import itertools import json import multiprocessing import numpy as np from typing import Dict from datasets import load_dataset from .testing_util import run_test DATASET = "codeparrot/apps" TIMEOUT = 10 def check_correctness(sample, generation, timeout, debug=True): """Check correctness of code generation with a global timeout. The global timeout is to catch some extreme/rare cases not handled by the timeouts inside `run_test`""" def _temp_run(sample, generation, debug, result): result.append(run_test(sample, test=generation, debug=debug)) manager = multiprocessing.Manager() result = manager.list() p = multiprocessing.Process(target=_temp_run, args=(sample, generation, debug, result)) p.start() p.join(timeout=timeout + 1) if p.is_alive(): p.kill() if not result: in_outs = json.loads(sample["input_output"]) # consider that all tests failed result = [[-1 for i in range(len(in_outs["inputs"]))]] if debug: print(f"global timeout") return result[0] def evaluate_generations(generations: list, level: str = "all", debug: bool = False): """We take the list of code generations and try to compile them and the run their corresponding unit tests which are retrieved from the APPS dataset. Args: generations: list of code generations (same order as samples in APPS dataset) level: difficulty level used in the generation, can be "all", "introductory", "interview" or "competition" Returns: results: dictionary of results, key is the problem index, value is a list of results for each generation [-2] = compile error, [-1] = runtime error [False] = failed test case [True] = passed test case """ # generations are code generations in the same order of the dataset apps_eval = load_dataset(DATASET, split="test", difficulties=[level]) results = {} for index in range(len(generations)): # code generations for problem (index) problem_generations = generations[index] # get corresponding samples from APPS dataset sample = apps_eval[index] res = [] # loop over the generations for o_idx, o in enumerate(problem_generations): curr_res = [-2] try: curr_res = check_correctness(sample, o, timeout=TIMEOUT, debug=debug) if debug: print(f"\nSuccessful compilation of task {index}!") fixed = [] for e in curr_res: if isinstance(e, np.ndarray): e = e.item(0) if isinstance(e, np.bool_): e = bool(e) fixed.append(e) curr_res = fixed if not np.all(curr_res): if debug: print(f"Results were not True for all test cases") except Exception as e: if debug: print(f"Compilation failed, test framework exception = {repr(e)}{e}\n") break finally: assert isinstance(curr_res, list) res.append(curr_res) results[index] = res return results def estimate_pass_at_k(num_samples, num_correct, k): """Estimates pass@k of each problem and returns them in an array.""" def estimator(n: int, c: int, k: int) -> float: """Calculates 1 - comb(n - c, k) / comb(n, k).""" if n - c < k: return 1.0 return 1.0 - np.prod(1.0 - k / np.arange(n - c + 1, n + 1)) if isinstance(num_samples, int): num_samples_it = itertools.repeat(num_samples, len(num_correct)) else: assert len(num_samples) == len(num_correct) num_samples_it = iter(num_samples) return np.array([estimator(int(n), int(c), k) for n, c in zip(num_samples_it, num_correct)]) def get_results(results: Dict[int, list], count_errors: bool = False, k_list: list = [1, 10, 100]): """ Given the results evaluated against the testcases we output some statistics. For single generations: >>> example_results = {0: [[-2]], 1: [[False,False]], 2: [[True,True]], 3: [[False,True,False,True]], 4: [[-1,-1]]} >>> get_results(example_results, count_errors=True) Computing accuracy metrics... number of compile errors = 1 avg = 0.2 number of runtime errors = 1 avg = 0.2 number of problems evaluated = 5 Average Accuracy : 0.3 Strict Accuracy : 0.2 {'avg_accuracy': 0.3, 'strict_accuracy': 0.2, 'pass_at_k': None} For multiple generations: >>> example_results = {0: [[-2], [True, True, True]], 1: [[-1,-1, -1], [True, False, True]]} >>> get_results(example_results, k_list=[1, 2]) Computing pass@k metric for multiple generations... {'pass@1': 0.25, 'pass@2': 0.5} {'avg_accuracy': None, 'strict_accuracy': None, 'pass_at_k': {'pass@1': 0.25, 'pass@2': 0.5}} """ metrics = {"avg_accuracy": None, "strict_accuracy": None, "pass_at_k": None} if len(results[0]) == 1: # for single generations we compute average accuracy and stric accuracy: original APPS metrics print("Computing accuracy metrics...") res = [] per_prob_res = [] all_correct = [] for index in results: problem_results = np.asarray(results[index]) res.extend(problem_results) per_prob_res.append(np.mean(problem_results > 0)) all_correct.append(np.all(problem_results > 0)) # we count campilation and runtime errors once per pronlem compile_errors = len([e for e in res if -2 in e]) runtime_errors = len([e for e in res if -1 in e]) total_testcases = len(res) if count_errors: print(f"number of compile errors = {compile_errors} avg = {compile_errors / total_testcases}") print(f"number of runtime errors = {runtime_errors} avg = {runtime_errors / total_testcases}") print(f"number of problems evaluated = {total_testcases}") print(f"Average Accuracy : {np.mean(per_prob_res)}") print(f"Strict Accuracy : {np.mean(all_correct)}") metrics["avg_accuracy"] = np.mean(per_prob_res) metrics["strict_accuracy"] = np.mean(all_correct) else: # for multiple generations we use pass@k metric used in the HumanEval benchmark # we use strict accuracy, a generation is valid if it has to pass all the tests print("Computing pass@k metric for multiple generations...") # total is list with nb generations per task (task=index) # correct is number of generations that passed all tests per task total = [] correct = [] for index in results: all_correct = [] for generation in results[index]: gen = np.array(generation) all_correct.append(np.all(gen>0)) total.append(len(all_correct)) correct.append(sum(all_correct)) total = np.array(total) correct = np.array(correct) ks = k_list pass_at_k = {f"pass@{k}": estimate_pass_at_k(total, correct, k).mean() for k in ks if (total >= k).all()} print(pass_at_k) metrics["pass_at_k"] = pass_at_k return metrics def compute_metrics(generations, level="all", k_list=[1, 10, 100], count_errors=True, debug=False): """Return metrics for the given generations. Args: generations: list of code generations for each problem (each generation is a list of generations) k_list: list of k values to compute pass@k when using multiple generations count_errors: whether to count compilation and runtime errors when using single generations level: difficulty level in APPS dataset that was used for the given generations (from: "all", "introductory", "interview", "competition") Returns: metrics: dict of metrics Examples: >>> import json >>> # lists of solutions to the two first APPS problems (note not all solutions pass all tests) >>> solution_sample1 = json.load(open("test_examples/solutions_problem_1.json", "r")) >>> solution_sample2 = json.load(open("test_examples/solutions_problem_2.json", "r")) >>> single_solutions = [solution_sample1[:1], solution_sample2[:1]] >>> compute_metrics(single_solutions, level="all") Computing accuracy metrics... number of compile errors = 0 avg = 0.0 number of runtime errors = 0 avg = 0.0 number of problems evaluated = 2 Average Accuracy : 1.0 Strict Accuracy : 1.0 {'avg_accuracy': 1.0, 'strict_accuracy': 1.0, 'pass_at_k': None} >>> multiple_solutions = [solution_sample1[:3], solution_sample2[:3]] >>> compute_metrics(multiple_solutions, level="all", k_list=[1, 2, 3]) Computing pass@k metric for multiple generations... {'pass@1': 1.0, 'pass@2': 1.0, 'pass@3': 1.0} {'avg_accuracy': None, 'strict_accuracy': None, 'pass_at_k': {'pass@1': 1.0, 'pass@2': 1.0, 'pass@3': 1.0}} """ results = evaluate_generations(generations, level=level, debug=debug) metrics = get_results(results, count_errors=count_errors, k_list=k_list) return metrics # import doctest # doctest.testmod()