import os from random import randrange, choice, random, sample from frozendict import frozendict import operators from archive import Archive from instrument import Arg, Params, invoke, call_statement, BranchTransformer, module_of from typing import Tuple, Dict, List, Set Range = Tuple[int, int] INT_RANGE: Range = (-1000, 1000) STRING_LEN_RANGE: Range = (0, 10) STRING_CHAR_RANGE: Range = (32, 127) POOL_SIZE: int = 1000 OUT_DIR = os.path.join(os.path.dirname(__file__), "tests") def random_int() -> int: return randrange(INT_RANGE[0], INT_RANGE[1]) def random_chr() -> str: chr_from, chr_to = STRING_CHAR_RANGE return chr(randrange(chr_from, chr_to)) def random_str() -> str: length = randrange(STRING_LEN_RANGE[0], STRING_LEN_RANGE[1]) return "".join([random_chr() for _ in range(length)]) def max_cases(args: List[Arg]) -> int: num = 1 for _, arg_type in args: if arg_type == 'int': num *= (INT_RANGE[1] - INT_RANGE[0]) elif arg_type == 'str': len_from, len_to = STRING_LEN_RANGE chr_from, chr_to = STRING_CHAR_RANGE num *= sum([(chr_to - chr_from) * length * length for length in range(len_from, len_to)]) else: raise ValueError(f"Arg type '{arg_type}' not supported") return num def random_arg(arg_type: str) -> any: if arg_type == 'str': return random_str() elif arg_type == 'int': return random_int() else: raise ValueError(f"Arg type '{arg_type}' not supported") def random_mutate(arg_type: str, arg_value: any) -> any: if arg_type == 'str': if len(arg_value) == 0: return arg_value prob = 1.0 / len(arg_value) for pos in range(len(arg_value)): if random() < prob: arg_value = list(arg_value) arg_value[pos] = random_chr() arg_value = "".join(arg_value) return arg_value elif arg_type == 'int': delta = randrange(-10, 10) return arg_value + delta else: raise ValueError(f"Arg type '{arg_type}' not supported") def random_params(arguments: List[Arg]) -> Params: test_input: Dict[str, any] = {} for arg_name, arg_type in arguments: test_input[arg_name] = random_arg(arg_type) return frozendict(test_input) pools: Dict[tuple, Set[tuple]] = {} def get_pool(arguments: List[Arg]) -> List[Params]: arg_types = tuple([arg_type for _, arg_type in arguments]) arg_names = [arg_name for arg_name, _ in arguments] # Generate pool if not generated already # The pool only remembers the order of parameters and not their names if arg_types not in pools: new_pool = set() for _ in range(POOL_SIZE): param_list: List[any] = [None] * len(arg_names) params = random_params(arguments) for i, name in enumerate(arg_names): param_list[i] = params[name] new_pool.add(tuple(param_list)) pools[arg_types] = new_pool return [frozendict({arg_names[i]: p for i, p in enumerate(param)}) for param in pools[arg_types]] def mutate(test_case: Params, arguments: List[Arg]) -> Params: arg_name = choice(list(test_case.keys())) # choose name to mutate types: Dict[str, str] = {arg_name: arg_type for arg_name, arg_type in arguments} return test_case.set(arg_name, random_mutate(types[arg_name], test_case[arg_name])) def crossover(chosen_test: Params, other_chosen_test: Params, arguments: List[Arg]) -> Tuple[Params, Params]: # Select a property at random and swap properties arg_name = choice(list(chosen_test.keys())) types: Dict[str, str] = {arg_name: arg_type for arg_name, arg_type in arguments} if types[arg_name] == 'str': # Crossover for strings intermingles the strings of the two chosen tests s1, s2 = str_crossover(chosen_test[arg_name], other_chosen_test[arg_name]) t1 = chosen_test.set(arg_name, s1) t2 = other_chosen_test.set(arg_name, s2) else: # types[arg_name] == 'int' # Crossover for integers swaps the values from the two tests i1, i2 = chosen_test[arg_name], other_chosen_test[arg_name] t1 = chosen_test.set(arg_name, i1) t2 = other_chosen_test.set(arg_name, i2) return t1, t2 def generate_test_case(f_name: str, arguments: List[Arg], archive: Archive) -> Params: pool: List[Params] = get_pool(arguments) while True: test = sample(pool, 1)[0] is_new = archive.satisfies_branch(test) if is_new is None: # print(f"Not new: {test}") continue print(f"New {is_new}!: {test}") try: invoke(f_name, test) return test # return only test cases that satisfy assertions except AssertionError: pass def str_crossover(parent1: str, parent2: str): if len(parent1) > 1 and len(parent2) > 1: pos = randrange(1, len(parent1)) offspring1 = parent1[:pos] + parent2[pos:] offspring2 = parent2[:pos] + parent1[pos:] return offspring1, offspring2 return parent1, parent2 def get_test_case_source(f_name: str, test_case: Params, i: int, indent: int): f_name_orig = BranchTransformer.to_original_name(f_name) single_indent = " " * 4 space = single_indent * indent operators.distances_true_all = {} operators.distances_false_all = {} output = invoke(f_name, test_case) comment = (f"{space}# distances_true = {repr(operators.distances_true_all)}\n" f"{space}# distances_false = {repr(operators.distances_false_all)}\n") return f"""{comment}{space}def test_{f_name_orig}_{i}(self): {space}{single_indent}assert {call_statement(f_name_orig, test_case)} == {repr(output)}""" def get_test_import_stmt(names: List[str]): imports = ["from unittest import TestCase"] for orig_f_name in names: f_name = BranchTransformer.to_instrumented_name(orig_f_name) imports.append(f"from {'.'.join(module_of[f_name])} import {orig_f_name}") return "\n".join(imports) + "\n" def get_test_class(orig_f_name: str, cases: Set[Params]) -> str: f_name = BranchTransformer.to_instrumented_name(orig_f_name) return (f"class Test_{orig_f_name}(TestCase):\n" + "\n\n".join([get_test_case_source(f_name, case, i + 1, 1) for i, case in enumerate(cases)]) + "\n")