Problem Setting --------------- Consider a CSV file with $N$ rows and $M$ columns, where $M \leq 10$. We feed each row to an LLM inference engine (with a prefix KV cache) by concatenating all column values in that row. For the $i$-th row with entries $A[i,1], A[i,2], \ldots, A[i,M]$, we construct the input string: ```math S_i = \text{Concat}(\text{string}(A[i,1]), \text{string}(A[i,2]), \ldots, \text{string}(A[i,M])) ```` When requesting $S_i$ for $i > 1$, the prefix KV-cache hit rate depends on the longest common prefix with any previously seen request: ```math \text{hit\_rate}_i = \frac{\max_{1 \le j < i} \text{LCP}(S_i, S_j)}{|S_i|} ``` where $LCP(S, T)$ is the length of the longest common prefix between strings $S$ and $T$. You are allowed to reorder the CSV columns. Let $p$ be a permutation of $\{1, 2, ..., M\}$. The reordered string for row $i$ becomes: ```math S'_i = \text{Concat}(\text{string}(A[i,p_1]), \text{string}(A[i,p_2]), \ldots, \text{string}(A[i,p_M])) ``` The goal is to choose a permutation $p$ that maximizes the overall KV-cache hit rate: ```math \max_p\; \frac{\sum_{i=2}^N \max_{1 \le j < i} \text{LCP}(S'_i, S'_j)} {\sum_{i=1}^N |S'_i|} ``` Target --- Maximize prefix hit rate shown above (higher is better) - **Hard Constraint**: Average runtime per dataset must be $\leq 10$ seconds (score = 0 if exceeded) and correctly handle column merge constraint. **Column Merges**: - Column merge specs are provided per dataset - Columns in each merge group are concatenated into a single column - The merged column replaces the original columns - Merge operations are applied before column reordering API Specification --- Implement a `Solution` class: ```python import pandas as pd class Solution: def solve( self, df: pd.DataFrame, early_stop: int = 100000, row_stop: int = 4, col_stop: int = 2, col_merge: list = None, one_way_dep: list = None, distinct_value_threshold: float = 0.7, parallel: bool = True, ) -> pd.DataFrame: """ Reorder columns in the DataFrame to maximize prefix hit rate. Args: df: Input DataFrame to optimize early_stop: Early stopping parameter (default: 100000) row_stop: Row stopping parameter (default: 4) col_stop: Column stopping parameter (default: 2) col_merge: List of column groups to merge (columns in each group are merged into one) one_way_dep: List of one-way dependencies (not used in this variant) distinct_value_threshold: Threshold for distinct values (default: 0.7) parallel: Whether to use parallel processing (default: True) Returns: DataFrame with reordered columns (same rows, different column order) """ # Your implementation pass ``` **Evaluation Process**: 1. Column merges are applied if specified 2. Your `solve()` method reorders the remaining columns 3. Rows are concatenated (no spaces) and prefix hit rate is calculated Scoring (0-100) --- baseline_hit_rate = Average prefix hit rate using original column order (0-point anchor) avg_hit_rate = Your solution's average prefix hit rate across all datasets For each dataset: dataset_score = ((hit_rate - baseline_hit_rate) / (1.0 - baseline_hit_rate)) × 100 final_score = Average of individual dataset scores Score is clamped to [0, 100] range **Runtime Constraint**: - Average runtime per dataset must be ≤ 10 seconds - If average runtime exceeds 10 seconds, score = 0.0 **Scoring Examples**: - baseline_hit_rate = 0.0 (worst), avg_hit_rate = 1.0 (perfect) → Score = 100 - baseline_hit_rate = 0.5, avg_hit_rate = 0.5 → Score = 0 - baseline_hit_rate = 0.5, avg_hit_rate = 0.75 → Score = 50 - baseline_hit_rate = 0.5, avg_hit_rate = 1.0 → Score = 100 Implementation Notes --- - Row values are concatenated without spaces: `"".join(row.values)` - Column reordering should optimize for maximum prefix overlap in the concatenated string representation - Consider column dependencies, distinct value distributions, and merge requirements when reordering - Large datasets with $M > 10$ columns require efficient algorithms due to larger search space - In our smaller dataset, $15k \leq N \leq 28k$ and $4 \leq M \leq 9$ **Example input** please ignore the $> 10$ column number here --- ```csv ID,LIMIT_BAL,SEX,EDUCATION,MARRIAGE,AGE,PAY_0,PAY_2,PAY_3,PAY_4,PAY_5,PAY_6,BILL_AMT1,BILL_AMT2,BILL_AMT3,BILL_AMT4,BILL_AMT5,BILL_AMT6,PAY_AMT1,PAY_AMT2,PAY_AMT3,PAY_AMT4,PAY_AMT5,PAY_AMT6,default payment next month 1,20000,2,2,1,24,2,2,-1,-1,-2,-2,3913,3102,689,0,0,0,0,689,0,0,0,0,1 2,120000,2,2,2,26,-1,2,0,0,0,2,2682,1725,2682,3272,3455,3261,0,1000,1000,1000,0,2000,1 3,90000,2,2,2,34,0,0,0,0,0,0,29239,14027,13559,14331,14948,15549,1518,1500,1000,1000,1000,5000,0 4,50000,2,2,1,37,0,0,0,0,0,0,46990,48233,49291,28314,28959,29547,2000,2019,1200,1100,1069,1000,0 5,50000,1,2,1,57,-1,0,-1,0,0,0,8617,5670,35835,20940,19146,19131,2000,36681,10000,9000,689,679,0 ... ``` **Example output** --- ``` ID,LIMIT_BAL,SEX,EDUCATION,MARRIAGE,AGE,PAY_0,PAY_2,PAY_3,PAY_4,PAY_5,PAY_6,BILL_AMT1,BILL_AMT2,BILL_AMT3,BILL_AMT4,BILL_AMT5,BILL_AMT6,PAY_AMT1,PAY_AMT2,PAY_AMT3,PAY_AMT4,PAY_AMT5,PAY_AMT6,default payment next month 1,20000,2,2,1,24,2,2,-1,-1,-2,-2,3913,3102,689,0,0,0,0,689,0,0,0,0,1 2,120000,2,2,2,26,-1,2,0,0,0,2,2682,1725,2682,3272,3455,3261,0,1000,1000,1000,0,2000,1 3,90000,2,2,2,34,0,0,0,0,0,0,29239,14027,13559,14331,14948,15549,1518,1500,1000,1000,1000,5000,0 4,50000,2,2,1,37,0,0,0,0,0,0,46990,48233,49291,28314,28959,29547,2000,2019,1200,1100,1069,1000,0 5,50000,1,2,1,57,-1,0,-1,0,0,0,8617,5670,35835,20940,19146,19131,2000,36681,10000,9000,689,679,0 ``` ($p$ = $1, 2, \ldots M$)