Datasets:

rohitspider
/

cross_query_benchmark

---
license: mit
task_categories:
  - text-classification
  - question-answering
language:
  - en
tags:
  - logical-reasoning
  - multi-query
  - consistency
  - satisfiability
  - SAT
  - SMT
  - belief-revision
  - LLM-evaluation
  - benchmark
pretty_name: Cross-Query Contradiction Benchmark
size_categories:
  - 1K<n<10K
configs:
  - config_name: default
    data_files:
      - split: train
        path: benchmark_train_v2.json
      - split: dev
        path: benchmark_dev_v2.json
      - split: test
        path: benchmark_test_v2.json
---

# Cross-Query Contradiction Benchmark

**Quantifying Cross-Query Contradictions in Multi-Query LLM Reasoning**

*Accepted at the ICLR 2026 Workshop on Logical Reasoning of Large Language Models*

> Rohit Kumar Salla (Virginia Tech), Ramya Manasa Amancherla (Columbia University), Manoj Saravanan (Virginia Tech)

---

## Overview

Large language models frequently produce mutually inconsistent answers when reasoning over multiple related queries derived from the same premises. This benchmark evaluates **case-file logical consistency**: whether a model can maintain a globally satisfiable belief state across a bundle of interdependent queries.

The benchmark contains **390 case files** across four reasoning domains, with **2,515 queries** organized into bundles of 5–8 interdependent questions. Every label is **machine-verified via Z3/CaDiCaL solvers**, and each case includes **formal representations** and **cross-query dependency annotations**.

## Key Features

- **Z3-verified labels**: All ENTAILED / CONTRADICTED / UNKNOWN labels are verified by SAT/SMT solvers — not just human annotation
- **Cross-query dependency annotations**: Each query is annotated with which other queries in its bundle it logically interacts with
- **Formal representations**: SMT-LIB and CNF formal encodings included for every case file
- **82.4% unique queries**: Minimal duplication across bundles (vs. typical synthetic benchmarks)
- **Four reasoning domains**: Relational (SAT), Temporal (SMT), Policy/Rules, and Underspecified/Abductive
- **Detailed reasoning traces**: Average 95 characters per query (not trivial one-liners)

## Benchmark Statistics

| | Cases | Bundles | Queries | Logic Fragment |
|---|---|---|---|---|
| **Relational (SAT)** | 120 | 120 | 787 | Propositional (seating, assignment, coloring) |
| **Temporal (SMT)** | 100 | 100 | 637 | Linear arithmetic (scheduling, ordering) |
| **Policy / Rules** | 80 | 80 | 506 | Ground first-order (access control, eligibility) |
| **Underspecified** | 90 | 90 | 585 | Partial information (diagnosis, investigation, fault) |
| **Total** | **390** | **390** | **2,515** | |

### Label Distribution

| Domain | ENTAILED | CONTRADICTED | UNKNOWN |
|---|---|---|---|
| Relational | 16% | 30% | 54% |
| Temporal | 11% | 32% | 57% |
| Policy | 6% | 32% | 62% |
| Underspecified | 18% | 36% | 46% |
| **Overall** | **13%** | **32%** | **55%** |

### Splits

| Split | Cases | Bundles |
|---|---|---|
| Train | 312 | 312 |
| Dev | 39 | 39 |
| Test | 39 | 39 |

Splits are stratified by domain at the case-file level to prevent leakage.

## File Structure

```
cross_query_benchmark/
├── benchmark_full_v2.json        # Complete benchmark (all cases + metadata + statistics)
├── benchmark_train_v2.json       # Training split (312 cases)
├── benchmark_dev_v2.json         # Development split (39 cases)
├── benchmark_test_v2.json        # Test split (39 cases)
├── evaluation_schema_v2.json     # Metric definitions
├── prompt_templates_v2.json      # Prompt templates for extraction & repair
└── README.md
```

## Data Format

### Case File Structure

Each case file in the JSON has the following schema:

```json
{
  "id": "rel_seating_0042",
  "domain": "relational",
  "subdomain": "seating_arrangement",
  "logic_type": "propositional",
  "premises": [
    "There are 5 people seated at a circular table: Alice, Bob, Charlie, Diana, and Eve.",
    "Each person occupies exactly one seat and all seats are distinct.",
    "Alice must sit directly next to Bob.",
    "Charlie must not sit directly next to Diana."
  ],
  "formal_representation": "; Seating: 5 people, circular\n; Variables: pos_X in [0, 4] ...",
  "entities": ["Alice", "Bob", "Charlie", "Diana", "Eve"],
  "bundles": [
    {
      "bundle_id": "bundle_0",
      "num_queries": 6,
      "label_distribution": {"ENTAILED": 2, "CONTRADICTED": 2, "UNKNOWN": 2},
      "queries": [
        {
          "query_id": "q0",
          "query": "Must Alice always be seated next to Bob?",
          "label": "ENTAILED",
          "reasoning": "The premises explicitly require Alice to sit next to Bob, so adjacency is guaranteed in every valid arrangement.",
          "query_type": "adj_forced",
          "depends_on": []
        },
        {
          "query_id": "q1",
          "query": "Can Charlie sit at position 3?",
          "label": "UNKNOWN",
          "reasoning": "Position 3 is available to Charlie in some arrangements but not others, depending on how other constraints resolve.",
          "query_type": "pos",
          "depends_on": [0]
        }
      ]
    }
  ]
}
```

### Field Descriptions

| Field | Description |
|---|---|
| `id` | Unique case identifier (`{domain}_{subdomain}_{index}`) |
| `domain` | One of: `relational`, `temporal`, `policy`, `underspecified` |
| `subdomain` | Specific scenario type (e.g., `seating_arrangement`, `event_scheduling`, `access_control`, `diagnostic`) |
| `logic_type` | Formal logic fragment: `propositional`, `linear_arithmetic`, `first_order_ground`, `partial_information` |
| `premises` | List of natural-language premise strings |
| `formal_representation` | SMT-LIB or CNF-style formal encoding of the case file |
| `entities` | Named entities in the case file |
| `bundles[].queries[].label` | Gold label: `ENTAILED`, `CONTRADICTED`, or `UNKNOWN` |
| `bundles[].queries[].reasoning` | Reasoning trace explaining the label (avg. 95 chars) |
| `bundles[].queries[].depends_on` | Indices of earlier queries in the bundle that this query logically interacts with |
| `bundles[].queries[].query_type` | Query category (e.g., `adj`, `pos`, `overlap`, `order`, `eligible`, `is_guilty`) |

## Evaluation Metrics

### Per-Query Metrics

| Metric | Description |
|---|---|
| **Accuracy** | Fraction of correct labels |
| **Macro-F1** | F1 averaged across ENTAILED, CONTRADICTED, UNKNOWN |
| **Unknown-F1** | F1 for the UNKNOWN class specifically |

### Set-Level Metrics

| Metric | Description | Direction |
|---|---|---|
| **SetConsRate** | Fraction of bundles where the final belief state is satisfiable | ↑ higher is better |
| **AUC-PrefixCons** | Average prefix satisfiability in sequential settings | ↑ higher is better |
| **RevisionCost** | Average commitments revised to restore satisfiability | ↓ lower is better |
| **ContradictionDensity** | Fraction of steps where a new contradiction emerges | ↓ lower is better |

### Compute Metrics

| Metric | Description |
|---|---|
| **Overhead (OH)** | Wall-clock time normalized to No-CoT baseline |
| **Solver calls/bundle** | Average SAT/SMT solver invocations per bundle |

## Quick Start

### Loading the Data

```python
import json

# Load full benchmark
with open("benchmark_full_v2.json") as f:
    benchmark = json.load(f)

print(f"Cases: {benchmark['statistics']['total_cases']}")
print(f"Queries: {benchmark['statistics']['total_queries']}")

# Iterate over cases
for case in benchmark["cases"]:
    print(f"{case['id']}: {case['domain']} / {case['subdomain']}")
    for bundle in case["bundles"]:
        for query in bundle["queries"]:
            print(f"  Q: {query['query']}")
            print(f"  A: {query['label']} | Deps: {query['depends_on']}")
```

### Loading Splits

```python
# Load train/dev/test
for split in ["train", "dev", "test"]:
    with open(f"benchmark_{split}_v2.json") as f:
        data = json.load(f)
    print(f"{split}: {data['num_cases']} cases, {data['num_bundles']} bundles")
```

### Evaluating a Model

```python
def evaluate_bundle(predictions, gold_labels):
    """
    predictions: list of predicted labels (ENTAILED/CONTRADICTED/UNKNOWN)
    gold_labels: list of gold labels
    """
    correct = sum(p == g for p, g in zip(predictions, gold_labels))
    accuracy = correct / len(gold_labels)
    return accuracy

# Per-query evaluation
for case in benchmark["cases"]:
    for bundle in case["bundles"]:
        gold = [q["label"] for q in bundle["queries"]]
        # your_predictions = model.predict(case["premises"], [q["query"] for q in bundle["queries"]])
        # acc = evaluate_bundle(your_predictions, gold)
```

### Using Formal Representations

```python
# Access the formal (SMT-LIB / CNF) encoding for solver-based evaluation
for case in benchmark["cases"]:
    if case["domain"] == "temporal":
        print(case["formal_representation"])
        # Parse and feed to Z3 or CaDiCaL
        break
```

## Prompt Templates

The repository includes prompt templates (`prompt_templates_v2.json`) for three tasks:

1. **Multi-query reasoning**: Main evaluation prompt for LLMs to classify queries
2. **Commitment extraction**: Extracts symbolic commitments (atoms/constraints) from model answers
3. **Repair prompting**: Guides the LLM to propose minimal repairs for conflicting commitments

## Domain Details

### Relational (SAT) — 120 cases
Constraint satisfaction over discrete structures: circular/linear seating arrangements, office/team/color/shift assignments. Constraints include adjacency, non-adjacency, forced assignments, and bans. Verified via propositional SAT (CaDiCaL).

### Temporal (SMT) — 100 cases
Event scheduling with ordering, duration, gap, overlap, and fixed-time constraints over bounded integer timelines. Also includes pure ordering problems with precedence and adjacency constraints. Verified via Z3 with QF\_LIA (linear integer arithmetic).

### Policy / Rules — 80 cases
Role-based access control (grant/deny/conditional rules over roles and resources) and eligibility checking (age/income/experience thresholds for programs). Verified via Z3 with Boolean + integer constraints.

### Underspecified / Abductive — 90 cases
Scenarios with deliberately incomplete information: medical diagnosis (partial symptom observations, exactly-one-condition), criminal investigation (partial evidence, exactly-one-guilty), and system fault diagnosis (partial sensor data, dependency cascades). Designed to produce high UNKNOWN rates by construction.

## Generation and Verification

All case files are **procedurally generated with Z3 solver verification**. The generation pipeline:

1. **Constraint generation**: Random but structurally valid constraint systems per domain
2. **Z3 verification**: Every query label is determined by checking entailment (true in ALL models), contradiction (false in ALL models), or unknown (true in some, false in others)
3. **Quality filtering**: Cases with mono-label bundles or extreme label imbalance are filtered
4. **Dependency annotation**: Cross-query entity sharing is detected and annotated
5. **Deduplication**: Query uniqueness is enforced within and across bundles (82.4% unique)

Generator scripts are available in the repository.

## Paper Results (Summary)

Our solver-augmented belief-state tracking method achieves:

| Method | Acc | SetCons | RevCost | Overhead |
|---|---|---|---|---|
| No-CoT (baseline) | 0.80 | 0.56 | 1.9 | 1.00× |
| CoT | 0.84 | 0.60 | 1.7 | 1.16× |
| Self-Consistency (K=20) | 0.86 | 0.63 | 1.6 | 2.75× |
| **Ours (Check+Repair)** | **0.85** | **0.94** | **0.3** | **1.55×** |

*Results shown for DeepSeek-R1 on the deep evaluation subset. See paper for full results across 8 models.*


## License

This benchmark is released under the [MIT License](LICENSE).

## Contact

- Rohit Kumar Salla — [rohits25@vt.edu](mailto:rohits25@vt.edu)
- Ramya Manasa Amancherla — [ra3439@columbia.edu](mailto:ra3105@columbia.edu)
- Manoj Saravanan — [manoj663@vt.edu](mailto:manoj663@vt.edu)