/* * Copyright 2011-2012 Con Kolivas * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License as published by the Free * Software Foundation; either version 3 of the License, or (at your option) * any later version. See COPYING for more details. */ #include "config.h" #if defined(HAVE_ADL) && (defined(__unix__) || defined (WIN32)) #include #include #include #ifdef HAVE_CURSES #if defined(__MINGW32__) #include #else #include #endif // defined(__MINGW32__) #endif #include "miner.h" #include "ADL_SDK/adl_sdk.h" #include "compat.h" #if defined (__unix__) # include # include # include #else /* WIN32 */ # include # include #endif #include "adl_functions.h" #ifndef HAVE_CURSES # define wlogprint(...) applog(LOG_WARNING, __VA_ARGS__) #endif bool adl_active; bool opt_reorder = false; int opt_hysteresis = 3; int opt_targettemp = 75; int opt_overheattemp = 85; static pthread_mutex_t adl_lock; struct gpu_adapters { int iAdapterIndex; int iBusNumber; int virtual_gpu; int id; }; // Memory allocation function static void * __stdcall ADL_Main_Memory_Alloc(int iSize) { void *lpBuffer = malloc(iSize); return lpBuffer; } // Optional Memory de-allocation function static void __stdcall ADL_Main_Memory_Free (void **lpBuffer) { if (*lpBuffer != NULL) { free (*lpBuffer); *lpBuffer = NULL; } } #if defined (UNIX) // equivalent functions in linux static void *GetProcAddress(void *pLibrary, const char *name) { return dlsym( pLibrary, name); } #endif static ADL_MAIN_CONTROL_CREATE ADL_Main_Control_Create; static ADL_MAIN_CONTROL_DESTROY ADL_Main_Control_Destroy; static ADL_ADAPTER_NUMBEROFADAPTERS_GET ADL_Adapter_NumberOfAdapters_Get; static ADL_ADAPTER_ADAPTERINFO_GET ADL_Adapter_AdapterInfo_Get; static ADL_ADAPTER_ID_GET ADL_Adapter_ID_Get; static ADL_MAIN_CONTROL_REFRESH ADL_Main_Control_Refresh; static ADL_ADAPTER_VIDEOBIOSINFO_GET ADL_Adapter_VideoBiosInfo_Get; static ADL_DISPLAY_DISPLAYINFO_GET ADL_Display_DisplayInfo_Get; static ADL_ADAPTER_ACCESSIBILITY_GET ADL_Adapter_Accessibility_Get; static ADL_OVERDRIVE_CAPS ADL_Overdrive_Caps; static ADL_OVERDRIVE5_TEMPERATURE_GET ADL_Overdrive5_Temperature_Get; static ADL_OVERDRIVE5_CURRENTACTIVITY_GET ADL_Overdrive5_CurrentActivity_Get; static ADL_OVERDRIVE5_ODPARAMETERS_GET ADL_Overdrive5_ODParameters_Get; static ADL_OVERDRIVE5_FANSPEEDINFO_GET ADL_Overdrive5_FanSpeedInfo_Get; static ADL_OVERDRIVE5_FANSPEED_GET ADL_Overdrive5_FanSpeed_Get; static ADL_OVERDRIVE5_FANSPEED_SET ADL_Overdrive5_FanSpeed_Set; static ADL_OVERDRIVE5_ODPERFORMANCELEVELS_GET ADL_Overdrive5_ODPerformanceLevels_Get; static ADL_OVERDRIVE5_ODPERFORMANCELEVELS_SET ADL_Overdrive5_ODPerformanceLevels_Set; static ADL_OVERDRIVE5_POWERCONTROL_GET ADL_Overdrive5_PowerControl_Get; static ADL_OVERDRIVE5_POWERCONTROL_SET ADL_Overdrive5_PowerControl_Set; static ADL_OVERDRIVE5_FANSPEEDTODEFAULT_SET ADL_Overdrive5_FanSpeedToDefault_Set; static ADL_OVERDRIVE6_CAPABILITIES_GET ADL_Overdrive6_Capabilities_Get; static ADL_OVERDRIVE6_FANSPEED_GET ADL_Overdrive6_FanSpeed_Get; static ADL_OVERDRIVE6_THERMALCONTROLLER_CAPS ADL_Overdrive6_ThermalController_Caps; static ADL_OVERDRIVE6_TEMPERATURE_GET ADL_Overdrive6_Temperature_Get; static ADL_OVERDRIVE6_STATEINFO_GET ADL_Overdrive6_StateInfo_Get; static ADL_OVERDRIVE6_CURRENTSTATUS_GET ADL_Overdrive6_CurrentStatus_Get; static ADL_OVERDRIVE6_POWERCONTROL_CAPS ADL_Overdrive6_PowerControl_Caps; static ADL_OVERDRIVE6_POWERCONTROLINFO_GET ADL_Overdrive6_PowerControlInfo_Get; static ADL_OVERDRIVE6_POWERCONTROL_GET ADL_Overdrive6_PowerControl_Get; static ADL_OVERDRIVE6_FANSPEED_SET ADL_Overdrive6_FanSpeed_Set; static ADL_OVERDRIVE6_STATE_SET ADL_Overdrive6_State_Set; static ADL_OVERDRIVE6_POWERCONTROL_SET ADL_Overdrive6_PowerControl_Set; #if defined (UNIX) static void *hDLL; // Handle to .so library #else HINSTANCE hDLL; // Handle to DLL #endif static int iNumberAdapters; static LPAdapterInfo lpInfo = NULL; int set_fanspeed(int gpu, int iFanSpeed); static float __gpu_temp(struct gpu_adl *ga); char *adl_error_desc(int error) { char *result; switch(error) { case ADL_ERR: result = "Generic error (escape call failed?)"; break; case ADL_ERR_NOT_INIT: result = "ADL not initialized"; break; case ADL_ERR_INVALID_PARAM: result = "Invalid parameter"; break; case ADL_ERR_INVALID_PARAM_SIZE: result = "Invalid parameter size"; break; case ADL_ERR_INVALID_ADL_IDX: result = "Invalid ADL index"; break; case ADL_ERR_INVALID_CONTROLLER_IDX: result = "Invalid controller index"; break; case ADL_ERR_INVALID_DIPLAY_IDX: result = "Invalid display index"; break; case ADL_ERR_NOT_SUPPORTED: result = "Function not supported by the driver"; break; case ADL_ERR_NULL_POINTER: result = "Null Pointer error"; break; case ADL_ERR_DISABLED_ADAPTER: result = "Disabled adapter, can't make call"; break; case ADL_ERR_INVALID_CALLBACK: result = "Invalid callback"; break; case ADL_ERR_RESOURCE_CONFLICT: result = "Display resource conflict"; break; case ADL_ERR_SET_INCOMPLETE: result = "Failed to update some of the values"; break; case ADL_ERR_NO_XDISPLAY: result = "No Linux XDisplay in Linux Console environment"; break; default: result = "Unhandled error"; break; } return result; } static inline void lock_adl(void) { mutex_lock(&adl_lock); } static inline void unlock_adl(void) { mutex_unlock(&adl_lock); } /* This looks for the twin GPU that has the fanspeed control of a non fanspeed * control GPU on dual GPU cards */ static bool fanspeed_twin(struct gpu_adl *ga, struct gpu_adl *other_ga) { if (!other_ga->has_fanspeed) return false; if (abs(ga->iBusNumber - other_ga->iBusNumber) != 1) return false; if (strcmp(ga->strAdapterName, other_ga->strAdapterName)) return false; return true; } static bool init_overdrive5() { ADL_Overdrive5_Temperature_Get = (ADL_OVERDRIVE5_TEMPERATURE_GET) GetProcAddress(hDLL,"ADL_Overdrive5_Temperature_Get"); ADL_Overdrive5_CurrentActivity_Get = (ADL_OVERDRIVE5_CURRENTACTIVITY_GET) GetProcAddress(hDLL, "ADL_Overdrive5_CurrentActivity_Get"); ADL_Overdrive5_ODParameters_Get = (ADL_OVERDRIVE5_ODPARAMETERS_GET) GetProcAddress(hDLL, "ADL_Overdrive5_ODParameters_Get"); ADL_Overdrive5_FanSpeedInfo_Get = (ADL_OVERDRIVE5_FANSPEEDINFO_GET) GetProcAddress(hDLL, "ADL_Overdrive5_FanSpeedInfo_Get"); ADL_Overdrive5_FanSpeed_Get = (ADL_OVERDRIVE5_FANSPEED_GET) GetProcAddress(hDLL, "ADL_Overdrive5_FanSpeed_Get"); ADL_Overdrive5_FanSpeed_Set = (ADL_OVERDRIVE5_FANSPEED_SET) GetProcAddress(hDLL, "ADL_Overdrive5_FanSpeed_Set"); ADL_Overdrive5_ODPerformanceLevels_Get = (ADL_OVERDRIVE5_ODPERFORMANCELEVELS_GET) GetProcAddress(hDLL, "ADL_Overdrive5_ODPerformanceLevels_Get"); ADL_Overdrive5_ODPerformanceLevels_Set = (ADL_OVERDRIVE5_ODPERFORMANCELEVELS_SET) GetProcAddress(hDLL, "ADL_Overdrive5_ODPerformanceLevels_Set"); ADL_Overdrive5_PowerControl_Get = (ADL_OVERDRIVE5_POWERCONTROL_GET) GetProcAddress(hDLL, "ADL_Overdrive5_PowerControl_Get"); ADL_Overdrive5_PowerControl_Set = (ADL_OVERDRIVE5_POWERCONTROL_SET) GetProcAddress(hDLL, "ADL_Overdrive5_PowerControl_Set"); ADL_Overdrive5_FanSpeedToDefault_Set = (ADL_OVERDRIVE5_FANSPEEDTODEFAULT_SET) GetProcAddress(hDLL, "ADL_Overdrive5_FanSpeedToDefault_Set"); if (!ADL_Overdrive5_Temperature_Get || !ADL_Overdrive5_CurrentActivity_Get || !ADL_Overdrive5_ODParameters_Get || !ADL_Overdrive5_FanSpeedInfo_Get || !ADL_Overdrive5_FanSpeed_Get || !ADL_Overdrive5_FanSpeed_Set || !ADL_Overdrive5_ODPerformanceLevels_Get || !ADL_Overdrive5_ODPerformanceLevels_Set || !ADL_Overdrive5_PowerControl_Get || !ADL_Overdrive5_PowerControl_Set || !ADL_Overdrive5_FanSpeedToDefault_Set) { applog(LOG_WARNING, "ATI ADL Overdrive5's API is missing or broken."); return false; } else { applog(LOG_INFO, "ATI ADL Overdrive5 API found."); } return true; } static bool init_overdrive6() { ADL_Overdrive6_FanSpeed_Get = (ADL_OVERDRIVE6_FANSPEED_GET) GetProcAddress(hDLL,"ADL_Overdrive6_FanSpeed_Get"); ADL_Overdrive6_ThermalController_Caps = (ADL_OVERDRIVE6_THERMALCONTROLLER_CAPS)GetProcAddress (hDLL, "ADL_Overdrive6_ThermalController_Caps"); ADL_Overdrive6_Temperature_Get = (ADL_OVERDRIVE6_TEMPERATURE_GET)GetProcAddress (hDLL, "ADL_Overdrive6_Temperature_Get"); ADL_Overdrive6_Capabilities_Get = (ADL_OVERDRIVE6_CAPABILITIES_GET)GetProcAddress(hDLL, "ADL_Overdrive6_Capabilities_Get"); ADL_Overdrive6_StateInfo_Get = (ADL_OVERDRIVE6_STATEINFO_GET)GetProcAddress(hDLL, "ADL_Overdrive6_StateInfo_Get"); ADL_Overdrive6_CurrentStatus_Get = (ADL_OVERDRIVE6_CURRENTSTATUS_GET)GetProcAddress(hDLL, "ADL_Overdrive6_CurrentStatus_Get"); ADL_Overdrive6_PowerControl_Caps = (ADL_OVERDRIVE6_POWERCONTROL_CAPS)GetProcAddress(hDLL, "ADL_Overdrive6_PowerControl_Caps"); ADL_Overdrive6_PowerControlInfo_Get = (ADL_OVERDRIVE6_POWERCONTROLINFO_GET)GetProcAddress(hDLL, "ADL_Overdrive6_PowerControlInfo_Get"); ADL_Overdrive6_PowerControl_Get = (ADL_OVERDRIVE6_POWERCONTROL_GET)GetProcAddress(hDLL, "ADL_Overdrive6_PowerControl_Get"); ADL_Overdrive6_FanSpeed_Set = (ADL_OVERDRIVE6_FANSPEED_SET)GetProcAddress(hDLL, "ADL_Overdrive6_FanSpeed_Set"); ADL_Overdrive6_State_Set = (ADL_OVERDRIVE6_STATE_SET)GetProcAddress(hDLL, "ADL_Overdrive6_State_Set"); ADL_Overdrive6_PowerControl_Set = (ADL_OVERDRIVE6_POWERCONTROL_SET) GetProcAddress(hDLL, "ADL_Overdrive6_PowerControl_Set"); if (!ADL_Overdrive6_FanSpeed_Get || !ADL_Overdrive6_ThermalController_Caps || !ADL_Overdrive6_Temperature_Get || !ADL_Overdrive6_Capabilities_Get || !ADL_Overdrive6_StateInfo_Get || !ADL_Overdrive6_CurrentStatus_Get || !ADL_Overdrive6_PowerControl_Caps || !ADL_Overdrive6_PowerControlInfo_Get || !ADL_Overdrive6_PowerControl_Get || !ADL_Overdrive6_FanSpeed_Set || !ADL_Overdrive6_State_Set || !ADL_Overdrive6_PowerControl_Set) { applog(LOG_WARNING, "ATI ADL Overdrive6's API is missing or broken."); return false; } else { applog(LOG_INFO, "ATI ADL Overdrive6 API found."); } return true; } static bool prepare_adl(void) { int result; #if defined (UNIX) hDLL = dlopen( "libatiadlxx.so", RTLD_LAZY|RTLD_GLOBAL); #else hDLL = LoadLibrary("atiadlxx.dll"); if (hDLL == NULL) // A 32 bit calling application on 64 bit OS will fail to LoadLIbrary. // Try to load the 32 bit library (atiadlxy.dll) instead hDLL = LoadLibrary("atiadlxy.dll"); #endif if (hDLL == NULL) { applog(LOG_INFO, "Unable to load ATI ADL library."); return false; } ADL_Main_Control_Create = (ADL_MAIN_CONTROL_CREATE) GetProcAddress(hDLL,"ADL_Main_Control_Create"); ADL_Main_Control_Destroy = (ADL_MAIN_CONTROL_DESTROY) GetProcAddress(hDLL,"ADL_Main_Control_Destroy"); ADL_Adapter_NumberOfAdapters_Get = (ADL_ADAPTER_NUMBEROFADAPTERS_GET) GetProcAddress(hDLL,"ADL_Adapter_NumberOfAdapters_Get"); ADL_Adapter_AdapterInfo_Get = (ADL_ADAPTER_ADAPTERINFO_GET) GetProcAddress(hDLL,"ADL_Adapter_AdapterInfo_Get"); ADL_Display_DisplayInfo_Get = (ADL_DISPLAY_DISPLAYINFO_GET) GetProcAddress(hDLL,"ADL_Display_DisplayInfo_Get"); ADL_Adapter_ID_Get = (ADL_ADAPTER_ID_GET) GetProcAddress(hDLL,"ADL_Adapter_ID_Get"); ADL_Main_Control_Refresh = (ADL_MAIN_CONTROL_REFRESH) GetProcAddress(hDLL, "ADL_Main_Control_Refresh"); ADL_Adapter_VideoBiosInfo_Get = (ADL_ADAPTER_VIDEOBIOSINFO_GET)GetProcAddress(hDLL,"ADL_Adapter_VideoBiosInfo_Get"); ADL_Overdrive_Caps = (ADL_OVERDRIVE_CAPS)GetProcAddress(hDLL, "ADL_Overdrive_Caps"); ADL_Adapter_Accessibility_Get = (ADL_ADAPTER_ACCESSIBILITY_GET)GetProcAddress(hDLL, "ADL_Adapter_Accessibility_Get"); if (!ADL_Main_Control_Create || !ADL_Main_Control_Destroy || !ADL_Adapter_NumberOfAdapters_Get || !ADL_Adapter_AdapterInfo_Get || !ADL_Display_DisplayInfo_Get || !ADL_Adapter_ID_Get || !ADL_Main_Control_Refresh || !ADL_Adapter_VideoBiosInfo_Get || !ADL_Overdrive_Caps) { applog(LOG_WARNING, "ATI ADL API is missing or broken."); return false; } // Initialise ADL. The second parameter is 1, which means: // retrieve adapter information only for adapters that are physically present and enabled in the system result = ADL_Main_Control_Create(ADL_Main_Memory_Alloc, 1); if (result != ADL_OK) { applog(LOG_INFO, "ADL initialisation error: %d (%s)", result, adl_error_desc(result)); return false; } result = ADL_Main_Control_Refresh(); if (result != ADL_OK) { applog(LOG_INFO, "ADL refresh error: %d (%s)", result, adl_error_desc(result)); return false; } init_overdrive5(); init_overdrive6(); // FIXME: don't if ADL6 is not present return true; } void init_adl(int nDevs) { int result, i, j, devices = 0, last_adapter = -1, gpu = 0, dummy = 0; struct gpu_adapters adapters[MAX_GPUDEVICES], vadapters[MAX_GPUDEVICES]; bool devs_match = true; ADLBiosInfo BiosInfo; applog(LOG_INFO, "Number of ADL devices: %d", nDevs); if (unlikely(pthread_mutex_init(&adl_lock, NULL))) { applog(LOG_ERR, "Failed to init adl_lock in init_adl"); return; } if (!prepare_adl()) return; // Obtain the number of adapters for the system result = ADL_Adapter_NumberOfAdapters_Get (&iNumberAdapters); if (result != ADL_OK) { applog(LOG_INFO, "Cannot get the number of adapters! Error %d!", result); return ; } if (iNumberAdapters > 0) { lpInfo = (LPAdapterInfo)malloc ( sizeof (AdapterInfo) * iNumberAdapters ); memset ( lpInfo,'\0', sizeof (AdapterInfo) * iNumberAdapters ); lpInfo->iSize = sizeof(lpInfo); // Get the AdapterInfo structure for all adapters in the system result = ADL_Adapter_AdapterInfo_Get (lpInfo, sizeof (AdapterInfo) * iNumberAdapters); if (result != ADL_OK) { applog(LOG_INFO, "ADL_Adapter_AdapterInfo_Get Error! Error %d", result); return ; } } else { applog(LOG_INFO, "No adapters found"); return; } applog(LOG_INFO, "Found %d logical ADL adapters", iNumberAdapters); /* Iterate over iNumberAdapters and find the lpAdapterID of real devices */ for (i = 0; i < iNumberAdapters; i++) { int iAdapterIndex; int lpAdapterID; iAdapterIndex = lpInfo[i].iAdapterIndex; /* Get unique identifier of the adapter, 0 means not AMD */ result = ADL_Adapter_ID_Get(iAdapterIndex, &lpAdapterID); if (ADL_Adapter_VideoBiosInfo_Get(iAdapterIndex, &BiosInfo) == ADL_ERR) { applog(LOG_INFO, "ADL index %d, id %d - FAILED to get BIOS info", iAdapterIndex, lpAdapterID); } else { applog(LOG_INFO, "ADL index %d, id %d - BIOS partno.: %s, version: %s, date: %s", iAdapterIndex, lpAdapterID, BiosInfo.strPartNumber, BiosInfo.strVersion, BiosInfo.strDate); } if (result != ADL_OK) { applog(LOG_INFO, "Failed to ADL_Adapter_ID_Get. Error %d", result); if (result == -10) applog(LOG_INFO, "(Device is not enabled.)"); continue; } /* Each adapter may have multiple entries */ if (lpAdapterID == last_adapter) { continue; } applog(LOG_INFO, "GPU %d assigned: " "iAdapterIndex:%d " "iPresent:%d " "strUDID:%s " "iBusNumber:%d " "iDeviceNumber:%d " #if defined(__linux__) "iDrvIndex:%d " #endif "iFunctionNumber:%d " "iVendorID:%d " "name:%s", devices, lpInfo[i].iAdapterIndex, lpInfo[i].iPresent, lpInfo[i].strUDID, lpInfo[i].iBusNumber, lpInfo[i].iDeviceNumber, #if defined(__linux__) lpInfo[i].iDrvIndex, #endif lpInfo[i].iFunctionNumber, lpInfo[i].iVendorID, lpInfo[i].strAdapterName); adapters[devices].iAdapterIndex = iAdapterIndex; adapters[devices].iBusNumber = lpInfo[i].iBusNumber; adapters[devices].id = i; /* We found a truly new adapter instead of a logical * one. Now since there's no way of correlating the * opencl enumerated devices and the ADL enumerated * ones, we have to assume they're in the same order.*/ if (++devices > nDevs && devs_match) { applog(LOG_ERR, "ADL found more devices than opencl!"); applog(LOG_ERR, "There is possibly at least one GPU that doesn't support OpenCL"); applog(LOG_ERR, "Use the gpu map feature to reliably map OpenCL to ADL"); devs_match = false; } last_adapter = lpAdapterID; if (!lpAdapterID) { applog(LOG_INFO, "Adapter returns ID 0 meaning not AMD. Card order might be confused"); continue; } } if (devices < nDevs) { applog(LOG_ERR, "ADL found less devices than opencl!"); applog(LOG_ERR, "There is possibly more than one display attached to a GPU"); applog(LOG_ERR, "Use the gpu map feature to reliably map OpenCL to ADL"); devs_match = false; } for (i = 0; i < devices; i++) { vadapters[i].virtual_gpu = i; vadapters[i].id = adapters[i].id; } /* Apply manually provided OpenCL to ADL mapping, if any */ for (i = 0; i < nDevs; i++) { if (gpus[i].mapped) { vadapters[gpus[i].virtual_adl].virtual_gpu = i; applog(LOG_INFO, "Mapping OpenCL device %d to ADL device %d", i, gpus[i].virtual_adl); } else { gpus[i].virtual_adl = i; } } if (!devs_match) { applog(LOG_ERR, "WARNING: Number of OpenCL and ADL devices did not match!"); applog(LOG_ERR, "Hardware monitoring may NOT match up with devices!"); } else if (opt_reorder) { /* Windows has some kind of random ordering for bus number IDs and * ordering the GPUs according to ascending order fixes it. Linux * has usually sequential but decreasing order instead! */ for (i = 0; i < devices; i++) { int j, virtual_gpu; virtual_gpu = 0; for (j = 0; j < devices; j++) { if (i == j) continue; #ifdef WIN32 if (adapters[j].iBusNumber < adapters[i].iBusNumber) #else if (adapters[j].iBusNumber > adapters[i].iBusNumber) #endif virtual_gpu++; } if (virtual_gpu != i) { applog(LOG_INFO, "Mapping device %d to GPU %d according to Bus Number order", i, virtual_gpu); vadapters[virtual_gpu].virtual_gpu = i; vadapters[virtual_gpu].id = adapters[i].id; } } } if (devices > nDevs) devices = nDevs; for (gpu = 0; gpu < devices; gpu++) { struct gpu_adl *ga; int iAdapterIndex; int lpAdapterID; ADLODPerformanceLevels *lpOdPerformanceLevels; int lev, adlGpu; size_t plsize; ADLBiosInfo BiosInfo; adlGpu = gpus[gpu].virtual_adl; i = vadapters[adlGpu].id; iAdapterIndex = lpInfo[i].iAdapterIndex; gpus[gpu].virtual_gpu = vadapters[adlGpu].virtual_gpu; /* Get unique identifier of the adapter, 0 means not AMD */ result = ADL_Adapter_ID_Get(iAdapterIndex, &lpAdapterID); if (result != ADL_OK) { applog(LOG_INFO, "Failed to ADL_Adapter_ID_Get. Error %d", result); continue; } if (gpus[gpu].deven == DEV_DISABLED) { gpus[gpu].gpu_engine = gpus[gpu].gpu_memclock = gpus[gpu].gpu_vddc = gpus[gpu].gpu_fan = gpus[gpu].gpu_powertune = 0; continue; } applog(LOG_INFO, "GPU %d %s hardware monitoring enabled", gpu, lpInfo[i].strAdapterName); if (gpus[gpu].name) free(gpus[gpu].name); gpus[gpu].name = lpInfo[i].strAdapterName; gpus[gpu].has_adl = true; /* Flag adl as active if any card is successfully activated */ adl_active = true; /* From here on we know this device is a discrete device and * should support ADL */ ga = &gpus[gpu].adl; ga->gpu = gpu; ga->iAdapterIndex = iAdapterIndex; ga->lpAdapterID = lpAdapterID; strcpy(ga->strAdapterName, lpInfo[i].strAdapterName); ga->DefPerfLev = NULL; ga->twin = NULL; ga->def_fan_valid = false; applog(LOG_INFO, "ADL GPU %d is Adapter index %d and maps to adapter id %d", ga->gpu, ga->iAdapterIndex, ga->lpAdapterID); if (ADL_Adapter_VideoBiosInfo_Get(iAdapterIndex, &BiosInfo) != ADL_ERR) applog(LOG_INFO, "GPU %d BIOS partno.: %s, version: %s, date: %s", gpu, BiosInfo.strPartNumber, BiosInfo.strVersion, BiosInfo.strDate); ga->lpOdParameters.iSize = sizeof(ADLODParameters); if (ADL_Overdrive5_ODParameters_Get(iAdapterIndex, &ga->lpOdParameters) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_ODParameters_Get"); lev = ga->lpOdParameters.iNumberOfPerformanceLevels - 1; /* We're only interested in the top performance level */ plsize = sizeof(ADLODPerformanceLevels) + lev * sizeof(ADLODPerformanceLevel); lpOdPerformanceLevels = (ADLODPerformanceLevels *)malloc(plsize); lpOdPerformanceLevels->iSize = plsize; /* Get default performance levels first */ if (ADL_Overdrive5_ODPerformanceLevels_Get(iAdapterIndex, 1, lpOdPerformanceLevels) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_ODPerformanceLevels_Get"); /* Set the limits we'd use based on default gpu speeds */ ga->maxspeed = ga->minspeed = lpOdPerformanceLevels->aLevels[lev].iEngineClock; ga->lpTemperature.iSize = sizeof(ADLTemperature); ga->lpFanSpeedInfo.iSize = sizeof(ADLFanSpeedInfo); ga->lpFanSpeedValue.iSize = ga->DefFanSpeedValue.iSize = sizeof(ADLFanSpeedValue); ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_RPM; ga->DefFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_RPM; /* Now get the current performance levels for any existing overclock */ if (ADL_Overdrive5_ODPerformanceLevels_Get(iAdapterIndex, 0, lpOdPerformanceLevels) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_ODPerformanceLevels_Get"); else { /* Save these values as the defaults in case we wish to reset to defaults */ ga->DefPerfLev = (ADLODPerformanceLevels *)malloc(plsize); memcpy(ga->DefPerfLev, lpOdPerformanceLevels, plsize); } if (gpus[gpu].gpu_engine) { int setengine = gpus[gpu].gpu_engine * 100; /* Lower profiles can't have a higher setting */ for (j = 0; j < lev; j++) { if (lpOdPerformanceLevels->aLevels[j].iEngineClock > setengine) lpOdPerformanceLevels->aLevels[j].iEngineClock = setengine; } lpOdPerformanceLevels->aLevels[lev].iEngineClock = setengine; applog(LOG_INFO, "Setting GPU %d engine clock to %d", gpu, gpus[gpu].gpu_engine); ADL_Overdrive5_ODPerformanceLevels_Set(iAdapterIndex, lpOdPerformanceLevels); ga->maxspeed = setengine; if (gpus[gpu].min_engine) ga->minspeed = gpus[gpu].min_engine * 100; ga->managed = true; if (gpus[gpu].gpu_memdiff) set_memoryclock(gpu, gpus[gpu].gpu_engine + gpus[gpu].gpu_memdiff); } if (gpus[gpu].gpu_memclock) { int setmem = gpus[gpu].gpu_memclock * 100; for (j = 0; j < lev; j++) { if (lpOdPerformanceLevels->aLevels[j].iMemoryClock > setmem) lpOdPerformanceLevels->aLevels[j].iMemoryClock = setmem; } lpOdPerformanceLevels->aLevels[lev].iMemoryClock = setmem; applog(LOG_INFO, "Setting GPU %d memory clock to %d", gpu, gpus[gpu].gpu_memclock); ADL_Overdrive5_ODPerformanceLevels_Set(iAdapterIndex, lpOdPerformanceLevels); ga->managed = true; } if (gpus[gpu].gpu_vddc) { int setv = gpus[gpu].gpu_vddc * 1000; for (j = 0; j < lev; j++) { if (lpOdPerformanceLevels->aLevels[j].iVddc > setv) lpOdPerformanceLevels->aLevels[j].iVddc = setv; } lpOdPerformanceLevels->aLevels[lev].iVddc = setv; applog(LOG_INFO, "Setting GPU %d voltage to %.3f", gpu, gpus[gpu].gpu_vddc); ADL_Overdrive5_ODPerformanceLevels_Set(iAdapterIndex, lpOdPerformanceLevels); ga->managed = true; } ADL_Overdrive5_ODPerformanceLevels_Get(iAdapterIndex, 0, lpOdPerformanceLevels); ga->iEngineClock = lpOdPerformanceLevels->aLevels[lev].iEngineClock; ga->iMemoryClock = lpOdPerformanceLevels->aLevels[lev].iMemoryClock; ga->iVddc = lpOdPerformanceLevels->aLevels[lev].iVddc; ga->iBusNumber = lpInfo[i].iBusNumber; if (ADL_Overdrive5_FanSpeedInfo_Get(iAdapterIndex, 0, &ga->lpFanSpeedInfo) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_FanSpeedInfo_Get"); if(!(ga->lpFanSpeedInfo.iFlags & (ADL_DL_FANCTRL_SUPPORTS_RPM_WRITE | ADL_DL_FANCTRL_SUPPORTS_PERCENT_WRITE))) ga->has_fanspeed = false; else ga->has_fanspeed = true; /* Save the fanspeed values as defaults in case we reset later */ if (ADL_Overdrive5_FanSpeed_Get(iAdapterIndex, 0, &ga->DefFanSpeedValue) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_FanSpeed_Get for default value"); else ga->def_fan_valid = true; if (gpus[gpu].gpu_fan) set_fanspeed(gpu, gpus[gpu].gpu_fan); else gpus[gpu].gpu_fan = 85; /* Set a nominal upper limit of 85% */ /* Not fatal if powercontrol get fails */ if (ADL_Overdrive5_PowerControl_Get(iAdapterIndex, &ga->iPercentage, &dummy) != ADL_OK) applog(LOG_INFO, "Failed to ADL_Overdrive5_PowerControl_get"); if (gpus[gpu].gpu_powertune) { ADL_Overdrive5_PowerControl_Set(iAdapterIndex, gpus[gpu].gpu_powertune); ADL_Overdrive5_PowerControl_Get(iAdapterIndex, &ga->iPercentage, &dummy); ga->managed = true; } /* Set some default temperatures for autotune when enabled */ if (!ga->targettemp) ga->targettemp = opt_targettemp; if (!ga->overtemp) ga->overtemp = opt_overheattemp; if (!gpus[gpu].cutofftemp) gpus[gpu].cutofftemp = opt_cutofftemp; if (opt_autofan) { /* Set a safe starting default if we're automanaging fan speeds */ int nominal = 50; ga->autofan = true; /* Clamp fanspeed values to range provided */ if (nominal > gpus[gpu].gpu_fan) nominal = gpus[gpu].gpu_fan; if (nominal < gpus[gpu].min_fan) nominal = gpus[gpu].min_fan; set_fanspeed(gpu, nominal); } if (opt_autoengine) { ga->autoengine = true; ga->managed = true; } ga->lasttemp = __gpu_temp(ga); } for (gpu = 0; gpu < devices; gpu++) { struct gpu_adl *ga = &gpus[gpu].adl; int j; for (j = 0; j < devices; j++) { struct gpu_adl *other_ga; if (j == gpu) continue; other_ga = &gpus[j].adl; /* Search for twin GPUs on a single card. They will be * separated by one bus id and one will have fanspeed * while the other won't. */ if (!ga->has_fanspeed) { if (fanspeed_twin(ga, other_ga)) { applog(LOG_INFO, "Dual GPUs detected: %d and %d", ga->gpu, other_ga->gpu); ga->twin = other_ga; other_ga->twin = ga; } } } } } static float __gpu_temp(struct gpu_adl *ga) { if (ADL_Overdrive5_Temperature_Get(ga->iAdapterIndex, 0, &ga->lpTemperature) != ADL_OK) return -1; return (float)ga->lpTemperature.iTemperature / 1000; } float gpu_temp(int gpu) { struct gpu_adl *ga; float ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); ret = __gpu_temp(ga); unlock_adl(); gpus[gpu].temp = ret; return ret; } static inline int __gpu_engineclock(struct gpu_adl *ga) { return ga->lpActivity.iEngineClock / 100; } int gpu_engineclock(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); if (ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity) != ADL_OK) goto out; ret = __gpu_engineclock(ga); out: unlock_adl(); return ret; } static inline int __gpu_memclock(struct gpu_adl *ga) { return ga->lpActivity.iMemoryClock / 100; } int gpu_memclock(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); if (ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity) != ADL_OK) goto out; ret = __gpu_memclock(ga); out: unlock_adl(); return ret; } static inline float __gpu_vddc(struct gpu_adl *ga) { return (float)ga->lpActivity.iVddc / 1000; } float gpu_vddc(int gpu) { struct gpu_adl *ga; float ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); if (ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity) != ADL_OK) goto out; ret = __gpu_vddc(ga); out: unlock_adl(); return ret; } static inline int __gpu_activity(struct gpu_adl *ga) { if (!ga->lpOdParameters.iActivityReportingSupported) return -1; return ga->lpActivity.iActivityPercent; } int gpu_activity(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); ret = ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity); unlock_adl(); if (ret != ADL_OK) return ret; if (!ga->lpOdParameters.iActivityReportingSupported) return ret; return ga->lpActivity.iActivityPercent; } static inline int __gpu_fanspeed(struct gpu_adl *ga) { if (!ga->has_fanspeed && ga->twin) return __gpu_fanspeed(ga->twin); if (!(ga->lpFanSpeedInfo.iFlags & ADL_DL_FANCTRL_SUPPORTS_RPM_READ)) return -1; ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_RPM; if (ADL_Overdrive5_FanSpeed_Get(ga->iAdapterIndex, 0, &ga->lpFanSpeedValue) != ADL_OK) return -1; return ga->lpFanSpeedValue.iFanSpeed; } int gpu_fanspeed(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); ret = __gpu_fanspeed(ga); unlock_adl(); return ret; } static int __gpu_fanpercent(struct gpu_adl *ga) { if (!ga->has_fanspeed && ga->twin) return __gpu_fanpercent(ga->twin); if (!(ga->lpFanSpeedInfo.iFlags & ADL_DL_FANCTRL_SUPPORTS_PERCENT_READ )) return -1; ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_PERCENT; if (ADL_Overdrive5_FanSpeed_Get(ga->iAdapterIndex, 0, &ga->lpFanSpeedValue) != ADL_OK) return -1; return ga->lpFanSpeedValue.iFanSpeed; } int gpu_fanpercent(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); ret = __gpu_fanpercent(ga); unlock_adl(); if (unlikely(ga->has_fanspeed && ret == -1)) { #if 0 /* Recursive calling applog causes a hang, so disable messages */ applog(LOG_WARNING, "GPU %d stopped reporting fanspeed due to driver corruption", gpu); if (opt_restart) { applog(LOG_WARNING, "Restart enabled, will attempt to restart sgminer"); applog(LOG_WARNING, "You can disable this with the --no-restart option"); app_restart(); } applog(LOG_WARNING, "Disabling fanspeed monitoring on this device"); ga->has_fanspeed = false; if (ga->twin) { applog(LOG_WARNING, "Disabling fanspeed linking on GPU twins"); ga->twin->twin = NULL;; ga->twin = NULL; } #endif if (opt_restart) app_restart(); ga->has_fanspeed = false; if (ga->twin) { ga->twin->twin = NULL;; ga->twin = NULL; } } return ret; } static inline int __gpu_powertune(struct gpu_adl *ga) { int dummy = 0; if (ADL_Overdrive5_PowerControl_Get(ga->iAdapterIndex, &ga->iPercentage, &dummy) != ADL_OK) return -1; return ga->iPercentage; } int gpu_powertune(int gpu) { struct gpu_adl *ga; int ret = -1; if (!gpus[gpu].has_adl || !adl_active) return ret; ga = &gpus[gpu].adl; lock_adl(); ret = __gpu_powertune(ga); unlock_adl(); return ret; } bool gpu_stats(int gpu, float *temp, int *engineclock, int *memclock, float *vddc, int *activity, int *fanspeed, int *fanpercent, int *powertune) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) return false; ga = &gpus[gpu].adl; lock_adl(); *temp = __gpu_temp(ga); if (ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity) != ADL_OK) { *engineclock = 0; *memclock = 0; *vddc = 0; *activity = 0; } else { *engineclock = __gpu_engineclock(ga); *memclock = __gpu_memclock(ga); *vddc = __gpu_vddc(ga); *activity = __gpu_activity(ga); } *fanspeed = __gpu_fanspeed(ga); *fanpercent = __gpu_fanpercent(ga); *powertune = __gpu_powertune(ga); unlock_adl(); return true; } #ifdef HAVE_CURSES static void get_enginerange(int gpu, int *imin, int *imax) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Get enginerange not supported\n"); return; } ga = &gpus[gpu].adl; *imin = ga->lpOdParameters.sEngineClock.iMin / 100; *imax = ga->lpOdParameters.sEngineClock.iMax / 100; } #endif int set_engineclock(int gpu, int iEngineClock) { ADLODPerformanceLevels *lpOdPerformanceLevels; struct cgpu_info *cgpu; int i, lev, ret = 1; struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Set engineclock not supported\n"); return ret; } iEngineClock *= 100; ga = &gpus[gpu].adl; /* Keep track of intended engine clock in case the device changes * profile and drops while idle, not taking the new engine clock */ ga->lastengine = iEngineClock; lev = ga->lpOdParameters.iNumberOfPerformanceLevels - 1; lpOdPerformanceLevels = (ADLODPerformanceLevels *)alloca(sizeof(ADLODPerformanceLevels)+(lev * sizeof(ADLODPerformanceLevel))); lpOdPerformanceLevels->iSize = sizeof(ADLODPerformanceLevels) + sizeof(ADLODPerformanceLevel) * lev; lock_adl(); if (ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels) != ADL_OK) goto out; for (i = 0; i < lev; i++) { if (lpOdPerformanceLevels->aLevels[i].iEngineClock > iEngineClock) lpOdPerformanceLevels->aLevels[i].iEngineClock = iEngineClock; } lpOdPerformanceLevels->aLevels[lev].iEngineClock = iEngineClock; ADL_Overdrive5_ODPerformanceLevels_Set(ga->iAdapterIndex, lpOdPerformanceLevels); ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels); if (lpOdPerformanceLevels->aLevels[lev].iEngineClock == iEngineClock) ret = 0; ga->iEngineClock = lpOdPerformanceLevels->aLevels[lev].iEngineClock; if (ga->iEngineClock > ga->maxspeed) ga->maxspeed = ga->iEngineClock; if (ga->iEngineClock < ga->minspeed) ga->minspeed = ga->iEngineClock; ga->iMemoryClock = lpOdPerformanceLevels->aLevels[lev].iMemoryClock; ga->iVddc = lpOdPerformanceLevels->aLevels[lev].iVddc; ga->managed = true; out: unlock_adl(); cgpu = &gpus[gpu]; if (cgpu->gpu_memdiff) set_memoryclock(gpu, iEngineClock / 100 + cgpu->gpu_memdiff); return ret; } #ifdef HAVE_CURSES static void get_memoryrange(int gpu, int *imin, int *imax) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Get memoryrange not supported\n"); return; } ga = &gpus[gpu].adl; *imin = ga->lpOdParameters.sMemoryClock.iMin / 100; *imax = ga->lpOdParameters.sMemoryClock.iMax / 100; } #endif int set_memoryclock(int gpu, int iMemoryClock) { ADLODPerformanceLevels *lpOdPerformanceLevels; int i, lev, ret = 1; struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Set memoryclock not supported\n"); return ret; } iMemoryClock *= 100; ga = &gpus[gpu].adl; lev = ga->lpOdParameters.iNumberOfPerformanceLevels - 1; lpOdPerformanceLevels = (ADLODPerformanceLevels *)alloca(sizeof(ADLODPerformanceLevels)+(lev * sizeof(ADLODPerformanceLevel))); lpOdPerformanceLevels->iSize = sizeof(ADLODPerformanceLevels) + sizeof(ADLODPerformanceLevel) * lev; lock_adl(); if (ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels) != ADL_OK) goto out; lpOdPerformanceLevels->aLevels[lev].iMemoryClock = iMemoryClock; for (i = 0; i < lev; i++) { if (lpOdPerformanceLevels->aLevels[i].iMemoryClock > iMemoryClock) lpOdPerformanceLevels->aLevels[i].iMemoryClock = iMemoryClock; } ADL_Overdrive5_ODPerformanceLevels_Set(ga->iAdapterIndex, lpOdPerformanceLevels); ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels); if (lpOdPerformanceLevels->aLevels[lev].iMemoryClock == iMemoryClock) ret = 0; ga->iEngineClock = lpOdPerformanceLevels->aLevels[lev].iEngineClock; ga->iMemoryClock = lpOdPerformanceLevels->aLevels[lev].iMemoryClock; ga->iVddc = lpOdPerformanceLevels->aLevels[lev].iVddc; ga->managed = true; out: unlock_adl(); return ret; } #ifdef HAVE_CURSES static void get_vddcrange(int gpu, float *imin, float *imax) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Get vddcrange not supported\n"); return; } ga = &gpus[gpu].adl; *imin = (float)ga->lpOdParameters.sVddc.iMin / 1000; *imax = (float)ga->lpOdParameters.sVddc.iMax / 1000; } static float curses_float(const char *query) { float ret; char *cvar; cvar = curses_input(query); ret = atof(cvar); free(cvar); return ret; } #endif int set_vddc(int gpu, float fVddc) { ADLODPerformanceLevels *lpOdPerformanceLevels; int i, iVddc, lev, ret = 1; struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Set vddc not supported\n"); return ret; } iVddc = 1000 * fVddc; ga = &gpus[gpu].adl; lev = ga->lpOdParameters.iNumberOfPerformanceLevels - 1; lpOdPerformanceLevels = (ADLODPerformanceLevels *)alloca(sizeof(ADLODPerformanceLevels)+(lev * sizeof(ADLODPerformanceLevel))); lpOdPerformanceLevels->iSize = sizeof(ADLODPerformanceLevels) + sizeof(ADLODPerformanceLevel) * lev; lock_adl(); if (ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels) != ADL_OK) goto out; for (i = 0; i < lev; i++) { if (lpOdPerformanceLevels->aLevels[i].iVddc > iVddc) lpOdPerformanceLevels->aLevels[i].iVddc = iVddc; } lpOdPerformanceLevels->aLevels[lev].iVddc = iVddc; ADL_Overdrive5_ODPerformanceLevels_Set(ga->iAdapterIndex, lpOdPerformanceLevels); ADL_Overdrive5_ODPerformanceLevels_Get(ga->iAdapterIndex, 0, lpOdPerformanceLevels); if (lpOdPerformanceLevels->aLevels[lev].iVddc == iVddc) ret = 0; ga->iEngineClock = lpOdPerformanceLevels->aLevels[lev].iEngineClock; ga->iMemoryClock = lpOdPerformanceLevels->aLevels[lev].iMemoryClock; ga->iVddc = lpOdPerformanceLevels->aLevels[lev].iVddc; ga->managed = true; out: unlock_adl(); return ret; } static void get_fanrange(int gpu, int *imin, int *imax) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Get fanrange not supported\n"); return; } ga = &gpus[gpu].adl; *imin = ga->lpFanSpeedInfo.iMinPercent; *imax = ga->lpFanSpeedInfo.iMaxPercent; } int set_fanspeed(int gpu, int iFanSpeed) { struct gpu_adl *ga; int ret = 1; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Set fanspeed not supported\n"); return ret; } ga = &gpus[gpu].adl; if (!(ga->lpFanSpeedInfo.iFlags & (ADL_DL_FANCTRL_SUPPORTS_RPM_WRITE | ADL_DL_FANCTRL_SUPPORTS_PERCENT_WRITE ))) { applog(LOG_DEBUG, "GPU %d doesn't support rpm or percent write", gpu); return ret; } /* Store what fanspeed we're actually aiming for for re-entrant changes * in case this device does not support fine setting changes */ ga->targetfan = iFanSpeed; lock_adl(); ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_RPM; if (ADL_Overdrive5_FanSpeed_Get(ga->iAdapterIndex, 0, &ga->lpFanSpeedValue) != ADL_OK) { applog(LOG_DEBUG, "GPU %d call to fanspeed get failed", gpu); } if (!(ga->lpFanSpeedValue.iFlags & ADL_DL_FANCTRL_FLAG_USER_DEFINED_SPEED)) { /* If user defined is not already specified, set it first */ ga->lpFanSpeedValue.iFlags |= ADL_DL_FANCTRL_FLAG_USER_DEFINED_SPEED; ADL_Overdrive5_FanSpeed_Set(ga->iAdapterIndex, 0, &ga->lpFanSpeedValue); } if (!(ga->lpFanSpeedInfo.iFlags & ADL_DL_FANCTRL_SUPPORTS_PERCENT_WRITE)) { /* Must convert speed to an RPM */ iFanSpeed = ga->lpFanSpeedInfo.iMaxRPM * iFanSpeed / 100; ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_RPM; } else ga->lpFanSpeedValue.iSpeedType = ADL_DL_FANCTRL_SPEED_TYPE_PERCENT; ga->lpFanSpeedValue.iFanSpeed = iFanSpeed; ret = ADL_Overdrive5_FanSpeed_Set(ga->iAdapterIndex, 0, &ga->lpFanSpeedValue); ga->managed = true; unlock_adl(); return ret; } #ifdef HAVE_CURSES int set_powertune(int gpu, int iPercentage) { struct gpu_adl *ga; int dummy, ret = 1; if (!gpus[gpu].has_adl || !adl_active) { wlogprint("Set powertune not supported\n"); return ret; } ga = &gpus[gpu].adl; lock_adl(); ADL_Overdrive5_PowerControl_Set(ga->iAdapterIndex, iPercentage); ADL_Overdrive5_PowerControl_Get(ga->iAdapterIndex, &ga->iPercentage, &dummy); if (ga->iPercentage == iPercentage) ret = 0; ga->managed = true; unlock_adl(); return ret; } #endif /* Returns whether the fanspeed is optimal already or not. The fan_window bool * tells us whether the current fanspeed is in the target range for fanspeeds. */ static bool fan_autotune(int gpu, int temp, int fanpercent, int lasttemp, bool *fan_window) { struct cgpu_info *cgpu = &gpus[gpu]; int tdiff = round((double)(temp - lasttemp)); struct gpu_adl *ga = &cgpu->adl; int top = gpus[gpu].gpu_fan; int bot = gpus[gpu].min_fan; int newpercent = fanpercent; int iMin = 0, iMax = 100; get_fanrange(gpu, &iMin, &iMax); if (temp > ga->overtemp && fanpercent < iMax) { applog(LOG_WARNING, "Overheat detected on GPU %d, increasing fan to 100%%", gpu); newpercent = iMax; dev_error(cgpu, REASON_DEV_OVER_HEAT); } else if (temp > ga->targettemp && fanpercent < top && tdiff >= 0) { applog(LOG_DEBUG, "Temperature over target, increasing fanspeed"); if (temp > ga->targettemp + opt_hysteresis) newpercent = ga->targetfan + 10; else newpercent = ga->targetfan + 5; if (newpercent > top) newpercent = top; } else if (fanpercent > bot && temp < ga->targettemp - opt_hysteresis) { /* Detect large swings of 5 degrees or more and change fan by * a proportion more */ if (tdiff <= 0) { applog(LOG_DEBUG, "Temperature %d degrees below target, decreasing fanspeed", opt_hysteresis); newpercent = ga->targetfan - 1 + tdiff / 5; } else if (tdiff >= 5) { applog(LOG_DEBUG, "Temperature climbed %d while below target, increasing fanspeed", tdiff); newpercent = ga->targetfan + tdiff / 5; } } else { /* We're in the optimal range, make minor adjustments if the * temp is still drifting */ if (fanpercent > bot && tdiff < 0 && lasttemp < ga->targettemp) { applog(LOG_DEBUG, "Temperature dropping while in target range, decreasing fanspeed"); newpercent = ga->targetfan + tdiff; } else if (fanpercent < top && tdiff > 0 && temp > ga->targettemp - opt_hysteresis) { applog(LOG_DEBUG, "Temperature rising while in target range, increasing fanspeed"); newpercent = ga->targetfan + tdiff; } } if (newpercent > iMax) newpercent = iMax; else if (newpercent < iMin) newpercent = iMin; if (newpercent <= top) *fan_window = true; else *fan_window = false; if (newpercent != fanpercent) { applog(LOG_INFO, "Setting GPU %d fan percentage to %d", gpu, newpercent); set_fanspeed(gpu, newpercent); /* If the fanspeed is going down and we're below the top speed, * consider the fan optimal to prevent minute changes in * fanspeed delaying GPU engine speed changes */ if (newpercent < fanpercent && *fan_window) return true; return false; } return true; } void gpu_autotune(int gpu, enum dev_enable *denable) { int temp, fanpercent, engine, newengine, twintemp = 0; bool fan_optimal = true, fan_window = true; struct cgpu_info *cgpu; struct gpu_adl *ga; int i; cgpu = &gpus[gpu]; ga = &cgpu->adl; lock_adl(); ADL_Overdrive5_CurrentActivity_Get(ga->iAdapterIndex, &ga->lpActivity); temp = __gpu_temp(ga); if (ga->twin) twintemp = __gpu_temp(ga->twin); fanpercent = __gpu_fanpercent(ga); unlock_adl(); newengine = engine = gpu_engineclock(gpu) * 100; if (temp && fanpercent >= 0 && ga->autofan) { if (!ga->twin) fan_optimal = fan_autotune(gpu, temp, fanpercent, ga->lasttemp, &fan_window); else if (ga->autofan && (ga->has_fanspeed || !ga->twin->autofan)) { /* On linked GPUs, we autotune the fan only once, based * on the highest temperature from either GPUs */ int hightemp, fan_gpu; int lasttemp; if (twintemp > temp) { lasttemp = ga->twin->lasttemp; hightemp = twintemp; } else { lasttemp = ga->lasttemp; hightemp = temp; } if (ga->has_fanspeed) fan_gpu = gpu; else fan_gpu = ga->twin->gpu; fan_optimal = fan_autotune(fan_gpu, hightemp, fanpercent, lasttemp, &fan_window); } } if (engine && ga->autoengine) { if (temp > cgpu->cutofftemp) { applog(LOG_WARNING, "Hit thermal cutoff limit on GPU %d, disabling!", gpu); *denable = DEV_RECOVER; newengine = ga->minspeed; dev_error(cgpu, REASON_DEV_THERMAL_CUTOFF); } else if (temp > ga->overtemp && engine > ga->minspeed) { applog(LOG_WARNING, "Overheat detected, decreasing GPU %d clock speed", gpu); newengine = ga->minspeed; dev_error(cgpu, REASON_DEV_OVER_HEAT); } else if (temp > ga->targettemp + opt_hysteresis && engine > ga->minspeed && fan_optimal) { applog(LOG_DEBUG, "Temperature %d degrees over target, decreasing clock speed", opt_hysteresis); newengine = engine - ga->lpOdParameters.sEngineClock.iStep; /* Only try to tune engine speed up if this GPU is not disabled */ } else if (temp < ga->targettemp && engine < ga->maxspeed && fan_window && *denable == DEV_ENABLED) { int iStep = ga->lpOdParameters.sEngineClock.iStep; applog(LOG_DEBUG, "Temperature below target, increasing clock speed"); if (temp < ga->targettemp - opt_hysteresis) iStep *= 2; newengine = engine + iStep; } else if (temp < ga->targettemp && *denable == DEV_RECOVER && opt_restart) { applog(LOG_NOTICE, "Device recovered to temperature below target, re-enabling"); *denable = DEV_ENABLED; for (i = 0; i < cgpu->threads; i++) cgsem_post(&cgpu->thr[i]->sem); } if (newengine > ga->maxspeed) newengine = ga->maxspeed; else if (newengine < ga->minspeed) newengine = ga->minspeed; /* Adjust engine clock speed if it's lower, or if it's higher * but higher than the last intended value as well as the * current speed, to avoid setting the engine clock speed to * a speed relateive to a lower profile during idle periods. */ if (newengine < engine || (newengine > engine && newengine > ga->lastengine)) { newengine /= 100; applog(LOG_INFO, "Setting GPU %d engine clock to %d", gpu, newengine); set_engineclock(gpu, newengine); } } ga->lasttemp = temp; } void set_defaultfan(int gpu) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) return; ga = &gpus[gpu].adl; lock_adl(); if (ga->def_fan_valid) ADL_Overdrive5_FanSpeed_Set(ga->iAdapterIndex, 0, &ga->DefFanSpeedValue); unlock_adl(); } void set_defaultengine(int gpu) { struct gpu_adl *ga; if (!gpus[gpu].has_adl || !adl_active) return; ga = &gpus[gpu].adl; lock_adl(); if (ga->DefPerfLev) ADL_Overdrive5_ODPerformanceLevels_Set(ga->iAdapterIndex, ga->DefPerfLev); unlock_adl(); } #ifdef HAVE_CURSES void change_autosettings(int gpu) { struct gpu_adl *ga = &gpus[gpu].adl; char input; int val; wlogprint("Target temperature: %d\n", ga->targettemp); wlogprint("Overheat temperature: %d\n", ga->overtemp); wlogprint("Cutoff temperature: %d\n", gpus[gpu].cutofftemp); wlogprint("Toggle [F]an auto [G]PU auto\nChange [T]arget [O]verheat [C]utoff\n"); wlogprint("Or press any other key to continue\n"); input = getch(); if (!strncasecmp(&input, "f", 1)) { ga->autofan ^= true; wlogprint("Fan autotune is now %s\n", ga->autofan ? "enabled" : "disabled"); if (!ga->autofan) { wlogprint("Resetting fan to startup settings\n"); set_defaultfan(gpu); } } else if (!strncasecmp(&input, "g", 1)) { ga->autoengine ^= true; wlogprint("GPU engine clock autotune is now %s\n", ga->autoengine ? "enabled" : "disabled"); if (!ga->autoengine) { wlogprint("Resetting GPU engine clock to startup settings\n"); set_defaultengine(gpu); } } else if (!strncasecmp(&input, "t", 1)) { val = curses_int("Enter target temperature for this GPU in C (0-200)"); if (val < 0 || val > 200) wlogprint("Invalid temperature"); else ga->targettemp = val; } else if (!strncasecmp(&input, "o", 1)) { wlogprint("Enter overheat temperature for this GPU in C (%d+)", ga->targettemp); val = curses_int(""); if (val <= ga->targettemp || val > 200) wlogprint("Invalid temperature"); else ga->overtemp = val; } else if (!strncasecmp(&input, "c", 1)) { wlogprint("Enter cutoff temperature for this GPU in C (%d+)", ga->overtemp); val = curses_int(""); if (val <= ga->overtemp || val > 200) wlogprint("Invalid temperature"); else gpus[gpu].cutofftemp = val; } } void change_gpusettings(int gpu) { struct gpu_adl *ga = &gpus[gpu].adl; float fval, fmin = 0, fmax = 0; int val, imin = 0, imax = 0; char input, ut_c; int engineclock = 0, memclock = 0, activity = 0, fanspeed = 0, fanpercent = 0, powertune = 0; float temp = 0, vddc = 0; double ut_best_score = 0; /* Best hashrate */ int ut_best_gpu = 0; /* Best score GPU engine clock */ int ut_best_mem = 0; /* Best score MEM clock */ int ut_gpu, ut_mem, gpu_min, gpu_max, mem_min, mem_max; int ut_gpu_resume = 0, ut_mem_resume = 0; int ut_stabledelay; /* Time to wait after applying new GPU/MEM freq. settings before taking performance measurements (ms) */ int ut_loops; int i; double displayed_rolling, displayed_total, last_rolling; bool mhash_base = true, ut_best_mhash_base; updated: if (gpu_stats(gpu, &temp, &engineclock, &memclock, &vddc, &activity, &fanspeed, &fanpercent, &powertune)) wlogprint("Temp: %.1f C\n", temp); if (fanpercent >= 0 || fanspeed >= 0) { wlogprint("Fan Speed: "); if (fanpercent >= 0) wlogprint("%d%% ", fanpercent); if (fanspeed >= 0) wlogprint("(%d RPM)", fanspeed); wlogprint("\n"); } wlogprint("Engine Clock: %d MHz\nMemory Clock: %d Mhz\nVddc: %.3f V\nActivity: %d%%\nPowertune: %d%%\n", engineclock, memclock, vddc, activity, powertune); wlogprint("Fan autotune is %s (%d-%d)\n", ga->autofan ? "enabled" : "disabled", gpus[gpu].min_fan, gpus[gpu].gpu_fan); wlogprint("GPU engine clock autotune is %s (%d-%d)\n", ga->autoengine ? "enabled" : "disabled", ga->minspeed / 100, ga->maxspeed / 100); wlogprint("Change [A]utomatic [E]ngine [F]an [M]emory [V]oltage [P]owertune [U]ltratune\n"); wlogprint("Or press any other key to continue\n"); input = getch(); if (!strncasecmp(&input, "a", 1)) { change_autosettings(gpu); } else if (!strncasecmp(&input, "e", 1)) { get_enginerange(gpu, &imin, &imax); wlogprint("Enter GPU engine clock speed (%d - %d Mhz)", imin, imax); val = curses_int(""); if (val < imin || val > imax) { wlogprint("Value is outside safe range, are you sure?\n"); input = getch(); if (strncasecmp(&input, "y", 1)) return; } if (!set_engineclock(gpu, val)) wlogprint("Driver reports success but check values below\n"); else wlogprint("Failed to modify engine clock speed\n"); } else if (!strncasecmp(&input, "f", 1)) { get_fanrange(gpu, &imin, &imax); wlogprint("Enter fan percentage (%d - %d %%)", imin, imax); val = curses_int(""); if (val < imin || val > imax) { wlogprint("Value is outside safe range, are you sure?\n"); input = getch(); if (strncasecmp(&input, "y", 1)) return; } if (!set_fanspeed(gpu, val)) wlogprint("Driver reports success but check values below\n"); else wlogprint("Failed to modify fan speed\n"); } else if (!strncasecmp(&input, "m", 1)) { get_memoryrange(gpu, &imin, &imax); wlogprint("Enter GPU memory clock speed (%d - %d Mhz)", imin, imax); val = curses_int(""); if (val < imin || val > imax) { wlogprint("Value is outside safe range, are you sure?\n"); input = getch(); if (strncasecmp(&input, "y", 1)) return; } if (!set_memoryclock(gpu, val)) wlogprint("Driver reports success but check values below\n"); else wlogprint("Failed to modify memory clock speed\n"); } else if (!strncasecmp(&input, "v", 1)) { get_vddcrange(gpu, &fmin, &fmax); wlogprint("Enter GPU voltage (%.3f - %.3f V)", fmin, fmax); fval = curses_float(""); if (fval < fmin || fval > fmax) { wlogprint("Value is outside safe range, are you sure?\n"); input = getch(); if (strncasecmp(&input, "y", 1)) return; } if (!set_vddc(gpu, fval)) wlogprint("Driver reports success but check values below\n"); else wlogprint("Failed to modify voltage\n"); } else if (!strncasecmp(&input, "p", 1)) { val = curses_int("Enter powertune value (-20 - 20)"); if (val < -20 || val > 20) { wlogprint("Value is outside safe range, are you sure?\n"); input = getch(); if (strncasecmp(&input, "y", 1)) return; } if (!set_powertune(gpu, val)) wlogprint("Driver reports success but check values below\n"); else wlogprint("Failed to modify powertune value\n"); } else if (!strncasecmp(&input, "u", 1)) { /* Ultratune - Search for optimal tuning parameters for hardware */ /* We need ADL */ if (!gpus[gpu].has_adl || !adl_active) { wlogprint("ADL must be enabled to use this feature."); cgsleep_ms(3000); return; } wlogprint("Enter MINIMUM GPU engine speed [900]"); gpu_min = curses_int(""); if (gpu_min == -1) gpu_min = 900; wlogprint("Enter MAXIMUM GPU engine speed [1150]"); gpu_max = curses_int(""); if (gpu_max == -1) gpu_max = 1150; wlogprint("Enter MINIMUM MEMORY speed [1400]"); mem_min = curses_int(""); if (mem_min == -1) mem_min = 1400; wlogprint("Enter MAXIMUM MEMORY speed [1750]"); mem_max = curses_int(""); if (mem_max == -1) mem_max = 1750; wlogprint("Enter stabilization time (ms) [5000]"); ut_stabledelay = curses_int(""); if (!ut_stabledelay) ut_stabledelay = 5000; wlogprint("Resume from previous session? (y/n)"); ut_c = getch(); wlogprint("\n"); if (!strncasecmp(&ut_c, "y", 1)) { wlogprint("Enter previous session's best GPU clock (MHz)"); ut_gpu_resume = curses_int(""); if (!ut_gpu_resume) ut_gpu_resume = 0; wlogprint("Enter previous session's best MEMORY clock (MHz)"); ut_mem_resume = curses_int(""); if (!ut_mem_resume) ut_mem_resume = 0; } clear_logwin(); wlogprint("Here comes *LOTS* of trial and error, be patient...\n"); ut_best_score = 0; ut_best_mhash_base = mhash_base; ut_best_gpu = engineclock; ut_best_mem = memclock; /* Increase the GPU clock from MIN to MAX and run through various memory settings for each speed */ for (ut_gpu = gpu_min; ut_gpu <= gpu_max; ut_gpu += 10) { /* Resume? */ if (ut_gpu_resume) { ut_gpu = ut_gpu_resume; ut_gpu_resume = 0; } /* Set GPU clock speed */ if (set_engineclock(gpu, ut_gpu)) { /* Failed, wait a couple seconds and try again */ wlogprint("Failed to set GPU clock to %d MHz. Trying again...\n", ut_gpu); cgsleep_ms(2000); if (set_engineclock(gpu, ut_gpu)) { wlogprint("Failed to set GPU clock to %d MHz. Ultratune Aborted.\n", ut_gpu); input = getch(); return; } } /* Run through memory speeds to find the best one for this GPU freq. */ ut_loops = 0; for (ut_mem = mem_min; ut_mem <= mem_max; ut_mem += 5) { ut_loops++; /* Resume? */ if (ut_mem_resume) { ut_mem = ut_mem_resume; ut_mem_resume = 0; } /* Set new memory speed */ if (set_memoryclock(gpu, ut_mem)) { /* Failed, wait a couple seconds and try again */ wlogprint("Failed to set MEM clock to %d MHz. Trying again...\n", ut_mem); cgsleep_ms(2000); if (set_memoryclock(gpu, ut_mem)) { wlogprint("Failed to set MEM clock to %d MHz. Ultratune Aborted.\n", ut_mem); input = getch(); return; } } wlogprint("Ultratune Clocks: GPU: %d MHz, MEM: %d", ut_gpu, ut_mem); cgsleep_ms(ut_stabledelay); /* Loop if the hash rate is increasing */ /* This loop is tuned (number of loops + delay) based on trial and error */ last_rolling = gpus[gpu].rolling; for (i = 0; i < 6; i++) { cgsleep_ms(1250); /* keep waiting? */ if (gpus[gpu].rolling > last_rolling) { last_rolling = gpus[gpu].rolling; /* Wait around even longer if hashes are going up occasionally */ if (i) i--; if (i) i--; continue; } } displayed_rolling = last_rolling; displayed_total = gpus[gpu].total_mhashes / total_secs; ut_best_mhash_base = true; if (displayed_rolling < 1) { displayed_rolling *= 1000; displayed_total *= 1000; mhash_base = false; ut_best_mhash_base = mhash_base; } /* Display score */ wlogprint(", Score: %.1f%sh/s, Ratio: %.3f\n", displayed_rolling, mhash_base ? "M" : "K", (double) ut_gpu / ut_mem); /* Record the score */ if (last_rolling > ut_best_score) { ut_best_score = last_rolling; ut_best_gpu = ut_gpu; ut_best_mem = ut_mem; } /* Show Ultratune's best settings */ if (!(ut_loops % 5)) { wlogprint("Best Settings (so far): GPU = %d MHz, MEM = %d MHz, Score = %.1f%sh\n", ut_best_gpu, ut_best_mem, ut_best_score < 1 ? ut_best_score * 1000 : ut_best_score, ut_best_mhash_base ? "M" : "K"); } /* Remind the user how to quit once in a while */ if (!(ut_loops % 10)) { wlogprint("Press Ctrl-C to Quit. Write down best GPU/MEM settings (above).\n"); } } } /* Ultratune finished */ wlogprint("Best Settings: GPU = %d MHz, MEM = %d MHz, Score: %.1f%sh, Ratio: %.3f\n", ut_best_gpu, ut_best_mem, ut_best_score < 1 ? ut_best_score * 1000 : ut_best_score, ut_best_mhash_base ? "M" : "K", (double) ut_best_gpu / ut_best_mem); /* Set the card to the best settings */ if (set_engineclock(gpu, ut_best_gpu)) { /* Failed */ wlogprint("Failed to set GPU engine clock to %d MHz. Ultratune Aborted.", ut_best_gpu); input = getch(); return; } if (set_memoryclock(gpu, ut_best_mem)) { /* Failed */ wlogprint("Failed to set MEM engine clock to %d MHz. Ultratune Aborted.", ut_best_mem); input = getch(); return; } wlogprint("Ultratune Finished. Write down the above values then press any key.\n"); input = getch(); } else { clear_logwin(); return; } cgsleep_ms(1000); goto updated; } #endif static void free_adl(void) { ADL_Main_Memory_Free ((void **)&lpInfo); ADL_Main_Control_Destroy (); #if defined (UNIX) dlclose(hDLL); #else FreeLibrary(hDLL); #endif } void clear_adl(int nDevs) { struct gpu_adl *ga; int i; if (!adl_active) return; lock_adl(); /* Try to reset values to their defaults */ for (i = 0; i < nDevs; i++) { ga = &gpus[i].adl; /* Only reset the values if we've changed them at any time */ if (!gpus[i].has_adl || !ga->managed || !ga->DefPerfLev) continue; ADL_Overdrive5_ODPerformanceLevels_Set(ga->iAdapterIndex, ga->DefPerfLev); free(ga->DefPerfLev); if (ga->def_fan_valid) ADL_Overdrive5_FanSpeed_Set(ga->iAdapterIndex, 0, &ga->DefFanSpeedValue); ADL_Overdrive5_FanSpeedToDefault_Set(ga->iAdapterIndex, 0); } adl_active = false; unlock_adl(); free_adl(); } #endif /* HAVE_ADL */