2D grid environments, requiring models to perform multi-step inference over a combination of relevant and distracting textual facts.
The benchmark allows for fine-grained, orthogonal control over key complexity dimensions:
- Logical Depth (L): The number of actions in the ground-truth optimal solution.
- Backtracking Count (B): The number of locked doors on the optimal path that necessitate detours to find corresponding keys.
- Noise Ratio (N): The proportion of distracting (irrelevant) facts relative to supporting (relevant) facts in the problem description.
This dataset (seqBench_compact.jsonl.gz) contains 7079 instances, sampled to provide broad coverage across these complexity dimensions.
Each instance provides:
instance_id: A unique identifier for the specific problem variant.context: The natural language problem description presented to the model.completion: The ground-truth sequence of actions representing the optimal solution.complexity_parameters: A dictionary containing the specific L, B, and N values for the instance.instance_metadata: Additional information, including maze dimensions and agent/target names.structural_details: A JSON string detailing the underlying base maze configuration. This includes room coordinate mappings, adjacency lists, door/key states, and all canonical facts (before noise application).
Dataset Structure and Schema
The dataset is provided in gzipped JSONL format (seqBench_compact.jsonl.gz). Each line is a JSON object representing a single problem instance with the following fields:
instance_id(string): Unique identifier for the problem instance.context(string): Textual problem description.completion(string): Expected sequence of actions (e.g.,"['action1: param1', 'action2: param2', ...]").complexity_parameters(object):logical_depth_L(int64): Logical Depth (L).backtracking_count_B(int64): Backtracking Count (B).noise_ratio_N(float64): Applied Noise Ratio (N).
instance_metadata(object):maze_rows(int64): Number of rows in the maze grid.maze_cols(int64): Number of columns in the maze grid.agent_name(string): Agent's name.target_name(string): Target/victim's name.
structural_details(string): A JSON string containing:mappings(object):coordinate_to_name(object): Maps coordinate strings (e.g., "3,6") to original room identifiers (e.g., "D5").
structure(object):adjacency_list(object): Maps coordinate strings to a list of directly connected coordinate strings.door_details(object): Maps a door identifier string (lexicographically sorted coordinate strings joined by "_", e.g., "3,6_3,7") to an object:{"status": "open" | "closed and locked", "key_id": "string"}.key_locations(object): Maps akey_idstring to the coordinate string of the room containing the key.start_room_coord(string): Coordinate string of the agent's starting room.end_room_coord(string): Coordinate string of the victim's room.
canonical_facts(list): A list of objects, where each object represents a true factual statement about the base maze (before noise/shuffling). Each fact object has:{"type": "string", "args": list_of_strings, "supporting": boolean}. Theargsare specific to thetype(e.g., for "connected_rooms", args might be["coord1_str", "coord2_str", "status_str"]).
A machine-readable metadata file (croissant.json) is included in the metadata/ directory of the main repository to facilitate dataset discovery and integration.
Using structural_details
The structural_details field offers a ground-truth representation of the maze.
import gzip
import json
# Example: Load the first instance and inspect its structural_details
file_path = "seqBench_compact.jsonl.gz" # Path to your dataset file
instance_data = None
try:
with gzip.open(file_path, "rt", encoding="utf-8") as f:
first_line = f.readline()
if first_line:
instance_data = json.loads(first_line)
except FileNotFoundError:
print(f"Error: Dataset file not found at {file_path}")
except Exception as e:
print(f"Error loading dataset: {e}")
if instance_data:
print(f"Instance ID: {instance_data.get('instance_id', 'N/A')}")
# Parse the structural_details string
structural_details_str = instance_data.get("structural_details")
if structural_details_str:
structural_details = json.loads(structural_details_str)
structure = structural_details.get("structure", {})
start_coord_str = structure.get("start_room_coord")
print(f"Start Room Coordinate String: {start_coord_str}")
# Example: Door details for a hypothetical door
# Note: Door keys are formed by sorting coordinate strings and joining with '_'
coord1_str, coord2_str = "3,6", "3,7" # Replace with actual coordinates you want to check
door_dict_key = "_".join(sorted([coord1_str, coord2_str]))
door_info = structure.get("door_details", {}).get(door_dict_key)
if door_info:
print(f"Door info for {door_dict_key}: {door_info}")
else:
print(f"No direct door entry for {door_dict_key} (may not exist or names are different).")
print(f"Key locations: {structure.get('key_locations', {})}")
# print("First canonical fact:", structural_details.get("canonical_facts", [{}])[0])
else:
print("structural_details field is missing or empty.")
# For a deeper understanding of the data generation pipeline and semantics,
# refer to the scripts (`maze.py`, `maze_loader.py`, `rooms.py`)
# available in the main project repository.
Dataset Statistics (for seqBench_compact.jsonl.gz)
- Total Instances: 7079
- Logical Depth (L):
- Range: [3, 774]
- Distribution: Instances span a wide range of L values. For L-bins of size 5 (e.g., L0-4, L5-9, etc.), there are typically 30-80 instances per bin in the lower to mid L-ranges.
- Backtracking Count (B):
- Range: [0, 6]
- Distribution:
- B = 0: 441 instances
- B = 1: 438 instances
- B = 2: 565 instances
- B = 3: 790 instances
- B = 4: 1046 instances
- B = 5: 1601 instances
- B = 6: 2198 instances
- Noise Ratio (N):
- Range: [0.0, 0.2, 0.4, 0.6, 0.8, 1.0]
- Distribution: Instances are approximately evenly distributed across the 6 noise levels, each with roughly 1180 instances.
- Combined Complexity: The dataset is sampled to ensure coverage across (B, N) combinations (typically 60-380 instances per pair) and (L-bin, N) combinations (aiming for approximately 10 instances per L-bin of size 5 for each N, varying with the natural distribution of L).
Generation Process
The benchmark instances are generated through a multi-stage process:
- Base Maze Generation: Acyclic maze graphs are programmatically created on N x M grids.
- Rewind Construction: A target number of backtracking maneuvers (B_target) are embedded by working backward from a goal room, strategically placing keys and locked doors.
- NLP Formulation: For each base maze configuration, a list of canonical facts describing the environment and task is derived.
- Noise Application: A specified
noise_ratio_Nis used to select a proportion of distracting (irrelevant) facts to include alongside supporting (relevant) facts, forming the finalcontext.
Citation
Please cite this work as:
@misc{anonymous2025seqbench,
author = {Anonymous Submission},
title = {SeqBench: A Tunable Benchmark to Quantify Sequential Reasoning Limits of LLMs},
year = {2025},
publisher = {Proceedings of the Conference on Empirical Methods in Natural Language Processing},
note = {Special Theme: Interdisciplinary Recontextualization of NLP},
comment = {Dataset accessible at https://huggingface.co/datasets/emnlp-submission/seqBench}
}