~chenluhua/Bond2.git

			@@ -3,10 +3,14 @@
			#include "CMaster.h"
			#include <future>
			#include <vector>
			#include <algorithm>
			#include "RecipeManager.h"
			#include <fstream>
			#include "SerializeUtil.h"
			#include "CServoUtilsTool.h"
			#include "AlarmManager.h"
			#include "ToolUnits.h"
			#include "Model.h"


			namespace SERVO {
			@@ -58,6 +62,8 @@
			m_ullStartTime = 0;
			m_ullRunTime = 0;
			m_state = MASTERSTATE::READY;
			m_curveMode = CurveMode::Production;
			m_schedulingMode = SchedulingMode::Production;
			m_pActiveRobotTask = nullptr;
			m_nLastError = ER_CODE_NOERROR;
			m_isCompareMapsBeforeProceeding = FALSE;
			@@ -71,6 +77,8 @@
			m_nContinuousWorkingPort = 0;
			m_nContinuousWorkingSlot = 0;
			m_pControlJob = nullptr;
			m_bPauseAlarmRaised = false;
			m_pModelCtx = nullptr;
			m_nTestFlag = 0;
			InitializeCriticalSection(&m_criticalSection);
			}
			@@ -112,12 +120,18 @@
			m_hEventDispatchThreadExit[1] = nullptr;
			}


			DeleteCriticalSection(&m_criticalSection);
			}

			void CMaster::setListener(MasterListener listener)
			{
			m_listener = listener;
			}

			void CMaster::setModelCtx(CModel* pModel)
			{
			m_pModelCtx = pModel;
			}

			CRobotTask* CMaster::getActiveRobotTask()
			@@ -127,11 +141,18 @@

			int CMaster::init()
			{
			const ULONGLONG boot_master_begin = GetTickCount64();
			LOGI("<Master>正在初始化...");
			LOGI("[BOOT][MASTER] init begin");


			// cclink
			if (m_cclink.Connect(CC_LINK_IE_CONTROL_CHANNEL(1)) != 0) {
			const ULONGLONG boot_cclink_begin = GetTickCount64();
			const int cc_ret = m_cclink.Connect(CC_LINK_IE_CONTROL_CHANNEL(1));
			LOGI("[BOOT][MASTER] CC-Link connect ret=%d, cost=%llu ms",
			cc_ret,
			(unsigned long long)(GetTickCount64() - boot_cclink_begin));
			if (cc_ret != 0) {
			LOGE("连接CC-Link失败.");
			}
			else {
			@@ -220,8 +241,21 @@


			// 读缓存数据
			const ULONGLONG boot_cache_begin = GetTickCount64();
			const ULONGLONG boot_read_begin = GetTickCount64();
			readCache();
			LOGI("[BOOT][MASTER] readCache finished, cost=%llu ms", (unsigned long long)(GetTickCount64() - boot_read_begin));

			const ULONGLONG boot_state_begin = GetTickCount64();
			loadState();
			LOGI("[BOOT][MASTER] loadState finished, cost=%llu ms", (unsigned long long)(GetTickCount64() - boot_state_begin));
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}

			LOGI("[BOOT][MASTER] cache/state loaded, cost=%llu ms (since init %llu ms)",
			(unsigned long long)(GetTickCount64() - boot_cache_begin),
			(unsigned long long)(GetTickCount64() - boot_master_begin));


			// 定时器
			@@ -244,7 +278,50 @@


			LOGI("<Master>初始化完成.");
			LOGI("[BOOT][MASTER] init finished, total cost=%llu ms",
			(unsigned long long)(GetTickCount64() - boot_master_begin));
			return 0;
			}

			void CMaster::setCurveMode(CurveMode mode)
			{
			if (m_curveMode == mode) {
			return;
			}
			m_curveMode = mode;
			if (m_pCollector != nullptr) {
			const uint32_t mids[] = {
			MID_Bonder1, MID_Bonder2,
			MID_VacuumBakeA, MID_VacuumBakeB,
			MID_BakeCoolingA, MID_BakeCoolingB
			};
			for (uint32_t mid : mids) {
			if (mode == CurveMode::EmptyChamber) {
			m_pCollector->batchStart(mid, "EMPTY_CHAMBER", 30 * 60 * 1000ULL); // 空腔模式：启动采样批次
			}
			else {
			m_pCollector->batchStop(mid);
			m_pCollector->buffersClear(mid); // 切回生产模式，清掉空腔数据
			}
			}
			}
			LOGI("<Master>CurveMode=%s", mode == CurveMode::EmptyChamber ? "EmptyChamber" : "Production");
			}

			CurveMode CMaster::getCurveMode() const
			{
			return m_curveMode;
			}

			void CMaster::setSchedulingMode(SchedulingMode mode)
			{
			m_schedulingMode = mode;
			LOGI("<Master>SchedulingMode=%s", mode == SchedulingMode::Production ? "Production" : "Tuning");
			}

			SchedulingMode CMaster::getSchedulingMode() const
			{
			return m_schedulingMode;
			}

			int CMaster::term()
			@@ -272,6 +349,13 @@
			}
			m_listEquipment.clear();

			// release manual-remove buffer before glass pool is torn down
			for (auto* pGlass : m_bufGlass) {
			if (pGlass != nullptr) {
			pGlass->release();
			}
			}
			m_bufGlass.clear();

			if (m_pCollector != nullptr) {
			m_pCollector->stopLoop();
			@@ -674,14 +758,22 @@


			// Measurement -> LoadPort
			for (int s = 0; s < 4; s++) {
			PortType pt = pLoadPorts[s]->getPortType();
			if (!rmd.armState[0] && pLoadPorts[s]->isEnable()
			&& (pt == PortType::Unloading \|\| pt == PortType::Both)
			&& pLoadPorts[s]->getPortStatus() == PORT_INUSE) {
			m_pActiveRobotTask = createTransferTask(pMeasurement, pLoadPorts[s], MaterialsType::G1, secondaryType);
			if (m_pActiveRobotTask != nullptr) {
			goto PORT_PUT;
			if (m_schedulingMode == SchedulingMode::Production) {
			if (!rmd.armState[0]) {
			m_pActiveRobotTask = createTransferTask_returnOrigin(pMeasurement, pLoadPorts);
			CHECK_RUN_ACTIVE_ROBOT_TASK(m_pActiveRobotTask);
			}
			}
			else {
			for (int s = 0; s < 4; s++) {
			PortType pt = pLoadPorts[s]->getPortType();
			if (!rmd.armState[0] && pLoadPorts[s]->isEnable()
			&& (pt == PortType::Unloading \|\| pt == PortType::Both)
			&& pLoadPorts[s]->getPortStatus() == PORT_INUSE) {
			m_pActiveRobotTask = createTransferTask(pMeasurement, pLoadPorts[s], MaterialsType::G1, secondaryType);
			if (m_pActiveRobotTask != nullptr) {
			goto PORT_PUT;
			}
			}
			}
			}
			@@ -878,6 +970,33 @@
			continue;
			}

			// 5.5) 暂停状态检查：若 CJ 或在制 PJ 处于 Paused，暂缓调度新的搬送
			bool pausedByEvent = false;
			if (m_pControlJob != nullptr && m_pControlJob->state() == CJState::Paused) {
			pausedByEvent = true;
			}
			for (auto pj : m_inProcesJobs) {
			if (pj != nullptr && pj->state() == PJState::Paused) {
			pausedByEvent = true;
			break;
			}
			}
			if (!pausedByEvent && m_bPauseAlarmRaised) {
			if (m_pModelCtx != nullptr) {
			m_pModelCtx->clearSoftAlarm(ALID_SOFTWARE_PAUSE_EVENT, 0, 0);
			}
			else {
			AlarmManager& alarmManager = AlarmManager::getInstance();
			alarmManager.clearAlarmByAttributes(ALID_SOFTWARE_PAUSE_EVENT, 0, 0, CToolUnits::getCurrentTimeString());
			}
			m_bPauseAlarmRaised = false;
			}
			if (pausedByEvent) {
			LOGI("<Master>调度暂停：ControlJob/ProcessJob 处于 Paused 状态（可能由 PauseEvent 触发）");
			unlock();
			continue;
			}

			// 6) ——关键：全局统计 G1/G2 与组数门限（与单片分支对齐）——
			auto countG1G2 = [&]() {
			int g1 = 0, g2 = 0;
			@@ -909,19 +1028,27 @@
			// 组数门限：≥2 组时不再从 LP 上片，避免堆积（与单片一致）
			bool blockLoadFromLP = (nGlassGroup >= 2);

			// 7) Measurement -> LoadPort（固定：G1 优先回 LP）
			// 7) Measurement -> LoadPort
			if (rmd.armState[0] \|\| rmd.armState[1]) {
			LOGD("Arm1 %s, Arm2 %s.",
			rmd.armState[0] ? _T("不可用") : _T("可用"),
			rmd.armState[1] ? _T("不可用") : _T("可用"));
			}
			for (int s = 0; s < 4; s++) {
			PortType pt = pLoadPorts[s]->getPortType();
			if (!rmd.armState[0] && pLoadPorts[s]->isEnable()
			&& (pt == PortType::Unloading \|\| pt == PortType::Both)
			&& pLoadPorts[s]->getPortStatus() == PORT_INUSE) {
			m_pActiveRobotTask = createTransferTask(pMeasurement, pLoadPorts[s], MaterialsType::G1, secondaryType);
			if (m_pActiveRobotTask != nullptr) { goto BATCH_PORT_PUT; }
			if (m_schedulingMode == SchedulingMode::Production) {
			if (!rmd.armState[0]) {
			m_pActiveRobotTask = createTransferTask_returnOrigin(pMeasurement, pLoadPorts);
			CHECK_RUN_ACTIVE_ROBOT_TASK(m_pActiveRobotTask);
			}
			}
			else {
			for (int s = 0; s < 4; s++) {
			PortType pt = pLoadPorts[s]->getPortType();
			if (!rmd.armState[0] && pLoadPorts[s]->isEnable()
			&& (pt == PortType::Unloading \|\| pt == PortType::Both)
			&& pLoadPorts[s]->getPortStatus() == PORT_INUSE) {
			m_pActiveRobotTask = createTransferTask(pMeasurement, pLoadPorts[s], MaterialsType::G1, secondaryType);
			if (m_pActiveRobotTask != nullptr) { goto BATCH_PORT_PUT; }
			}
			}
			}

			@@ -1483,6 +1610,7 @@
			this->saveState();
			LOGE("<Master>ProcessJob(%s)完成.",
			pJob->id().c_str());
			processJobFromInPorcessToComplete(pJob);
			if (m_listener.onPjEnd != nullptr) {
			m_listener.onPjEnd(this, pJob);
			}
			@@ -1536,7 +1664,7 @@
			unlock();
			}
			};
			listener.onProcessStateChanged = [&](void* pEquipment, int slotNo, PROCESS_STATE state) -> void {
			listener.onProcessStateChanged = [&](void* pEquipment, int slotNo, PROCESS_STATE prevState, PROCESS_STATE state) -> void {
			ASSERT(1 <= slotNo && slotNo <= 8);
			int eqid = ((CEquipment*)pEquipment)->getID();
			CGlass* pGlass = ((CEquipment*)pEquipment)->getGlassFromSlot(slotNo);
			@@ -1551,6 +1679,15 @@
			if (pGlass != nullptr) {
			m_pCollector->batchStop(SlotToMid(eqid, slotNo));
			}
			}

			if (m_listener.onProcessStateChanged != nullptr) {
			m_listener.onProcessStateChanged(this, (CEquipment*)pEquipment, slotNo, prevState, state);
			}
			};
			listener.onProcessDataReport = [&](void* pEquipment, const std::vector<CParam>& params) {
			if (m_listener.onProcessDataReport != nullptr) {
			m_listener.onProcessDataReport(this, (CEquipment*)pEquipment, params);
			}
			};
			listener.onMapMismatch = [&](void* pEquipment, short scanMap, short downMap) {
			@@ -1624,6 +1761,15 @@
			}
			};
			listener.onSVDataReport = [&](void* pEquipment, void* pData) {
			const bool allowSvLog =
			(m_state == MASTERSTATE::RUNNING \|\|
			m_state == MASTERSTATE::RUNNING_CONTINUOUS_TRANSFER \|\|
			m_state == MASTERSTATE::RUNNING_BATCH \|\|
			m_state == MASTERSTATE::STARTING);
			const bool allowCurve = allowSvLog \|\| (m_curveMode == CurveMode::EmptyChamber);
			if (!allowCurve) {
			return;
			}
			CSVData* pSVData = (CSVData*)pData;
			auto rawData = pSVData->getSVRawData();
			std::vector<CParam> params;
			@@ -1675,18 +1821,23 @@
			int paramIndex = mapping.first;
			int channel = mapping.second;

			if (paramIndex < params.size() && channel - 1 < vacuumbakeTypes.size()) {
			if (paramIndex < params.size()) {
			auto& param = params.at(paramIndex);
			double value = param.getDoubleValue();
			const std::string& dataType = vacuumbakeTypes[channel - 1];
			const std::string& paramName = param.getName();
			const char slotTag = !paramName.empty() ? paramName[0] : '\0';
			const int typeIndex = (slotTag == 'B') ? (channel - 8) : (channel - 1);
			if (typeIndex < 0 \|\| typeIndex >= (int)vacuumbakeTypes.size()) {
			continue;
			}
			const int pushChannel = typeIndex + 1;
			const std::string& dataType = vacuumbakeTypes[typeIndex];

			if (m_pCollector != nullptr) {
			if (slotTag == 'A')
			m_pCollector->buffersPush(SlotToMid(eqid, 1), channel, ts, value);
			m_pCollector->buffersPush(SlotToMid(eqid, 1), pushChannel, ts, value);
			else if (slotTag == 'B')
			m_pCollector->buffersPush(SlotToMid(eqid, 2), channel, ts, value);
			m_pCollector->buffersPush(SlotToMid(eqid, 2), pushChannel, ts, value);
			}

			// 根据腔体前缀写入对应 Slot 的玻璃
			@@ -1720,20 +1871,25 @@
			int paramIndex = mapping.first;
			int channel = mapping.second;

			if (paramIndex < params.size() && channel - 1 < coolingTypes.size()) {
			if (paramIndex < params.size()) {
			auto& param = params.at(paramIndex);
			double value = param.getDoubleValue();
			const std::string& dataType = coolingTypes[channel - 1];
			const std::string& paramName = param.getName();
			const char slotTag = !paramName.empty() ? paramName[0] : '\0';
			const bool paramIsBake = paramName.find("烘烤") != std::string::npos;
			const bool paramIsCooling = paramName.find("冷却") != std::string::npos;
			const int typeIndex = (slotTag == 'B') ? (channel - 7) : (channel - 1);
			if (typeIndex < 0 \|\| typeIndex >= (int)coolingTypes.size()) {
			continue;
			}
			const int pushChannel = typeIndex + 1;
			const std::string& dataType = coolingTypes[typeIndex];

			if (m_pCollector != nullptr && paramIsBake) {
			if (slotTag == 'A')
			m_pCollector->buffersPush(SlotToMid(eqid, 1), channel, ts, value);
			m_pCollector->buffersPush(SlotToMid(eqid, 1), pushChannel, ts, value);
			else if (slotTag == 'B')
			m_pCollector->buffersPush(SlotToMid(eqid, 3), channel, ts, value);
			m_pCollector->buffersPush(SlotToMid(eqid, 3), pushChannel, ts, value);
			}

			if (!dataType.empty()) {
			@@ -1773,6 +1929,10 @@
			strOut.append(szBuffer);
			}
			LOGD("<CMaster-%s>SVDataReport:%s", ((CEquipment*)pEquipment)->getName().c_str(), strOut.c_str());

			if (m_listener.onSVDataReport != nullptr) {
			m_listener.onSVDataReport(this, (CEquipment*)pEquipment, params);
			}
			};
			listener.onPanelDataReport = [&](void* pEquipment, void* pContext) {
			LOGD("<CMaster-%s>onPanelDataReport", ((CEquipment*)pEquipment)->getName().c_str());
			@@ -1792,6 +1952,21 @@
			}
			}

			};
			listener.onReceivedJob = [&](void* pEquipment, int port, CJobDataS* pJobDataS) {
			if (m_listener.onJobReceived != nullptr) {
			m_listener.onJobReceived(this, (CEquipment*)pEquipment, port, pJobDataS);
			}
			};
			listener.onSentOutJob = [&](void* pEquipment, int port, CJobDataS* pJobDataS) {
			if (m_listener.onJobSentOut != nullptr) {
			m_listener.onJobSentOut(this, (CEquipment*)pEquipment, port, pJobDataS);
			}
			};
			listener.onEqStatusChanged = [&](void* pEquipment, int unitId, int status, int reason) {
			if (m_listener.onEqStatusChanged != nullptr) {
			m_listener.onEqStatusChanged(this, (CEquipment*)pEquipment, unitId, status, reason);
			}
			};
			pEquipment->setListener(listener);
			pEquipment->setCcLink(&m_cclink);
			@@ -2031,6 +2206,201 @@
			}


			// 模拟测试（无机器联机时用于联调 EAP）
			// 读取 test.ini（当前目录或 exe 同目录）
			{
			struct SimCfg {
			bool enabled{ false };
			DWORD intervalMs{ 5000 };
			int step{ 0 };
			};
			auto loadCfg = [&]() -> SimCfg {
			SimCfg cfg;

			// Try INI: current dir, then exe dir
			char iniPath[MAX_PATH] = { 0 };
			strcpy_s(iniPath, "test.ini");
			auto readIni = [&](const char* path) -> bool {
			const UINT en = GetPrivateProfileIntA("SimEap", "Enabled", 0, path);
			if (en == 0) return false; // treat as missing/disabled
			cfg.enabled = (en != 0);
			cfg.intervalMs = (DWORD)GetPrivateProfileIntA("SimEap", "IntervalMs", 5000, path);
			cfg.intervalMs = max(500u, cfg.intervalMs);
			cfg.step = (int)GetPrivateProfileIntA("SimEap", "Step", 0, path);
			return true;
			};
			if (!readIni(iniPath)) {
			char exePath[MAX_PATH] = { 0 };
			GetModuleFileNameA(NULL, exePath, MAX_PATH);
			char* lastSlash = strrchr(exePath, '\\');
			if (lastSlash != nullptr) {
			*(lastSlash + 1) = '\0';
			strcat_s(exePath, "test.ini");
			readIni(exePath);
			}
			}
			return cfg;
			};

			const SimCfg cfg = loadCfg();
			if (cfg.enabled) {
			static DWORD lastTick = 0;
			static int lastExecutedStep = -1;
			static bool inited = false;
			static SERVO::CGlass simGlass;
			static SERVO::CVcrEventReport simVcr;
			static SERVO::CProcessJob simPj("PJ1001");
			static SERVO::CControlJob simCj("CJ5007");

			if (!inited) {
			inited = true;
			simGlass.setID("SIM_PANEL_001");
			simVcr.getGlassId() = "SIM_PANEL_001";
			}

			DWORD now = GetTickCount();
			if (lastTick == 0) lastTick = now;
			if ((now - lastTick) < cfg.intervalMs) {
			return;
			}
			lastTick = now;

			// 单步触发：每个 Step 只执行一次；你手动修改 ini 的 Step 值后会再次触发
			const int step = cfg.step;
			if (step <= 0 \|\| step == lastExecutedStep) {
			return;
			}
			lastExecutedStep = step;

			// 取一个 LoadPort 作为模拟目标
			SERVO::CLoadPort* pLpEq = (SERVO::CLoadPort*)getEquipment(EQ_ID_LOADPORT1);

			auto fireLoadPortStatus = [&](short status) {
			pLpEq->simulateSetCassetteId("Test-Cassette-001");
			if (m_listener.onLoadPortStatusChanged != nullptr && pLpEq != nullptr) {
			m_listener.onLoadPortStatusChanged(this, pLpEq, status, 0);
			}
			};
			auto fireProcessState = [&](SERVO::CEquipment* pEq, int slotNo, SERVO::PROCESS_STATE st) {
			// Drive equipment state so listeners receive prev/current states consistently.
			if (pEq != nullptr) {
			pEq->fireSetProcessState(slotNo, st);
			}
			};

			LOGI("<Master>SIM_EAP single-step=%d", step);
			switch (step) {
			// ===== 业务流程步骤（1~23）=====
			case 1: // E87_06 Material Arrived(TransferBlock) -> Port Blocked
			fireLoadPortStatus(PORT_BLOCKED);
			break;
			case 2: // E87_03 CarrierID Readed -> Port InUse
			fireLoadPortStatus(PORT_INUSE);
			break;
			case 3: // S1F3 Query CJ Space (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step3: wait host S1F3");
			break;
			case 4: // S16F21 Query PJ Space (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step4: wait host S16F21");
			break;
			case 5: // S7F19 Query PPID List (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step5: wait host S7F19");
			break;
			case 6: // S3F17 ProceedWithCarrier (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step6: wait host S3F17 ProceedWithCarrier");
			break;
			case 7: // E87_14 Check SlotMap (设备上报/进入 WFH) - 由 PORT_INUSE 内部触发
			fireLoadPortStatus(PORT_INUSE);
			break;
			case 8: // S3F17 ProceedWithSlotMap (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step8: wait host S3F17 ProceedWithSlotMap");
			break;
			case 9: // SlotMap Verify OK (本项目在收到 ProceedWithSlotMap 后上报) - wait host
			LOGI("<Master>SIM_EAP step9: wait host ProceedWithSlotMap to trigger VerifyOK");
			break;
			case 10: // Create PJ (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step10: wait host S16F15 CreateMultiPJ");
			break;
			case 11: // PJ Queued（本项目在创建 PJ 后上报） - wait host
			LOGI("<Master>SIM_EAP step11: wait host CreateMultiPJ to trigger PJ_Queued");
			break;
			case 12: // Create CJ (Host->EQ) - wait host
			LOGI("<Master>SIM_EAP step12: wait host S14F9 CreateCJ");
			break;
			case 13: // CJ Start
			if (m_listener.onCjStart != nullptr) m_listener.onCjStart(this, &simCj);
			break;
			case 14: // PJ Start
			if (m_listener.onPjStart != nullptr) m_listener.onPjStart(this, &simPj);
			break;
			case 15: // OCR
			if (m_listener.onEqVcrEventReport != nullptr && pLpEq != nullptr) {
			m_listener.onEqVcrEventReport(this, pLpEq, &simVcr);
			}
			break;
			case 16: // Panel Start
			if (m_listener.onPanelStart != nullptr) m_listener.onPanelStart(this, &simGlass);
			// 同时触发一次子机台开始（示例：Bonder1, slot 1）
			fireProcessState(getEquipment(EQ_ID_Bonder1), 1, SERVO::PROCESS_STATE::Processing);
			break;
			case 17: // Panel End
			// 同时触发一次子机台结束（示例：Bonder1, slot 1）
			fireProcessState(getEquipment(EQ_ID_Bonder1), 1, SERVO::PROCESS_STATE::Complete);
			if (m_listener.onPanelEnd != nullptr) m_listener.onPanelEnd(this, &simGlass);
			break;
			case 18: // PJ End
			if (m_listener.onPjEnd != nullptr) m_listener.onPjEnd(this, &simPj);
			break;
			case 19: // CJ End
			if (m_listener.onCjEnd != nullptr) m_listener.onCjEnd(this, &simCj);
			break;
			case 20: // Ready to Release (Port Unload Ready; with prev INUSE will also trigger ReadyToRelease)
			fireLoadPortStatus(PORT_UNLOAD_READY);
			break;
			case 21: // CarrierRelease (Host->EQ) - optional / wait host
			LOGI("<Master>SIM_EAP step21: wait host S3F17 CarrierRelease");
			break;
			case 22: // Ready to Unload
			fireLoadPortStatus(PORT_UNLOAD_READY);
			break;
			case 23: // Material Removed (and ReadyToLoad)
			fireLoadPortStatus(PORT_LOAD_READY);
			fireLoadPortStatus(PORT_EMPTY); // will also raise LoadPortNotAssoc via Model
			break;
			case 24: { // 模拟 SV Data（示例：Bonder1）
			SERVO::CEquipment* pEq = getEquipment(EQ_ID_Bonder1);
			if (pEq != nullptr && m_listener.onSVDataReport != nullptr) {
			static int counter = 0;
			++counter;
			std::vector<CParam> params;
			params.emplace_back("MockSV_Temp", "1", "C", 25 + (counter % 5));
			params.emplace_back("MockSV_Pressure", "2", "kPa", 100 + (counter % 3));
			params.emplace_back("MockSV_Speed", "3", "mm/s", 50 + (counter % 7));
			m_listener.onSVDataReport(this, pEq, params);
			LOGI("<Master>SIM_EAP step24: mock SVData (Bonder1), params=%zu", params.size());
			}
			break;
			}
			case 25: { // 模拟 Process Data（示例：Bonder1）
			SERVO::CEquipment* pEq = getEquipment(EQ_ID_Bonder1);
			if (pEq != nullptr && m_listener.onProcessDataReport != nullptr) {
			static int counter = 0;
			++counter;
			std::vector<CParam> params;
			params.emplace_back("MockProc_CycleTime", "1", "s", 30 + (counter % 4));
			params.emplace_back("MockProc_MaxTemp", "2", "C", 200 + (counter % 6));
			params.emplace_back("MockProc_Result", "3", "", (counter % 2) ? 1 : 0);
			m_listener.onProcessDataReport(this, pEq, params);
			LOGI("<Master>SIM_EAP step25: mock ProcessData (Bonder1), params=%zu", params.size());
			}
			break;
			}
			default:
			break;
			}
			}
			}


			// 模拟测试
			/*
			@@ -2107,11 +2477,19 @@

			nRet = pLoadPort1->getPin("Out")->connectPin(pAligner->getPin("In1"));
			if (nRet < 0) {
			LOGE("连接LoadPort1-Fliper失败");
			LOGE("连接LoadPort1-Aligner失败");
			}
			nRet = pLoadPort2->getPin("Out")->connectPin(pAligner->getPin("In2"));
			if (nRet < 0) {
			LOGE("连接LoadPort1-Fliper失败");
			LOGE("连接LoadPort2-Aligner失败");
			}
			nRet = pLoadPort3->getPin("Out")->connectPin(pAligner->getPin("In3"));
			if (nRet < 0) {
			LOGE("连接LoadPort3-Aligner失败");
			}
			nRet = pLoadPort4->getPin("Out")->connectPin(pAligner->getPin("In4"));
			if (nRet < 0) {
			LOGE("连接LoadPort4-Aligner失败");
			}

			nRet = pAligner->getPin("Out1")->connectPin(pFliper->getPin("In"));
			@@ -2156,14 +2534,29 @@
			LOGE("连接BakeCooling-LoadPort3失败");
			}

			nRet = pMeasurement->getPin("Out1")->connectPin(pLoadPort3->getPin("In"));
			if (nRet < 0) {
			LOGE("连接BakeCooling-LoadPort3失败");
			}
			if (m_schedulingMode == SchedulingMode::Production) {
			// 生产模式：测量输出回到 G1 原位（默认 Port1 / Port3）
			nRet = pMeasurement->getPin("Out1")->connectPin(pLoadPort1->getPin("In"));
			if (nRet < 0) {
			LOGE("连接Measurement-LoadPort1失败");
			}

			nRet = pMeasurement->getPin("Out2")->connectPin(pLoadPort4->getPin("In"));
			if (nRet < 0) {
			LOGE("连接BakeCooling-LoadPort4失败");
			nRet = pMeasurement->getPin("Out2")->connectPin(pLoadPort3->getPin("In"));
			if (nRet < 0) {
			LOGE("连接Measurement-LoadPort3失败");
			}
			}
			else {
			// 调机模式：维持原连接（Out1->Port3, Out2->Port4）
			nRet = pMeasurement->getPin("Out1")->connectPin(pLoadPort3->getPin("In"));
			if (nRet < 0) {
			LOGE("连接Measurement-LoadPort3失败");
			}

			nRet = pMeasurement->getPin("Out2")->connectPin(pLoadPort4->getPin("In"));
			if (nRet < 0) {
			LOGE("连接Measurement-LoadPort4失败");
			}
			}
			}

			@@ -2393,6 +2786,57 @@
			return pTask;
			}

			CRobotTask* CMaster::createTransferTask_returnOrigin(CEquipment* pEqSrc, CLoadPort** pPorts)
			{
			if (!pEqSrc->IsEnabled()) {
			return nullptr;
			}

			CSlot* pSrcSlot = pEqSrc->getProcessedSlot(MaterialsType::G1, m_bJobMode);
			if (pSrcSlot == nullptr) {
			return nullptr;
			}

			CGlass* pGlass = (CGlass*)pSrcSlot->getContext();
			if (pGlass == nullptr) {
			return nullptr;
			}

			int port = 0, slot = 0;
			pGlass->getOrginPort(port, slot);
			if (port < 0 \|\| port >= 4 \|\| slot < 0 \|\| slot >= SLOT_MAX) {
			return nullptr;
			}

			CLoadPort* pPort = pPorts[port];
			if (pPort == nullptr \|\| !pPort->isEnable()) {
			return nullptr;
			}
			PortType pt = pPort->getPortType();
			if (!(pt == PortType::Unloading \|\| pt == PortType::Both)) {
			return nullptr;
			}
			if (pPort->getPortStatus() != PORT_INUSE) {
			return nullptr;
			}

			CSlot* pTarSlot = pPort->getSlot(slot);
			if (pTarSlot == nullptr) {
			return nullptr;
			}
			if (!pTarSlot->isEnable() \|\| pTarSlot->isLock() \|\| pTarSlot->getContext() != nullptr) {
			return nullptr;
			}

			CRobotTask* pTask = new CRobotTask();
			pTask->setContext(pSrcSlot->getContext());
			pTask->setEFEM((CEFEM*)getEquipment(EQ_ID_EFEM));
			taskSeqNo = pTask->setRobotTransferParam(taskSeqNo, 1, pSrcSlot->getPosition(),
			pTarSlot->getPosition(), pSrcSlot->getNo(), pTarSlot->getNo());

			return pTask;
			}

			CRobotTask* CMaster::createTransferTask_continuous_transfer(CEquipment* pSrcEq, int nSrcSlot,
			CEquipment* pTarEq, int nTarSlot, int armNo/* = 1*/)
			{
			@@ -2502,6 +2946,19 @@
			pPort->localSetCessetteType(type);
			}

			void CMaster::applySchedulingModePortMapping()
			{
			// 生产模式：固定 Port1/Port3 为 G1，Port2/Port4 为 G2（G4 未定义，按 G2 处理）
			if (m_schedulingMode != SchedulingMode::Production) {
			return;
			}

			setPortCassetteType(0, SERVO::CassetteType::G1);
			setPortCassetteType(1, SERVO::CassetteType::G2);
			setPortCassetteType(2, SERVO::CassetteType::G1);
			setPortCassetteType(3, SERVO::CassetteType::G2);
			}

			void CMaster::setPortEnable(unsigned int index, BOOL bEnable)
			{
			ASSERT(index < 4);
			@@ -2565,7 +3022,40 @@

			static int pid[] = { EQ_ID_LOADPORT1, EQ_ID_LOADPORT2, EQ_ID_LOADPORT3, EQ_ID_LOADPORT4};
			CLoadPort* pPort = (CLoadPort*)getEquipment(pid[port]);
			pPort->sendCassetteCtrlCmd(CCC_PROCESS_START, nullptr, 0, 0, 0, nullptr, nullptr);
			if (pPort == nullptr) return -1;

			short jobExistence[12] = { 0 };
			short slotProcess = 0;
			short jobCount = 0; // 0 = Process All Glass
			bool anyScheduled = false;

			// Prefer hardware scan map for job existence (first 16 slots).
			const short scanMap = pPort->getScanCassetteMap();
			if (scanMap != 0) {
			jobExistence[0] = scanMap;
			}

			const int maxSlots = 12 * 16;
			const int totalSlots = (SLOT_MAX < maxSlots) ? SLOT_MAX : maxSlots;
			for (int slot = 1; slot <= totalSlots; ++slot) {
			CGlass* pGlass = pPort->getGlassFromSlot(slot);
			if (pGlass == nullptr) continue;

			const int wordIndex = (slot - 1) / 16;
			const int bitIndex = (slot - 1) % 16;
			jobExistence[wordIndex] = (short)(jobExistence[wordIndex] \| (1 << bitIndex));

			if (slot <= 16 && pGlass->isScheduledForProcessing()) {
			slotProcess = (short)(slotProcess \| (1 << bitIndex));
			anyScheduled = true;
			}
			}

			if (!anyScheduled) {
			slotProcess = jobExistence[0];
			}

			pPort->sendCassetteCtrlCmd(CCC_PROCESS_START, jobExistence, 12, slotProcess, jobCount, nullptr, nullptr);
			return 0;
			}

			@@ -2600,15 +3090,31 @@
			}
			m_processJobs = temp;

			// 重置各端口 DownloadMap（Host/本地勾选的期望加工槽位）
			for (int i = 0; i < 4; i++) {
			auto* pPort = (CLoadPort*)getEquipment(EQ_ID_LOADPORT1 + i);
			if (pPort != nullptr) {
			pPort->setDownloadCassetteMap(0);
			}
			}


			// 更新context
			std::vector<uint8_t> newSlots;
			std::vector<void*> newContexts;
			for (auto pj : m_processJobs) {
			for (auto& c : pj->carriers()) {
			auto pPort = getPortWithCarrierId(c.carrierId);
			if (pPort == nullptr) continue;

			short downloadMap = 0;
			for (auto s : c.slots) {
			if (s >= 1 && s <= 8) {
			downloadMap \|= (short)(1 << (s - 1));
			}
			}
			pPort->setDownloadCassetteMap((short)(pPort->getDownloadCassetteMap() \| downloadMap));

			std::vector<uint8_t> newSlots;
			std::vector<void*> newContexts;
			for (auto s : c.slots) {
			auto pGlass = pPort->getGlassFromSlot(s);
			if (pGlass == nullptr) continue;
			@@ -2624,6 +3130,9 @@


			this->saveState();
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}

			return (int)m_processJobs.size();
			}
			@@ -2681,6 +3190,9 @@
			}
			m_pControlJob->setPJs(temps);
			this->saveState();
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}


			return 0;
			@@ -2733,7 +3245,98 @@

			bool CMaster::ceidDefined(uint32_t ceid) const
			{
			return true;
			if (m_allowedCeids.empty()) return true; // backward compatible: treat as all allowed when not configured
			return m_allowedCeids.find(ceid) != m_allowedCeids.end();
			}

			bool CMaster::raiseSoftAlarm(int alarmId,
			const std::string& desc,
			int level/* = -1*/,
			int deviceId/* = 0*/,
			int unitId/* = 0*/,
			const char* deviceName/* = "Software"*/,
			const char* unitName/* = "App"*/)
			{
			AlarmManager& alarmManager = AlarmManager::getInstance();
			const AlarmInfo* info = alarmManager.getAlarmInfoByID(alarmId);

			int severity = level;
			if (severity < 0 && info != nullptr) {
			severity = info->nAlarmLevel;
			}
			if (severity < 0) severity = 0; // fallback

			std::string descText = desc;
			if (descText.empty() && info != nullptr) {
			descText = !info->strDescription.empty() ? info->strDescription : info->strAlarmText;
			}
			if (descText.empty()) {
			descText = CToolUnits::formatString("Alarm %d", alarmId);
			}

			AlarmData alarmData;
			alarmData.nId = alarmId;
			alarmData.nSeverityLevel = severity;
			alarmData.nDeviceId = deviceId;
			alarmData.nUnitId = unitId;
			alarmData.strDeviceName = deviceName;
			alarmData.strUnitName = unitName;
			alarmData.strStartTime = CToolUnits::timeToString2(CToolUnits::getTimestamp());
			alarmData.strEndTime = "";
			alarmData.strDescription = descText;

			int nAlarmEventId = 0;
			return alarmManager.addAlarm(alarmData, nAlarmEventId);
			}

			void CMaster::handleCollectionEvent(uint32_t ceid)
			{
			// 遍历当前 PJ，命中 pauseEvents 时可在此扩展暂停动作
			bool pausedAny = false;
			for (auto pj : m_processJobs) {
			if (pj == nullptr) continue;
			const auto& pauseList = pj->pauseEvents();
			if (std::find(pauseList.begin(), pauseList.end(), ceid) != pauseList.end()) {
			LOGW("<Master>PauseEvent hit: CEID=%u, PJ=%s, state=%d", ceid, pj->id().c_str(), (int)pj->state());
			if (pj->pause()) {
			LOGI("<Master>PJ paused by CEID=%u", ceid);
			pausedAny = true;
			}
			if (m_pControlJob != nullptr && m_pControlJob->state() == CJState::Executing) {
			if (m_pControlJob->pause()) {
			LOGI("<Master>ControlJob paused by CEID=%u", ceid);
			pausedAny = true;
			}
			}
			}
			}
			if (pausedAny && m_listener.onControlJobChanged) {
			// 通知应用层刷新 UI/按钮状态
			notifyControlJobChanged();
			}
			if (pausedAny && !m_bPauseAlarmRaised) {
			std::string desc = CToolUnits::formatString("<PauseEvent CEID=%u>", ceid);
			bool raised = false;
			if (m_pModelCtx != nullptr) {
			raised = m_pModelCtx->raiseSoftAlarm(ALID_SOFTWARE_PAUSE_EVENT, desc);
			}
			else {
			raised = raiseSoftAlarm(ALID_SOFTWARE_PAUSE_EVENT, desc);
			}
			if (raised) {
			LOGI("<Master>PauseEvent soft alarm raised, CEID=%u", ceid);
			m_bPauseAlarmRaised = true;
			}
			}
			}

			void CMaster::setAllowedCeids(const std::vector<unsigned int>& ceids)
			{
			m_allowedCeids.clear();
			m_allowedCeids.reserve(ceids.size());
			for (auto id : ceids) {
			m_allowedCeids.insert(id);
			}
			}

			bool CMaster::saveState() const
			@@ -3023,6 +3626,9 @@


			saveState();
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}

			return true;
			}
			@@ -3036,6 +3642,11 @@
			item->abort(description);
			}
			m_pControlJob->abort(description);

			// 先上报一次状态变化（便于 PrJobAbort 触发）
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}


			// 释放Job相关
			@@ -3057,6 +3668,9 @@


			saveState();
			if (m_listener.onControlJobChanged) {
			notifyControlJobChanged();
			}

			return true;
			}
			@@ -3118,6 +3732,15 @@
			if (pSlot == nullptr) return false;

			CGlass* pGlass = (CGlass*)pSlot->getContext();
			if (pGlass == nullptr) return false;

			// Buffer 上限为 1：新搬出时丢弃旧的
			if (!m_bufGlass.empty()) {
			for (auto* oldGlass : m_bufGlass) {
			if (oldGlass != nullptr) oldGlass->release();
			}
			m_bufGlass.clear();
			}
			m_bufGlass.push_back(pGlass);
			pGlass->addRef();
			pSlot->setContext(nullptr);
			@@ -3206,14 +3829,14 @@
			auto& dataTypes = CServoUtilsTool::getEqDataTypes();
			auto& bonderTypes = dataTypes[MID_Bonder1];
			for (size_t i = 0; i < bonderTypes.size(); ++i) {
			m_pCollector->buffersSetChannelName(MID_Bonder1, i + 1, bonderTypes[i].c_str());
			m_pCollector->buffersSetChannelName(MID_Bonder2, i + 1, bonderTypes[i].c_str());
			m_pCollector->buffersSetChannelName(MID_Bonder1, (UINT)i + 1, bonderTypes[(UINT)i].c_str());
			m_pCollector->buffersSetChannelName(MID_Bonder2, (UINT)i + 1, bonderTypes[(UINT)i].c_str());
			}

			auto& vacuumbakeTypes = dataTypes[MID_VacuumBakeA];
			for (size_t i = 0; i < vacuumbakeTypes.size(); ++i) {
			m_pCollector->buffersSetChannelName(MID_VacuumBakeA, i + 1, vacuumbakeTypes[i].c_str());
			m_pCollector->buffersSetChannelName(MID_VacuumBakeB, i + 1, vacuumbakeTypes[i].c_str());
			m_pCollector->buffersSetChannelName(MID_VacuumBakeA, (UINT)i + 1, vacuumbakeTypes[(UINT)i].c_str());
			m_pCollector->buffersSetChannelName(MID_VacuumBakeB, (UINT)i + 1, vacuumbakeTypes[(UINT)i].c_str());
			}

			auto& coolingTypes = dataTypes[MID_BakeCoolingA];
			@@ -3221,6 +3844,17 @@
			m_pCollector->buffersSetChannelName(MID_BakeCoolingA, i + 1, coolingTypes[i].c_str());
			m_pCollector->buffersSetChannelName(MID_BakeCoolingB, i + 1, coolingTypes[i].c_str());
			}

			if (m_curveMode == CurveMode::EmptyChamber) {
			const uint32_t mids[] = {
			MID_Bonder1, MID_Bonder2,
			MID_VacuumBakeA, MID_VacuumBakeB,
			MID_BakeCoolingA, MID_BakeCoolingB
			};
			for (uint32_t mid : mids) {
			m_pCollector->batchStart(mid, "EMPTY_CHAMBER", 10 * 60 * 1000ULL);
			}
			}
			}
			}