upper mock

upperHost_stimmock/ssmvep_headless.py

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+"""
+ssmvep_headless.py
+无界面版 SSMVEP 范式通讯流程模拟脚本。
+复现 ssmvep_main.py 的完整指令序列（train 0/1/2, rest, predict, saveData），
+但不依赖 psychopy 也不打开任何窗口/音频，用 time.sleep 替代帧循环等待。
+
+启动顺序:
+    1. runDecoder.py
+    2. datamock.py
+    3. ssmvep_headless.py
+"""
+
+import sys
+import os
+import json
+import time
+import threading
+import zmq
+import numpy as np
+from datetime import datetime
+
+sys.path.append(os.path.dirname(os.path.dirname(os.path.abspath(__file__))))
+from PubLibrary.InifileHelper import IniRead
+
+personname = 'demo'
+session = '01'
+
+DATAMOCK_LABEL_ADDR = 'tcp://127.0.0.1:8101'  # datamock 标签命令地址
+
+
+# ========== ZMQ 结果接收服务 ==========
+class ZmqResultServer(threading.Thread):
+    def __init__(self, port=8088):
+        threading.Thread.__init__(self)
+        self.port = port
+        self.running = True
+        self.energy = 0
+        self.paradigm = 0   # 0=个体校准, 1=康复训练, 2=等待模型训练
+        self.ChoosenNum = -1
+        self.context = zmq.Context()
+        self.socket = self.context.socket(zmq.ROUTER)
+        self.socket.bind(f"tcp://0.0.0.0:{self.port}")
+        self.daemon = True
+        self.trial_idx = 0
+
+    def run(self):
+        print(f"[Server] UpperHost_Server listening on {self.port}")
+        while self.running:
+            try:
+                frames = self.socket.recv_multipart(zmq.NOBLOCK)
+                if len(frames) < 3:
+                    continue
+                message = json.loads(frames[2].decode('utf-8'))
+                method = message.get('method')
+                params = message.get('params')
+                if method == 'energy':
+                    self.energy = params
+                elif method == 'paradigm':
+                    self.paradigm = params
+                    print(f"[Server] paradigm -> {params}")
+                elif method == 'result':
+                    self.ChoosenNum = params
+                    self.trial_idx += 1
+                    print(f"[Server] result={self.ChoosenNum}  (trial {self.trial_idx})")
+            except zmq.Again:
+                time.sleep(0.005)
+            except Exception as e:
+                print(f"[Server] error: {e}")
+
+    def stop(self):
+        self.running = False
+        self.socket.close()
+        self.context.term()
+
+
+# ========== ZMQ 命令发送客户端 ==========
+class ZmqCmdClient:
+    def __init__(self, host, port):
+        self.host = host
+        self.port = port
+        self.context = zmq.Context()
+        self.socket = self.context.socket(zmq.DEALER)
+        # PUSH socket 用于向 datamock.py 发送标签命令
+        self._label_sock = self.context.socket(zmq.PUSH)
+        self._label_sock.connect(DATAMOCK_LABEL_ADDR)
+        print(f"[Client] label PUSH connected to {DATAMOCK_LABEL_ADDR}")
+
+    def connect(self):
+        self.socket.connect(f"tcp://{self.host}:{self.port}")
+        print(f"[Client] connected to {self.host}:{self.port}")
+
+    def start_recv_thread(self, result_server):
+        """启动后台线程，持续接收 decoder 通过 8099 ROUTER 回发的消息，并更新 result_server 的状态"""
+        self._result_server = result_server
+        self._stop_recv = threading.Event()
+
+        def _recv_loop():
+            while not self._stop_recv.is_set():
+                try:
+                    frames = self.socket.recv_multipart(zmq.NOBLOCK)
+                    # DEALER 收到的格式: [b'', json_bytes]
+                    data_bytes = frames[-1]
+                    message = json.loads(data_bytes.decode('utf-8'))
+                    method = message.get('method')
+                    params = message.get('params')
+                    ts = datetime.now().strftime('%H:%M:%S.%f')[:-3]
+                    print(f"[{ts}] [CmdClient] recv: {method}={params}")
+                    if method == 'paradigm':
+                        self._result_server.paradigm = params
+                        print(f"[{ts}] [CmdClient] paradigm updated -> {params}")
+                    elif method == 'result':
+                        self._result_server.ChoosenNum = params
+                        self._result_server.trial_idx += 1
+                        print(f"[{ts}] [CmdClient] result={params} (trial {self._result_server.trial_idx})")
+                    elif method == 'energy':
+                        self._result_server.energy = params
+                except zmq.Again:
+                    time.sleep(0.005)
+                except Exception as e:
+                    print(f"[CmdClient recv] error: {e}")
+                    time.sleep(0.01)
+
+        self._recv_thread = threading.Thread(target=_recv_loop, daemon=True)
+        self._recv_thread.start()
+        print(f"[Client] 后台接收线程已启动（监听 decoder 8099 回发消息）")
+
+    def stop_recv_thread(self):
+        if hasattr(self, '_stop_recv'):
+            self._stop_recv.set()
+
+    def _send_label(self, label_value):
+        """向 datamock.py 发送标签命令"""
+        try:
+            self._label_sock.send_string(str(label_value), zmq.NOBLOCK)
+        except Exception as e:
+            print(f"[Client] label send error: {e}")
+
+    def send_data(self, method, params):
+        msg = {'method': method, 'params': params}
+        try:
+            self.socket.send_multipart([b'', json.dumps(msg).encode('utf-8')])
+            ts = datetime.now().strftime('%H:%M:%S.%f')[:-3]
+            print(f"[{ts}] send_data: {method}={params}")
+            # 根据 train/predict 命令向 datamock 发送标签
+            if method == 'train':
+                if params == 0:
+                    self._send_label(1)
+                    print(f"[Label] train 0 -> datamock label=1")
+                elif params == 1:
+                    self._send_label(2)
+                    print(f"[Label] train 1 -> datamock label=2")
+            elif method == 'predict':
+                self._send_label(99)
+                print(f"[Label] predict -> datamock label=99")
+        except Exception as e:
+            print(f"[Client] send error: {e}")
+
+
+# ========== 主流程 ==========
+def run_headless():
+    server = ZmqResultServer(port=8088)
+    server.start()
+
+    _dh = str(IniRead('system', 'Decoder_Host'))
+    _dp = int(IniRead('system', 'Decoder_Port'))
+    client = ZmqCmdClient(_dh, _dp)
+    client.connect()
+    client.start_recv_thread(server)  # 启动后台接收线程，监听 decoder 8099 回发的 paradigm/result 消息
+
+    time.sleep(1)  # 等待连接建立
+    client.send_data('decoderClass', 'ssmvep')
+
+    train_time   = 2.5   # 每轮训练刺激时长 (s)
+    test_time    = 2.5   # 每轮测试刺激时长 (s)
+    right_rehabilitation = float(IniRead('system', 'Right_rehabilitation'))
+    fault_rehabilitation = float(IniRead('system', 'Fault_rehabilitation'))
+    rest_time    = float(IniRead('system', 'Rest_time'))
+
+    num_blocks = int(IniRead('system', 'Num_blocks'))
+    num_trials = int(IniRead('system', 'Num_trials'))
+
+    position = [0, 1]
+    truePos_seq = position * int(num_trials / len(position))
+    truePos_seq = np.random.permutation(truePos_seq).tolist()
+    user_choice = []
+
+    os.makedirs('EEGFiles', exist_ok=True)
+    seq_file_path = f'EEGFiles/pos_seq_{personname}{session}_{datetime.now().strftime("%Y-%m-%d-%H-%M-%S")}.json'
+    seq_info = {
+        'position': position,
+        'sequence': truePos_seq,
+        'start_time': datetime.now().strftime('%Y-%m-%d %H:%M:%S')
+    }
+    with open(seq_file_path, 'w', encoding='utf-8') as f:
+        json.dump(seq_info, f, ensure_ascii=False, indent=2)
+
+    trained = 0
+    Num_Total = 0
+    Num_Success = 0
+
+    print("=" * 50)
+    print("[Headless] 开始运行 SSMVEP 通讯流程（无界面）")
+    print(f"  num_blocks={num_blocks}, num_trials={num_trials}")
+    print(f"  train_time={train_time}s, test_time={test_time}s")
+    print("=" * 50)
+
+    try:
+        while True:
+            # -------- 个体校准阶段 --------
+            print("\n[Phase] 个体校准阶段 (paradigm=0)")
+            client.send_data('rest', 0)
+            time.sleep(1)
+
+            # epoch完成需要的额外等待时间：train_latency=120包×20ms=2.4s
+            # 在train_time后需再等epoch_wait秒，decoder才能完成epoch采集并取出数据
+            epoch_wait = 2.4  # 秒，与train_latency对应
+
+            while server.paradigm == 0:
+                # 左腿刺激
+                print(f"\n[Train] 左腿刺激 (train 0) trained={trained}")
+                client.send_data('train', 0)
+                time.sleep(train_time + epoch_wait)  # 等待刺激时间+epoch完成时间
+
+                trained += 1
+                client.send_data('rest', 0)
+                time.sleep(max(0, abs(fault_rehabilitation - train_time) - epoch_wait))
+
+                # 右腿刺激
+                print(f"\n[Train] 右腿刺激 (train 1) trained={trained}")
+                client.send_data('train', 1)
+                time.sleep(train_time + epoch_wait)  # 等待刺激时间+epoch完成时间
+
+                trained += 1
+                client.send_data('rest', 0)
+                time.sleep(max(0, fault_rehabilitation - epoch_wait))
+
+            # 个体校准阶段结束
+            print("\n[Phase] 个体校准结束，等待 paradigm=1 ...")
+            trained = 0
+            time.sleep(1)
+
+            # -------- 康复训练阶段 --------
+            while server.paradigm == 1:
+                print("\n[Phase] 康复训练阶段 (paradigm=1)")
+                for block_idx in range(num_blocks):
+                    print(f"\n  [Block {block_idx+1}/{num_blocks}]")
+                    time.sleep(10)  # 每轮开始前等待
+
+                    for trial_idx in range(num_trials):
+                        true_position = truePos_seq[trial_idx]
+                        print(f"  [Trial {trial_idx+1}/{num_trials}] true_pos={true_position}")
+
+                        time.sleep(0.5)  # 提示 + 叮声
+                        server.ChoosenNum = -1
+
+                        # 开始测试
+                        # predict epoch latency = 115包×20ms = 2.3s，需额外等待epoch完成
+                        predict_epoch_wait = 2.3  # 秒，与predict latency=115包对应
+                        client.send_data('predict', 1)
+                        t_start = time.perf_counter()
+                        while time.perf_counter() - t_start < test_time + predict_epoch_wait:
+                            if server.ChoosenNum >= 0:
+                                Num_Total += 1
+                                user_choice.append(server.ChoosenNum)
+                                if server.ChoosenNum in [0, 1]:
+                                    Num_Success += 1
+                                    rest_time = right_rehabilitation
+                                break
+                            time.sleep(0.02)
+
+                        trained += 1
+                        client.send_data('rest', 0)
+                        time.sleep(0.5)
+                        time.sleep(rest_time)
+                        server.ChoosenNum = -1
+
+                # 训练结束
+                print("\n[Phase] 康复训练结束")
+                break  # 退出康复训练循环
+
+            # 统计结果
+            overall_accuracy = Num_Success / Num_Total if Num_Total > 0 else 0
+            expected_seq = truePos_seq * num_blocks
+            min_len = min(len(user_choice), len(expected_seq))
+            same_count = sum(1 for a, b in zip(user_choice[:min_len], expected_seq[:min_len]) if a == b)
+            true_accuracy = same_count / min_len if min_len > 0 else 0
+            print(f"\n[Result] Overall={overall_accuracy:.3f} ({Num_Success}/{Num_Total})")
+            print(f"[Result] TrueAcc={true_accuracy:.3f} ({same_count}/{min_len})")
+            break  # 完成一个完整流程后退出
+
+    except KeyboardInterrupt:
+        print("\n[Headless] 用户中断")
+    finally:
+        client.send_data('predict', 2)   # 关闭系统
+        client.send_data('saveData', 0)
+        server.stop()
+        print("[Headless] 已发送关闭指令，退出。")
+
+
+if __name__ == '__main__':
+    run_headless()