#!/usr/bin/env node "use strict"; /** * Strange Loops MCP Server * Provides nano-agent, quantum-classical hybrid computing, and temporal prediction tools */ 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 = Object.create((typeof Iterator === "function" ? Iterator : Object).prototype); return g.next = verb(0), g["throw"] = verb(1), g["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 (g && (g = 0, op[0] && (_ = 0)), _) 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 }; } }; Object.defineProperty(exports, "__esModule", { value: true }); var index_js_1 = require("@modelcontextprotocol/sdk/server/index.js"); var stdio_js_1 = require("@modelcontextprotocol/sdk/server/stdio.js"); var types_js_1 = require("@modelcontextprotocol/sdk/types.js"); // Import our Strange Loop library var StrangeLoop = require('../lib/strange-loop.js'); var StrangeLoopsMCPServer = /** @class */ (function () { function StrangeLoopsMCPServer() { this.isInitialized = false; this.server = new index_js_1.Server({ name: 'strange-loops', version: '0.1.0', }, { capabilities: { tools: {}, }, }); this.setupHandlers(); } StrangeLoopsMCPServer.prototype.setupHandlers = function () { var _this = this; // List available tools this.server.setRequestHandler(types_js_1.ListToolsRequestSchema, function () { return __awaiter(_this, void 0, void 0, function () { return __generator(this, function (_a) { return [2 /*return*/, { tools: [ { name: 'nano_swarm_create', description: 'Create a nano-agent swarm with specified configuration', inputSchema: { type: 'object', properties: { agentCount: { type: 'number', description: 'Number of agents in the swarm', default: 1000, minimum: 1, maximum: 100000 }, topology: { type: 'string', description: 'Swarm topology', enum: ['mesh', 'hierarchical', 'ring', 'star'], default: 'mesh' }, tickDurationNs: { type: 'number', description: 'Tick duration in nanoseconds', default: 25000 } } } }, { name: 'nano_swarm_run', description: 'Run nano-agent swarm simulation for specified duration', inputSchema: { type: 'object', properties: { durationMs: { type: 'number', description: 'Simulation duration in milliseconds', default: 5000, minimum: 100 } }, required: ['durationMs'] } }, { name: 'quantum_container_create', description: 'Create a quantum container for quantum-classical hybrid computing', inputSchema: { type: 'object', properties: { qubits: { type: 'number', description: 'Number of qubits', default: 3, minimum: 1, maximum: 16 } } } }, { name: 'quantum_superposition', description: 'Create quantum superposition across all states', inputSchema: { type: 'object', properties: { qubits: { type: 'number', description: 'Number of qubits for superposition', default: 3 } } } }, { name: 'quantum_measure', description: 'Measure quantum state (collapses superposition)', inputSchema: { type: 'object', properties: { qubits: { type: 'number', description: 'Number of qubits in system', default: 3 } } } }, { name: 'temporal_predictor_create', description: 'Create temporal predictor for future state prediction', inputSchema: { type: 'object', properties: { horizonNs: { type: 'number', description: 'Prediction horizon in nanoseconds', default: 10000000 }, historySize: { type: 'number', description: 'History buffer size', default: 500 } } } }, { name: 'temporal_predict', description: 'Predict future values based on current input', inputSchema: { type: 'object', properties: { currentValues: { type: 'array', items: { type: 'number' }, description: 'Current input values for prediction' }, horizonNs: { type: 'number', description: 'Prediction horizon', default: 10000000 } }, required: ['currentValues'] } }, { name: 'consciousness_evolve', description: 'Evolve temporal consciousness one step', inputSchema: { type: 'object', properties: { maxIterations: { type: 'number', description: 'Maximum evolution iterations', default: 1000 }, enableQuantum: { type: 'boolean', description: 'Enable quantum integration', default: true } } } }, { name: 'system_info', description: 'Get Strange Loops system information and capabilities', inputSchema: { type: 'object', properties: {} } }, { name: 'benchmark_run', description: 'Run comprehensive performance benchmark', inputSchema: { type: 'object', properties: { agentCount: { type: 'number', description: 'Number of agents for benchmark', default: 1000 }, durationMs: { type: 'number', description: 'Benchmark duration in milliseconds', default: 5000 } } } } ] }]; }); }); }); // Handle tool calls this.server.setRequestHandler(types_js_1.CallToolRequestSchema, function (request) { return __awaiter(_this, void 0, void 0, function () { var _a, name, args, _b, swarm, swarm, results, quantum, quantum, quantum, measurement, predictor, predictor, currentValues, prediction, consciousness, state, info, results, error_1; return __generator(this, function (_c) { switch (_c.label) { case 0: _a = request.params, name = _a.name, args = _a.arguments; _c.label = 1; case 1: _c.trys.push([1, 32, , 33]); if (!!this.isInitialized) return [3 /*break*/, 3]; return [4 /*yield*/, StrangeLoop.init()]; case 2: _c.sent(); this.isInitialized = true; _c.label = 3; case 3: _b = name; switch (_b) { case 'nano_swarm_create': return [3 /*break*/, 4]; case 'nano_swarm_run': return [3 /*break*/, 6]; case 'quantum_container_create': return [3 /*break*/, 9]; case 'quantum_superposition': return [3 /*break*/, 11]; case 'quantum_measure': return [3 /*break*/, 14]; case 'temporal_predictor_create': return [3 /*break*/, 18]; case 'temporal_predict': return [3 /*break*/, 20]; case 'consciousness_evolve': return [3 /*break*/, 23]; case 'system_info': return [3 /*break*/, 26]; case 'benchmark_run': return [3 /*break*/, 28]; } return [3 /*break*/, 30]; case 4: return [4 /*yield*/, StrangeLoop.createSwarm({ agentCount: (args === null || args === void 0 ? void 0 : args.agentCount) || 1000, topology: (args === null || args === void 0 ? void 0 : args.topology) || 'mesh', tickDurationNs: (args === null || args === void 0 ? void 0 : args.tickDurationNs) || 25000 })]; case 5: swarm = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, swarm: { agentCount: swarm.config.agentCount, topology: swarm.config.topology, tickDurationNs: swarm.config.tickDurationNs, agents: swarm.agents.length }, message: "Created nano-agent swarm with ".concat(swarm.config.agentCount, " agents") }, null, 2) } ] }]; case 6: return [4 /*yield*/, StrangeLoop.createSwarm({ agentCount: 1000, topology: 'mesh' })]; case 7: swarm = _c.sent(); return [4 /*yield*/, swarm.run((args === null || args === void 0 ? void 0 : args.durationMs) || 5000)]; case 8: results = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, results: { totalTicks: results.totalTicks, agentCount: results.agentCount, runtimeNs: results.runtimeNs, ticksPerSecond: Math.round(results.ticksPerSecond), budgetViolations: results.budgetViolations, avgCyclesPerTick: Math.round(results.avgCyclesPerTick) }, message: "Executed ".concat(results.totalTicks, " ticks at ").concat(Math.round(results.ticksPerSecond), " ticks/sec") }, null, 2) } ] }]; case 9: return [4 /*yield*/, StrangeLoop.createQuantumContainer((args === null || args === void 0 ? void 0 : args.qubits) || 3)]; case 10: quantum = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, quantum: { qubits: quantum.qubits, states: quantum.states, isInSuperposition: quantum.isInSuperposition }, message: "Created quantum container with ".concat(quantum.qubits, " qubits (").concat(quantum.states, " states)") }, null, 2) } ] }]; case 11: return [4 /*yield*/, StrangeLoop.createQuantumContainer((args === null || args === void 0 ? void 0 : args.qubits) || 3)]; case 12: quantum = _c.sent(); return [4 /*yield*/, quantum.createSuperposition()]; case 13: _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, quantum: { qubits: quantum.qubits, states: quantum.states, isInSuperposition: quantum.isInSuperposition }, message: "Created superposition across ".concat(quantum.states, " quantum states") }, null, 2) } ] }]; case 14: return [4 /*yield*/, StrangeLoop.createQuantumContainer((args === null || args === void 0 ? void 0 : args.qubits) || 3)]; case 15: quantum = _c.sent(); return [4 /*yield*/, quantum.createSuperposition()]; case 16: _c.sent(); return [4 /*yield*/, quantum.measure()]; case 17: measurement = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, measurement: { result: measurement, qubits: quantum.qubits, collapsedState: measurement, isInSuperposition: quantum.isInSuperposition }, message: "Quantum measurement collapsed to state ".concat(measurement) }, null, 2) } ] }]; case 18: return [4 /*yield*/, StrangeLoop.createTemporalPredictor({ horizonNs: (args === null || args === void 0 ? void 0 : args.horizonNs) || 10000000, historySize: (args === null || args === void 0 ? void 0 : args.historySize) || 500 })]; case 19: predictor = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, predictor: { horizonNs: predictor.horizonNs, historySize: predictor.historySize, currentHistory: predictor.history.length }, message: "Created temporal predictor with ".concat(predictor.horizonNs, "ns horizon") }, null, 2) } ] }]; case 20: return [4 /*yield*/, StrangeLoop.createTemporalPredictor({ horizonNs: (args === null || args === void 0 ? void 0 : args.horizonNs) || 10000000, historySize: 100 })]; case 21: predictor = _c.sent(); currentValues = (args === null || args === void 0 ? void 0 : args.currentValues) || [1.0, 2.0, 3.0]; return [4 /*yield*/, predictor.predict(currentValues)]; case 22: prediction = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, prediction: { input: currentValues, predicted: prediction, horizonNs: predictor.horizonNs }, message: "Predicted future values with ".concat(predictor.horizonNs / 1000000, "ms temporal lead") }, null, 2) } ] }]; case 23: return [4 /*yield*/, StrangeLoop.createTemporalConsciousness({ maxIterations: (args === null || args === void 0 ? void 0 : args.maxIterations) || 1000, enableQuantum: (args === null || args === void 0 ? void 0 : args.enableQuantum) !== false })]; case 24: consciousness = _c.sent(); return [4 /*yield*/, consciousness.evolveStep()]; case 25: state = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, consciousness: { iteration: state.iteration, consciousnessIndex: state.consciousnessIndex, temporalPatterns: state.temporalPatterns, quantumInfluence: state.quantumInfluence }, message: "Consciousness evolved to iteration ".concat(state.iteration, " with index ").concat(state.consciousnessIndex.toFixed(3)) }, null, 2) } ] }]; case 26: return [4 /*yield*/, StrangeLoop.getSystemInfo()]; case 27: info = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, system: info, message: 'Strange Loops system information retrieved' }, null, 2) } ] }]; case 28: return [4 /*yield*/, StrangeLoop.runBenchmark({ agentCount: (args === null || args === void 0 ? void 0 : args.agentCount) || 1000, duration: (args === null || args === void 0 ? void 0 : args.durationMs) || 5000 })]; case 29: results = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: true, benchmark: { totalTicks: results.totalTicks, agentCount: results.agentCount, runtimeNs: results.runtimeNs, ticksPerSecond: Math.round(results.ticksPerSecond), budgetViolations: results.budgetViolations, performanceRating: results.ticksPerSecond > 500000 ? 'Excellent' : results.ticksPerSecond > 250000 ? 'Good' : 'Fair' }, message: "Benchmark completed: ".concat(Math.round(results.ticksPerSecond), " ticks/sec") }, null, 2) } ] }]; case 30: return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: false, error: "Unknown tool: ".concat(name), availableTools: [ 'nano_swarm_create', 'nano_swarm_run', 'quantum_container_create', 'quantum_superposition', 'quantum_measure', 'temporal_predictor_create', 'temporal_predict', 'consciousness_evolve', 'system_info', 'benchmark_run' ] }, null, 2) } ] }]; case 31: return [3 /*break*/, 33]; case 32: error_1 = _c.sent(); return [2 /*return*/, { content: [ { type: 'text', text: JSON.stringify({ success: false, error: error_1 instanceof Error ? error_1.message : 'Unknown error', tool: name, arguments: args }, null, 2) } ] }]; case 33: return [2 /*return*/]; } }); }); }); }; StrangeLoopsMCPServer.prototype.start = function () { return __awaiter(this, void 0, void 0, function () { var transport; return __generator(this, function (_a) { switch (_a.label) { case 0: transport = new stdio_js_1.StdioServerTransport(); return [4 /*yield*/, this.server.connect(transport)]; case 1: _a.sent(); console.error('Strange Loops MCP Server started'); return [2 /*return*/]; } }); }); }; return StrangeLoopsMCPServer; }()); // Start the server var server = new StrangeLoopsMCPServer(); server.start().catch(function (error) { console.error('Failed to start Strange Loops MCP Server:', error); process.exit(1); });