code-complexity
Version:
Measure the churn/complexity score. Higher values mean hotspots where refactorings should happen.
84 lines (83 loc) • 4.23 kB
JavaScript
;
var __awaiter = (this && this.__awaiter) || function (thisArg, _arguments, P, generator) {
function adopt(value) { return value instanceof P ? value : new P(function (resolve) { resolve(value); }); }
return new (P || (P = Promise))(function (resolve, reject) {
function fulfilled(value) { try { step(generator.next(value)); } catch (e) { reject(e); } }
function rejected(value) { try { step(generator["throw"](value)); } catch (e) { reject(e); } }
function step(result) { result.done ? resolve(result.value) : adopt(result.value).then(fulfilled, rejected); }
step((generator = generator.apply(thisArg, _arguments || [])).next());
});
};
var __generator = (this && this.__generator) || function (thisArg, body) {
var _ = { label: 0, sent: function() { if (t[0] & 1) throw t[1]; return t[1]; }, trys: [], ops: [] }, f, y, t, g;
return g = { next: verb(0), "throw": verb(1), "return": verb(2) }, typeof Symbol === "function" && (g[Symbol.iterator] = function() { return this; }), g;
function verb(n) { return function (v) { return step([n, v]); }; }
function step(op) {
if (f) throw new TypeError("Generator is already executing.");
while (_) try {
if (f = 1, y && (t = op[0] & 2 ? y["return"] : op[0] ? y["throw"] || ((t = y["return"]) && t.call(y), 0) : y.next) && !(t = t.call(y, op[1])).done) return t;
if (y = 0, t) op = [op[0] & 2, t.value];
switch (op[0]) {
case 0: case 1: t = op; break;
case 4: _.label++; return { value: op[1], done: false };
case 5: _.label++; y = op[1]; op = [0]; continue;
case 7: op = _.ops.pop(); _.trys.pop(); continue;
default:
if (!(t = _.trys, t = t.length > 0 && t[t.length - 1]) && (op[0] === 6 || op[0] === 2)) { _ = 0; continue; }
if (op[0] === 3 && (!t || (op[1] > t[0] && op[1] < t[3]))) { _.label = op[1]; break; }
if (op[0] === 6 && _.label < t[1]) { _.label = t[1]; t = op; break; }
if (t && _.label < t[2]) { _.label = t[2]; _.ops.push(op); break; }
if (t[2]) _.ops.pop();
_.trys.pop(); continue;
}
op = body.call(thisArg, _);
} catch (e) { op = [6, e]; y = 0; } finally { f = t = 0; }
if (op[0] & 5) throw op[1]; return { value: op[0] ? op[1] : void 0, done: true };
}
};
exports.__esModule = true;
var node_child_process_1 = require("node:child_process");
var node_fs_1 = require("node:fs");
var cli_1 = require("./cli");
var output_1 = require("./output");
var lib_1 = require("../lib");
function main() {
return __awaiter(this, void 0, void 0, function () {
var options, statistics;
return __generator(this, function (_a) {
switch (_a.label) {
case 0: return [4 /*yield*/, cli_1["default"].parse()];
case 1:
options = _a.sent();
warnIfUsingComplexityWithIncompatibleFileTypes(options);
assertGitIsInstalled();
assertIsGitRootDirectory(options.directory);
return [4 /*yield*/, lib_1["default"].compute(options)];
case 2:
statistics = _a.sent();
cli_1["default"].cleanup(options);
output_1["default"].render(statistics, options);
return [2 /*return*/];
}
});
});
}
exports["default"] = main;
function warnIfUsingComplexityWithIncompatibleFileTypes(options) {
if (options.complexityStrategy !== "sloc") {
console.warn("Beware, the 'halstead' and 'cyclomatic' strategies are only available for JavaScript/TypeScript.");
}
}
function assertGitIsInstalled() {
try {
(0, node_child_process_1.execSync)("which git");
}
catch (error) {
throw new Error("Program 'git' must be installed");
}
}
function assertIsGitRootDirectory(directory) {
if (!(0, node_fs_1.existsSync)("".concat(directory, "/.git"))) {
throw new Error("Argument 'dir' must be the git root directory.");
}
}