GOSTCoin CUDA miner project, compatible with most nvidia cards, containing only gostd algo
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/*
* A trivial little dlopen()-based wrapper library for the
* NVIDIA NVML library, to allow runtime discovery of NVML on an
* arbitrary system. This is all very hackish and simple-minded, but
* it serves my immediate needs in the short term until NVIDIA provides
* a static NVML wrapper library themselves, hopefully in
* CUDA 6.5 or maybe sometime shortly after.
*
* This trivial code is made available under the "new" 3-clause BSD license,
* and/or any of the GPL licenses you prefer.
* Feel free to use the code and modify as you see fit.
*
* John E. Stone - john.stone@gmail.com
* Tanguy Pruvot - tpruvot@github
*
*/
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "miner.h"
#include "nvml.h"
#include "cuda_runtime.h"
#ifdef USE_WRAPNVML
extern nvml_handle *hnvml;
extern char driver_version[32];
static uint32_t device_bus_ids[MAX_GPUS] = { 0 };
extern uint32_t device_gpu_clocks[MAX_GPUS];
extern uint32_t device_mem_clocks[MAX_GPUS];
extern uint32_t device_plimit[MAX_GPUS];
extern uint8_t device_tlimit[MAX_GPUS];
extern int8_t device_pstate[MAX_GPUS];
extern int32_t device_led[MAX_GPUS];
int32_t device_led_state[MAX_GPUS] = { 0 };
static __thread bool has_rgb_ok = false;
uint32_t clock_prev[MAX_GPUS] = { 0 };
uint32_t clock_prev_mem[MAX_GPUS] = { 0 };
uint32_t limit_prev[MAX_GPUS] = { 0 };
/*
* Wrappers to emulate dlopen() on other systems like Windows
*/
#if defined(_MSC_VER) || defined(_WIN32) || defined(_WIN64)
#include <windows.h>
static void *wrap_dlopen(const char *filename) {
HMODULE h = LoadLibrary(filename);
if (!h && opt_debug) {
applog(LOG_DEBUG, "dlopen(%d): failed to load %s",
GetLastError(), filename);
}
return (void*)h;
}
static void *wrap_dlsym(void *h, const char *sym) {
return (void *)GetProcAddress((HINSTANCE)h, sym);
}
static int wrap_dlclose(void *h) {
/* FreeLibrary returns nonzero on success */
return (!FreeLibrary((HINSTANCE)h));
}
#else
/* assume we can use dlopen itself... */
#include <dlfcn.h>
#include <errno.h>
static void *wrap_dlopen(const char *filename) {
void *h = dlopen(filename, RTLD_NOW);
if (h == NULL && opt_debug) {
applog(LOG_DEBUG, "dlopen(%d): failed to load %s",
errno, filename);
}
return (void*)h;
}
static void *wrap_dlsym(void *h, const char *sym) {
return dlsym(h, sym);
}
static int wrap_dlclose(void *h) {
return dlclose(h);
}
#endif
nvml_handle * nvml_create()
{
int i=0;
nvml_handle *nvmlh = NULL;
#if defined(WIN32)
/* Windows (do not use slashes, else ExpandEnvironmentStrings will mix them) */
#define libnvidia_ml "%PROGRAMFILES%\\NVIDIA Corporation\\NVSMI\\nvml.dll"
#else
/* linux assumed */
#define libnvidia_ml "libnvidia-ml.so"
#endif
char tmp[512];
#ifdef WIN32
ExpandEnvironmentStrings(libnvidia_ml, tmp, sizeof(tmp));
#else
strcpy(tmp, libnvidia_ml);
#endif
void *nvml_dll = wrap_dlopen(tmp);
if (nvml_dll == NULL) {
#ifdef WIN32
nvml_dll = wrap_dlopen("nvml.dll");
if (nvml_dll == NULL)
#endif
return NULL;
}
nvmlh = (nvml_handle *) calloc(1, sizeof(nvml_handle));
nvmlh->nvml_dll = nvml_dll;
nvmlh->nvmlInit = (nvmlReturn_t (*)(void)) wrap_dlsym(nvmlh->nvml_dll, "nvmlInit_v2");
if (!nvmlh->nvmlInit)
nvmlh->nvmlInit = (nvmlReturn_t (*)(void)) wrap_dlsym(nvmlh->nvml_dll, "nvmlInit");
nvmlh->nvmlDeviceGetCount = (nvmlReturn_t (*)(int *)) wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetCount_v2");
if (!nvmlh->nvmlDeviceGetCount)
nvmlh->nvmlDeviceGetCount = (nvmlReturn_t (*)(int *)) wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetCount");
nvmlh->nvmlDeviceGetHandleByIndex = (nvmlReturn_t (*)(int, nvmlDevice_t *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetHandleByIndex_v2");
nvmlh->nvmlDeviceGetAPIRestriction = (nvmlReturn_t (*)(nvmlDevice_t, nvmlRestrictedAPI_t, nvmlEnableState_t *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetAPIRestriction");
nvmlh->nvmlDeviceSetAPIRestriction = (nvmlReturn_t (*)(nvmlDevice_t, nvmlRestrictedAPI_t, nvmlEnableState_t))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceSetAPIRestriction");
nvmlh->nvmlDeviceGetDefaultApplicationsClock = (nvmlReturn_t (*)(nvmlDevice_t, nvmlClockType_t, unsigned int *clock))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetDefaultApplicationsClock");
nvmlh->nvmlDeviceGetApplicationsClock = (nvmlReturn_t (*)(nvmlDevice_t, nvmlClockType_t, unsigned int *clocks))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetApplicationsClock");
nvmlh->nvmlDeviceSetApplicationsClocks = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int mem, unsigned int gpu))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceSetApplicationsClocks");
nvmlh->nvmlDeviceResetApplicationsClocks = (nvmlReturn_t (*)(nvmlDevice_t))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceResetApplicationsClocks");
nvmlh->nvmlDeviceGetSupportedGraphicsClocks = (nvmlReturn_t (*)(nvmlDevice_t, uint32_t mem, uint32_t *num, uint32_t *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetSupportedGraphicsClocks");
nvmlh->nvmlDeviceGetSupportedMemoryClocks = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *count, unsigned int *clocksMHz))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetSupportedMemoryClocks");
nvmlh->nvmlDeviceGetClockInfo = (nvmlReturn_t (*)(nvmlDevice_t, nvmlClockType_t, unsigned int *clock))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetClockInfo");
nvmlh->nvmlDeviceGetMaxClockInfo = (nvmlReturn_t (*)(nvmlDevice_t, nvmlClockType_t, unsigned int *clock))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetMaxClockInfo");
nvmlh->nvmlDeviceGetPciInfo = (nvmlReturn_t (*)(nvmlDevice_t, nvmlPciInfo_t *)) wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPciInfo_v2");
if (!nvmlh->nvmlDeviceGetPciInfo)
nvmlh->nvmlDeviceGetPciInfo = (nvmlReturn_t (*)(nvmlDevice_t, nvmlPciInfo_t *)) wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPciInfo");
nvmlh->nvmlDeviceGetCurrPcieLinkGeneration = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *gen))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetCurrPcieLinkGeneration");
nvmlh->nvmlDeviceGetCurrPcieLinkWidth = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *width))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetCurrPcieLinkWidth");
nvmlh->nvmlDeviceGetMaxPcieLinkGeneration = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *gen))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetMaxPcieLinkGeneration");
nvmlh->nvmlDeviceGetMaxPcieLinkWidth = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *width))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetMaxPcieLinkWidth");
nvmlh->nvmlDeviceGetPowerUsage = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPowerUsage");
nvmlh->nvmlDeviceGetPowerManagementDefaultLimit = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *limit))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPowerManagementDefaultLimit");
nvmlh->nvmlDeviceGetPowerManagementLimit = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *limit))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPowerManagementLimit");
nvmlh->nvmlDeviceGetPowerManagementLimitConstraints = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *min, unsigned int *max))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPowerManagementLimitConstraints");
nvmlh->nvmlDeviceSetPowerManagementLimit = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int limit))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceSetPowerManagementLimit");
nvmlh->nvmlDeviceGetName = (nvmlReturn_t (*)(nvmlDevice_t, char *, int))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetName");
nvmlh->nvmlDeviceGetTemperature = (nvmlReturn_t (*)(nvmlDevice_t, int, unsigned int *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetTemperature");
nvmlh->nvmlDeviceGetFanSpeed = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetFanSpeed");
nvmlh->nvmlDeviceGetPerformanceState = (nvmlReturn_t (*)(nvmlDevice_t, int *))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPerformanceState"); /* or nvmlDeviceGetPowerState */
nvmlh->nvmlDeviceGetSerial = (nvmlReturn_t (*)(nvmlDevice_t, char *, unsigned int))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetSerial");
nvmlh->nvmlDeviceGetUUID = (nvmlReturn_t (*)(nvmlDevice_t, char *, unsigned int))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetUUID");
nvmlh->nvmlDeviceGetVbiosVersion = (nvmlReturn_t (*)(nvmlDevice_t, char *, unsigned int))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetVbiosVersion");
nvmlh->nvmlSystemGetDriverVersion = (nvmlReturn_t (*)(char *, unsigned int))
wrap_dlsym(nvmlh->nvml_dll, "nvmlSystemGetDriverVersion");
nvmlh->nvmlErrorString = (char* (*)(nvmlReturn_t))
wrap_dlsym(nvmlh->nvml_dll, "nvmlErrorString");
nvmlh->nvmlShutdown = (nvmlReturn_t (*)())
wrap_dlsym(nvmlh->nvml_dll, "nvmlShutdown");
// v331
nvmlh->nvmlDeviceGetEnforcedPowerLimit = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int *limit))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetEnforcedPowerLimit");
// v340
#ifdef __linux__
nvmlh->nvmlDeviceClearCpuAffinity = (nvmlReturn_t (*)(nvmlDevice_t))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceClearCpuAffinity");
nvmlh->nvmlDeviceGetCpuAffinity = (nvmlReturn_t (*)(nvmlDevice_t, unsigned int sz, unsigned long *cpuSet))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetCpuAffinity");
nvmlh->nvmlDeviceSetCpuAffinity = (nvmlReturn_t (*)(nvmlDevice_t))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceSetCpuAffinity");
#endif
// v346
nvmlh->nvmlDeviceGetPcieThroughput = (nvmlReturn_t (*)(nvmlDevice_t, nvmlPcieUtilCounter_t, unsigned int *value))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetPcieThroughput");
// v36x (API 8 / Pascal)
nvmlh->nvmlDeviceGetClock = (nvmlReturn_t (*)(nvmlDevice_t, nvmlClockType_t clockType, nvmlClockId_t clockId, unsigned int *clockMHz))
wrap_dlsym(nvmlh->nvml_dll, "nvmlDeviceGetClock");
if (nvmlh->nvmlInit == NULL ||
nvmlh->nvmlShutdown == NULL ||
nvmlh->nvmlErrorString == NULL ||
nvmlh->nvmlDeviceGetCount == NULL ||
nvmlh->nvmlDeviceGetHandleByIndex == NULL ||
nvmlh->nvmlDeviceGetPciInfo == NULL ||
nvmlh->nvmlDeviceGetName == NULL)
{
if (opt_debug)
applog(LOG_DEBUG, "Failed to obtain required NVML function pointers");
wrap_dlclose(nvmlh->nvml_dll);
free(nvmlh);
return NULL;
}
nvmlh->nvmlInit();
if (nvmlh->nvmlSystemGetDriverVersion)
nvmlh->nvmlSystemGetDriverVersion(driver_version, sizeof(driver_version));
nvmlh->nvmlDeviceGetCount(&nvmlh->nvml_gpucount);
/* Query CUDA device count, in case it doesn't agree with NVML, since */
/* CUDA will only report GPUs with compute capability greater than 1.0 */
if (cudaGetDeviceCount(&nvmlh->cuda_gpucount) != cudaSuccess) {
if (opt_debug)
applog(LOG_DEBUG, "Failed to query CUDA device count!");
wrap_dlclose(nvmlh->nvml_dll);
free(nvmlh);
return NULL;
}
nvmlh->devs = (nvmlDevice_t *) calloc(nvmlh->nvml_gpucount, sizeof(nvmlDevice_t));
nvmlh->nvml_pci_domain_id = (unsigned int*) calloc(nvmlh->nvml_gpucount, sizeof(unsigned int));
nvmlh->nvml_pci_bus_id = (unsigned int*) calloc(nvmlh->nvml_gpucount, sizeof(unsigned int));
nvmlh->nvml_pci_device_id = (unsigned int*) calloc(nvmlh->nvml_gpucount, sizeof(unsigned int));
nvmlh->nvml_pci_subsys_id = (unsigned int*) calloc(nvmlh->nvml_gpucount, sizeof(unsigned int));
nvmlh->nvml_cuda_device_id = (int*) calloc(nvmlh->nvml_gpucount, sizeof(int));
nvmlh->cuda_nvml_device_id = (int*) calloc(nvmlh->cuda_gpucount, sizeof(int));
nvmlh->app_clocks = (nvmlEnableState_t*) calloc(nvmlh->nvml_gpucount, sizeof(nvmlEnableState_t));
/* Obtain GPU device handles we're going to need repeatedly... */
for (i=0; i<nvmlh->nvml_gpucount; i++) {
nvmlh->nvmlDeviceGetHandleByIndex(i, &nvmlh->devs[i]);
}
/* Query PCI info for each NVML device, and build table for mapping of */
/* CUDA device IDs to NVML device IDs and vice versa */
for (i=0; i<nvmlh->nvml_gpucount; i++) {
nvmlPciInfo_t pciinfo;
nvmlh->nvmlDeviceGetPciInfo(nvmlh->devs[i], &pciinfo);
nvmlh->nvml_pci_domain_id[i] = pciinfo.domain;
nvmlh->nvml_pci_bus_id[i] = pciinfo.bus;
nvmlh->nvml_pci_device_id[i] = pciinfo.device;
nvmlh->nvml_pci_subsys_id[i] = pciinfo.pci_subsystem_id;
nvmlh->app_clocks[i] = NVML_FEATURE_UNKNOWN;
if (nvmlh->nvmlDeviceSetAPIRestriction) {
nvmlh->nvmlDeviceSetAPIRestriction(nvmlh->devs[i], NVML_RESTRICTED_API_SET_APPLICATION_CLOCKS,
NVML_FEATURE_ENABLED);
/* there is only this API_SET_APPLICATION_CLOCKS on the 750 Ti (340.58) */
}
if (nvmlh->nvmlDeviceGetAPIRestriction) {
nvmlh->nvmlDeviceGetAPIRestriction(nvmlh->devs[i], NVML_RESTRICTED_API_SET_APPLICATION_CLOCKS,
&nvmlh->app_clocks[i]);
}
}
/* build mapping of NVML device IDs to CUDA IDs */
for (i=0; i<nvmlh->nvml_gpucount; i++) {
nvmlh->nvml_cuda_device_id[i] = -1;
}
for (i=0; i<nvmlh->cuda_gpucount; i++) {
cudaDeviceProp props;
nvmlh->cuda_nvml_device_id[i] = -1;
if (cudaGetDeviceProperties(&props, i) == cudaSuccess) {
device_bus_ids[i] = props.pciBusID;
for (int j = 0; j < nvmlh->nvml_gpucount; j++) {
if ((nvmlh->nvml_pci_domain_id[j] == (uint32_t) props.pciDomainID) &&
(nvmlh->nvml_pci_bus_id[j] == (uint32_t) props.pciBusID) &&
(nvmlh->nvml_pci_device_id[j] == (uint32_t) props.pciDeviceID)) {
if (opt_debug)
applog(LOG_DEBUG, "CUDA GPU %d matches NVML GPU %d by busId %u",
i, j, (uint32_t) props.pciBusID);
nvmlh->nvml_cuda_device_id[j] = i;
nvmlh->cuda_nvml_device_id[i] = j;
}
}
}
}
return nvmlh;
}
/* apply config clocks to an used device */
int nvml_set_clocks(nvml_handle *nvmlh, int dev_id)
{
nvmlReturn_t rc;
uint32_t gpu_clk = 0, mem_clk = 0;
int n = nvmlh->cuda_nvml_device_id[dev_id];
if (n < 0 || n >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!device_gpu_clocks[dev_id] && !device_mem_clocks[dev_id])
return 0; // nothing to do
if (nvmlh->app_clocks[n] != NVML_FEATURE_ENABLED) {
applog(LOG_WARNING, "GPU #%d: NVML application clock feature is not allowed!", dev_id);
return -EPERM;
}
uint32_t mem_prev = clock_prev_mem[dev_id];
if (!mem_prev)
nvmlh->nvmlDeviceGetApplicationsClock(nvmlh->devs[n], NVML_CLOCK_MEM, &mem_prev);
uint32_t gpu_prev = clock_prev[dev_id];
if (!gpu_prev)
nvmlh->nvmlDeviceGetApplicationsClock(nvmlh->devs[n], NVML_CLOCK_GRAPHICS, &gpu_prev);
nvmlh->nvmlDeviceGetDefaultApplicationsClock(nvmlh->devs[n], NVML_CLOCK_MEM, &mem_clk);
rc = nvmlh->nvmlDeviceGetDefaultApplicationsClock(nvmlh->devs[n], NVML_CLOCK_GRAPHICS, &gpu_clk);
if (rc != NVML_SUCCESS) {
applog(LOG_WARNING, "GPU #%d: unable to query application clocks", dev_id);
return -EINVAL;
}
if (opt_debug)
applog(LOG_DEBUG, "GPU #%d: default application clocks are %u/%u", dev_id, mem_clk, gpu_clk);
// get application config values
if (device_mem_clocks[dev_id]) mem_clk = device_mem_clocks[dev_id];
if (device_gpu_clocks[dev_id]) gpu_clk = device_gpu_clocks[dev_id];
// these functions works for the 960 and the 970 (346.72+), and for the 750 Ti with driver ~361+
uint32_t nclocks = 0, mem_clocks[32] = { 0 };
nvmlh->nvmlDeviceGetSupportedMemoryClocks(nvmlh->devs[n], &nclocks, NULL);
nclocks = min(nclocks, 32);
if (nclocks)
nvmlh->nvmlDeviceGetSupportedMemoryClocks(nvmlh->devs[n], &nclocks, mem_clocks);
for (uint8_t u=0; u < nclocks; u++) {
// ordered by pstate (so highest is first memory clock - P0)
if (mem_clocks[u] <= mem_clk) {
mem_clk = mem_clocks[u];
break;
}
}
uint32_t* gpu_clocks = NULL;
nclocks = 0;
nvmlh->nvmlDeviceGetSupportedGraphicsClocks(nvmlh->devs[n], mem_clk, &nclocks, NULL);
if (nclocks) {
if (opt_debug)
applog(LOG_DEBUG, "GPU #%d: %u clocks found for mem %u", dev_id, nclocks, mem_clk);
gpu_clocks = (uint32_t*) calloc(1, sizeof(uint32_t) * nclocks + 4);
nvmlh->nvmlDeviceGetSupportedGraphicsClocks(nvmlh->devs[n], mem_clk, &nclocks, gpu_clocks);
for (uint8_t u=0; u < nclocks; u++) {
// ordered desc, so get first
if (gpu_clocks[u] <= gpu_clk) {
gpu_clk = gpu_clocks[u];
break;
}
}
free(gpu_clocks);
}
rc = nvmlh->nvmlDeviceSetApplicationsClocks(nvmlh->devs[n], mem_clk, gpu_clk);
if (rc == NVML_SUCCESS)
applog(LOG_INFO, "GPU #%d: application clocks set to %u/%u", dev_id, mem_clk, gpu_clk);
else {
applog(LOG_WARNING, "GPU #%d: %u/%u - %s (NVML)", dev_id, mem_clk, gpu_clk, nvmlh->nvmlErrorString(rc));
return -1;
}
// store previous clocks for reset on exit (or during wait...)
clock_prev[dev_id] = gpu_prev;
clock_prev_mem[dev_id] = mem_prev;
return 1;
}
/* reset default app clocks and limits on exit */
int nvml_reset_clocks(nvml_handle *nvmlh, int dev_id)
{
int ret = 0;
nvmlReturn_t rc;
uint32_t gpu_clk = 0, mem_clk = 0;
int n = nvmlh->cuda_nvml_device_id[dev_id];
if (n < 0 || n >= nvmlh->nvml_gpucount)
return -ENODEV;
if (clock_prev[dev_id]) {
rc = nvmlh->nvmlDeviceResetApplicationsClocks(nvmlh->devs[n]);
if (rc != NVML_SUCCESS) {
applog(LOG_WARNING, "GPU #%d: unable to reset application clocks", dev_id);
}
clock_prev[dev_id] = 0;
ret = 1;
}
if (limit_prev[dev_id]) {
uint32_t plimit = limit_prev[dev_id];
if (nvmlh->nvmlDeviceGetPowerManagementDefaultLimit && !plimit) {
rc = nvmlh->nvmlDeviceGetPowerManagementDefaultLimit(nvmlh->devs[n], &plimit);
} else if (plimit) {
rc = NVML_SUCCESS;
}
if (rc == NVML_SUCCESS)
nvmlh->nvmlDeviceSetPowerManagementLimit(nvmlh->devs[n], plimit);
ret = 1;
}
return ret;
}
/**
* Set power state of a device (9xx)
* Code is similar as clocks one, which allow the change of the pstate
*/
int nvml_set_pstate(nvml_handle *nvmlh, int dev_id)
{
nvmlReturn_t rc;
uint32_t gpu_clk = 0, mem_clk = 0;
int n = nvmlh->cuda_nvml_device_id[dev_id];
if (n < 0 || n >= nvmlh->nvml_gpucount)
return -ENODEV;
if (device_pstate[dev_id] < 0)
return 0;
if (nvmlh->app_clocks[n] != NVML_FEATURE_ENABLED) {
applog(LOG_WARNING, "GPU #%d: NVML app. clock feature is not allowed!", dev_id);
return -EPERM;
}
nvmlh->nvmlDeviceGetDefaultApplicationsClock(nvmlh->devs[n], NVML_CLOCK_MEM, &mem_clk);
rc = nvmlh->nvmlDeviceGetDefaultApplicationsClock(nvmlh->devs[n], NVML_CLOCK_GRAPHICS, &gpu_clk);
if (rc != NVML_SUCCESS) {
applog(LOG_WARNING, "GPU #%d: unable to query application clocks", dev_id);
return -EINVAL;
}
// get application config values
if (device_mem_clocks[dev_id]) mem_clk = device_mem_clocks[dev_id];
if (device_gpu_clocks[dev_id]) gpu_clk = device_gpu_clocks[dev_id];
// these functions works for the 960 and the 970 (346.72+), and for the 750 Ti with driver ~361+
uint32_t nclocks = 0, mem_clocks[32] = { 0 };
int8_t wanted_pstate = device_pstate[dev_id];
nvmlh->nvmlDeviceGetSupportedMemoryClocks(nvmlh->devs[n], &nclocks, NULL);
nclocks = min(nclocks, 32);
if (nclocks)
nvmlh->nvmlDeviceGetSupportedMemoryClocks(nvmlh->devs[n], &nclocks, mem_clocks);
if ((uint32_t) wanted_pstate+1 > nclocks) {
applog(LOG_WARNING, "GPU #%d: only %u mem clocks available (p-states)", dev_id, nclocks);
}
for (uint8_t u=0; u < nclocks; u++) {
// ordered by pstate (so highest P0 first)
if (u == wanted_pstate) {
mem_clk = mem_clocks[u];
break;
}
}
uint32_t* gpu_clocks = NULL;
nclocks = 0;
nvmlh->nvmlDeviceGetSupportedGraphicsClocks(nvmlh->devs[n], mem_clk, &nclocks, NULL);
if (nclocks) {
gpu_clocks = (uint32_t*) calloc(1, sizeof(uint32_t) * nclocks + 4);
rc = nvmlh->nvmlDeviceGetSupportedGraphicsClocks(nvmlh->devs[n], mem_clk, &nclocks, gpu_clocks);
if (rc == NVML_SUCCESS) {
// ordered desc, get the max app clock (do not limit)
gpu_clk = gpu_clocks[0];
}
free(gpu_clocks);
}
rc = nvmlh->nvmlDeviceSetApplicationsClocks(nvmlh->devs[n], mem_clk, gpu_clk);
if (rc != NVML_SUCCESS) {
applog(LOG_WARNING, "GPU #%d: pstate P%d (%u/%u) %s", dev_id, (int) wanted_pstate,
mem_clk, gpu_clk, nvmlh->nvmlErrorString(rc));
return -1;
}
if (!opt_quiet)
applog(LOG_INFO, "GPU #%d: app clocks set to P%d (%u/%u)", dev_id, (int) wanted_pstate, mem_clk, gpu_clk);
clock_prev[dev_id] = 1;
return 1;
}
int nvml_set_plimit(nvml_handle *nvmlh, int dev_id)
{
nvmlReturn_t rc = NVML_ERROR_UNKNOWN;
uint32_t gpu_clk = 0, mem_clk = 0;
int n = nvmlh->cuda_nvml_device_id[dev_id];
if (n < 0 || n >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!device_plimit[dev_id])
return 0; // nothing to do
if (!nvmlh->nvmlDeviceSetPowerManagementLimit)
return -ENOSYS;
uint32_t plimit = device_plimit[dev_id] * 1000;
uint32_t pmin = 1000, pmax = 0, prev_limit = 0;
if (nvmlh->nvmlDeviceGetPowerManagementLimitConstraints)
rc = nvmlh->nvmlDeviceGetPowerManagementLimitConstraints(nvmlh->devs[n], &pmin, &pmax);
if (rc != NVML_SUCCESS) {
if (!nvmlh->nvmlDeviceGetPowerManagementLimit)
return -ENOSYS;
}
nvmlh->nvmlDeviceGetPowerManagementLimit(nvmlh->devs[n], &prev_limit);
if (!pmax) pmax = prev_limit;
plimit = min(plimit, pmax);
plimit = max(plimit, pmin);
rc = nvmlh->nvmlDeviceSetPowerManagementLimit(nvmlh->devs[n], plimit);
if (rc != NVML_SUCCESS) {
applog(LOG_WARNING, "GPU #%d: plimit %s", dev_id, nvmlh->nvmlErrorString(rc));
return -1;
}
if (!opt_quiet) {
applog(LOG_INFO, "GPU #%d: power limit set to %uW (allowed range is %u-%u)",
dev_id, plimit/1000U, pmin/1000U, pmax/1000U);
}
limit_prev[dev_id] = prev_limit;
return 1;
}
// ccminer -D -n
#define LSTDEV_PFX " "
void nvml_print_device_info(int dev_id)
{
if (!hnvml) return;
int n = hnvml->cuda_nvml_device_id[dev_id];
if (n < 0 || n >= hnvml->nvml_gpucount)
return;
nvmlReturn_t rc;
if (hnvml->nvmlDeviceGetClock) {
uint32_t gpu_clk = 0, mem_clk = 0;
fprintf(stderr, "------- Clocks -------\n");
hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_GRAPHICS, NVML_CLOCK_ID_APP_CLOCK_DEFAULT, &gpu_clk);
rc = hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_MEM, NVML_CLOCK_ID_APP_CLOCK_DEFAULT, &mem_clk);
if (rc == NVML_SUCCESS) {
fprintf(stderr, LSTDEV_PFX "DEFAULT MEM %4u GPU %4u MHz\n", mem_clk, gpu_clk);
}
hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_GRAPHICS, NVML_CLOCK_ID_APP_CLOCK_TARGET, &gpu_clk);
rc = hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_MEM, NVML_CLOCK_ID_APP_CLOCK_TARGET, &mem_clk);
if (rc == NVML_SUCCESS) {
fprintf(stderr, LSTDEV_PFX "TARGET MEM %4u GPU %4u MHz\n", mem_clk, gpu_clk);
}
hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_GRAPHICS, NVML_CLOCK_ID_CURRENT, &gpu_clk);
rc = hnvml->nvmlDeviceGetClock(hnvml->devs[n], NVML_CLOCK_MEM, NVML_CLOCK_ID_CURRENT, &mem_clk);
if (rc == NVML_SUCCESS) {
fprintf(stderr, LSTDEV_PFX "CURRENT MEM %4u GPU %4u MHz\n", mem_clk, gpu_clk);
}
}
}
int nvml_get_gpucount(nvml_handle *nvmlh, int *gpucount)
{
*gpucount = nvmlh->nvml_gpucount;
return 0;
}
int cuda_get_gpucount(nvml_handle *nvmlh, int *gpucount)
{
*gpucount = nvmlh->cuda_gpucount;
return 0;
}
int nvml_get_gpu_name(nvml_handle *nvmlh, int cudaindex, char *namebuf, int bufsize)
{
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetName)
return -ENOSYS;
if (nvmlh->nvmlDeviceGetName(nvmlh->devs[gpuindex], namebuf, bufsize) != NVML_SUCCESS)
return -1;
return 0;
}
int nvml_get_tempC(nvml_handle *nvmlh, int cudaindex, unsigned int *tempC)
{
nvmlReturn_t rc;
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetTemperature)
return -ENOSYS;
rc = nvmlh->nvmlDeviceGetTemperature(nvmlh->devs[gpuindex], 0u /* NVML_TEMPERATURE_GPU */, tempC);
if (rc != NVML_SUCCESS) {
return -1;
}
return 0;
}
int nvml_get_fanpcnt(nvml_handle *nvmlh, int cudaindex, unsigned int *fanpcnt)
{
nvmlReturn_t rc;
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetFanSpeed)
return -ENOSYS;
rc = nvmlh->nvmlDeviceGetFanSpeed(nvmlh->devs[gpuindex], fanpcnt);
if (rc != NVML_SUCCESS) {
return -1;
}
return 0;
}
int nvml_get_current_clocks(int cudaindex, uint32_t *graphics_clock, uint32_t *mem_clock)
{
nvmlReturn_t rc;
int gpuindex = hnvml->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= hnvml->nvml_gpucount) return -ENODEV;
if (!hnvml->nvmlDeviceGetClockInfo) return -ENOSYS;
rc = hnvml->nvmlDeviceGetClockInfo(hnvml->devs[gpuindex], NVML_CLOCK_SM, graphics_clock);
if (rc != NVML_SUCCESS) return -1;
rc = hnvml->nvmlDeviceGetClockInfo(hnvml->devs[gpuindex], NVML_CLOCK_MEM, mem_clock);
if (rc != NVML_SUCCESS) return -1;
return 0;
}
/* Not Supported on 750Ti 340.23 */
int nvml_get_power_usage(nvml_handle *nvmlh, int cudaindex, unsigned int *milliwatts)
{
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetPowerUsage)
return -ENOSYS;
nvmlReturn_t res = nvmlh->nvmlDeviceGetPowerUsage(nvmlh->devs[gpuindex], milliwatts);
if (res != NVML_SUCCESS) {
//if (opt_debug)
// applog(LOG_DEBUG, "nvmlDeviceGetPowerUsage: %s", nvmlh->nvmlErrorString(res));
return -1;
}
return 0;
}
/* Not Supported on 750Ti 340.23 */
int nvml_get_pstate(nvml_handle *nvmlh, int cudaindex, int *pstate)
{
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetPerformanceState)
return -ENOSYS;
nvmlReturn_t res = nvmlh->nvmlDeviceGetPerformanceState(nvmlh->devs[gpuindex], pstate);
if (res != NVML_SUCCESS) {
//if (opt_debug)
// applog(LOG_DEBUG, "nvmlDeviceGetPerformanceState: %s", nvmlh->nvmlErrorString(res));
return -1;
}
return 0;
}
int nvml_get_busid(nvml_handle *nvmlh, int cudaindex, int *busid)
{
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
(*busid) = nvmlh->nvml_pci_bus_id[gpuindex];
return 0;
}
int nvml_get_serial(nvml_handle *nvmlh, int cudaindex, char *sn, int maxlen)
{
uint32_t subids = 0;
char uuid[NVML_DEVICE_UUID_BUFFER_SIZE];
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
nvmlReturn_t res;
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (nvmlh->nvmlDeviceGetSerial) {
res = nvmlh->nvmlDeviceGetSerial(nvmlh->devs[gpuindex], sn, maxlen);
if (res == NVML_SUCCESS)
return 0;
}
if (!nvmlh->nvmlDeviceGetUUID)
return -ENOSYS;
// nvmlDeviceGetUUID: GPU-f2bd642c-369f-5a14-e0b4-0d22dfe9a1fc
// use a part of uuid to generate an unique serial
// todo: check if there is vendor id is inside
memset(uuid, 0, sizeof(uuid));
res = nvmlh->nvmlDeviceGetUUID(nvmlh->devs[gpuindex], uuid, sizeof(uuid)-1);
if (res != NVML_SUCCESS) {
if (opt_debug)
applog(LOG_DEBUG, "nvmlDeviceGetUUID: %s", nvmlh->nvmlErrorString(res));
return -1;
}
strncpy(sn, &uuid[4], min((int) strlen(uuid), maxlen));
sn[maxlen-1] = '\0';
return 0;
}
int nvml_get_bios(nvml_handle *nvmlh, int cudaindex, char *desc, int maxlen)
{
uint32_t subids = 0;
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
if (!nvmlh->nvmlDeviceGetVbiosVersion)
return -ENOSYS;
nvmlReturn_t res = nvmlh->nvmlDeviceGetVbiosVersion(nvmlh->devs[gpuindex], desc, maxlen);
if (res != NVML_SUCCESS) {
if (opt_debug)
applog(LOG_DEBUG, "nvmlDeviceGetVbiosVersion: %s", nvmlh->nvmlErrorString(res));
return -1;
}
return 0;
}
int nvml_get_info(nvml_handle *nvmlh, int cudaindex, uint16_t &vid, uint16_t &pid)
{
uint32_t subids = 0;
int gpuindex = nvmlh->cuda_nvml_device_id[cudaindex];
if (gpuindex < 0 || gpuindex >= nvmlh->nvml_gpucount)
return -ENODEV;
subids = nvmlh->nvml_pci_subsys_id[gpuindex];
if (!subids) subids = nvmlh->nvml_pci_device_id[gpuindex];
pid = subids >> 16;
vid = subids & 0xFFFF;
// Colorful and Inno3D
if (pid == 0) pid = nvmlh->nvml_pci_device_id[gpuindex] >> 16;
return 0;
}
int nvml_destroy(nvml_handle *nvmlh)
{
nvmlh->nvmlShutdown();
wrap_dlclose(nvmlh->nvml_dll);
free(nvmlh->nvml_pci_bus_id);
free(nvmlh->nvml_pci_device_id);
free(nvmlh->nvml_pci_domain_id);
free(nvmlh->nvml_pci_subsys_id);
free(nvmlh->nvml_cuda_device_id);
free(nvmlh->cuda_nvml_device_id);
free(nvmlh->app_clocks);
free(nvmlh->devs);
free(nvmlh);
return 0;
}
// ----------------------------------------------------------------------------
/**
* nvapi alternative for windows x86 binaries
* nvml api doesn't exists as 32bit dll :///
*/
#ifdef WIN32
#include "nvapi/nvapi_ccminer.h"
static unsigned int nvapi_dev_map[MAX_GPUS] = { 0 };
static NvDisplayHandle hDisplay_a[NVAPI_MAX_PHYSICAL_GPUS * 2] = { 0 };
static NvPhysicalGpuHandle phys[NVAPI_MAX_PHYSICAL_GPUS] = { 0 };
static NvU32 nvapi_dev_cnt = 0;
extern bool nvapi_dll_loaded;
int nvapi_temperature(unsigned int devNum, unsigned int *temperature)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
NV_GPU_THERMAL_SETTINGS thermal;
thermal.version = NV_GPU_THERMAL_SETTINGS_VER;
ret = NvAPI_GPU_GetThermalSettings(phys[devNum], 0, &thermal);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI NvAPI_GPU_GetThermalSettings: %s", string);
return -1;
}
(*temperature) = (unsigned int) thermal.sensor[0].currentTemp;
return 0;
}
int nvapi_fanspeed(unsigned int devNum, unsigned int *speed)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
NvU32 fanspeed = 0;
ret = NvAPI_GPU_GetTachReading(phys[devNum], &fanspeed);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI NvAPI_GPU_GetTachReading: %s", string);
return -1;
}
(*speed) = (unsigned int) fanspeed;
return 0;
}
int nvapi_getpstate(unsigned int devNum, unsigned int *pstate)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
NV_GPU_PERF_PSTATE_ID CurrentPstate = NVAPI_GPU_PERF_PSTATE_UNDEFINED; /* 16 */
ret = NvAPI_GPU_GetCurrentPstate(phys[devNum], &CurrentPstate);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI NvAPI_GPU_GetCurrentPstate: %s", string);
return -1;
}
else {
// get pstate for the moment... often 0 = P0
(*pstate) = (unsigned int)CurrentPstate;
}
return 0;
}
#define UTIL_DOMAIN_GPU 0
int nvapi_getusage(unsigned int devNum, unsigned int *pct)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
NV_GPU_DYNAMIC_PSTATES_INFO_EX info;
info.version = NV_GPU_DYNAMIC_PSTATES_INFO_EX_VER;
ret = NvAPI_GPU_GetDynamicPstatesInfoEx(phys[devNum], &info);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI GetDynamicPstatesInfoEx: %s", string);
return -1;
}
else {
if (info.utilization[UTIL_DOMAIN_GPU].bIsPresent)
(*pct) = info.utilization[UTIL_DOMAIN_GPU].percentage;
}
return 0;
}
int nvapi_getinfo(unsigned int devNum, uint16_t &vid, uint16_t &pid)
{
NvAPI_Status ret;
NvU32 pDeviceId, pSubSystemId, pRevisionId, pExtDeviceId;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
ret = NvAPI_GPU_GetPCIIdentifiers(phys[devNum], &pDeviceId, &pSubSystemId, &pRevisionId, &pExtDeviceId);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI GetPCIIdentifiers: %s", string);
return -1;
}
pid = pDeviceId >> 16;
vid = pDeviceId & 0xFFFF;
if (vid == 0x10DE && pSubSystemId) {
vid = pSubSystemId & 0xFFFF;
pid = pSubSystemId >> 16;
// Colorful and Inno3D
if (pid == 0) pid = pDeviceId >> 16;
}
return 0;
}
int nvapi_getserial(unsigned int devNum, char *serial, unsigned int maxlen)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
memset(serial, 0, maxlen);
if (maxlen < 11)
return -EINVAL;
NvAPI_ShortString ser = { 0 };
ret = NvAPI_DLL_GetSerialNumber(phys[devNum], ser);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI GetSerialNumber: %s", string);
return -1;
}
uint8_t *bytes = (uint8_t*) ser;
for (int n=0; n<5; n++) sprintf(&serial[n*2], "%02X", bytes[n]);
return 0;
}
int nvapi_getbios(unsigned int devNum, char *desc, unsigned int maxlen)
{
NvAPI_Status ret;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
if (maxlen < 64) // Short String
return -1;
ret = NvAPI_GPU_GetVbiosVersionString(phys[devNum], desc);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI GetVbiosVersionString: %s", string);
return -1;
}
return 0;
}
static int SetAsusRGBLogo(unsigned int devNum, uint32_t RGB, bool ignorePrevState)
{
NvAPI_Status ret = NVAPI_OK;
NV_I2C_INFO_EX* i2cInfo;
int delay1 = 20000;
int delay2 = 0;
uchar4 rgb = { 0 };
memcpy(&rgb, &RGB, 4);
uchar4 prgb = { 0 };
int32_t prev = device_led_state[nvapi_devid(devNum)];
memcpy(&prgb, &prev, 4);
NV_INIT_STRUCT_ALLOC(NV_I2C_INFO_EX, i2cInfo);
if (i2cInfo == NULL) return -ENOMEM;
NvU32 data[5] = { 0 };
NvU32 datv[2] = { 0, 1 };
NvU32 datw[2] = { 1, 0 };
if (rgb.z != prgb.z || ignorePrevState) {
data[2] = 4; // R:4 G:5 B:6, Mode = 7 (1 static, 2 breath, 3 blink, 4 demo)
data[3] = 1;
datv[0] = rgb.z | 0x13384000;
i2cInfo->i2cDevAddress = 0x52;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 1;
i2cInfo->pbData = (NvU8*) datv;
i2cInfo->cbRead = 5;
i2cInfo->cbSize = 1;
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
ret = NvAPI_DLL_I2CWriteEx(phys[devNum], i2cInfo, datw);
usleep(delay1);
has_rgb_ok = (ret == NVAPI_OK);
}
if (rgb.y != prgb.y || ignorePrevState) {
data[2] = 5;
data[3] = 1;
datv[0] = rgb.y | 0x4000;
i2cInfo->i2cDevAddress = 0x52;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 1;
i2cInfo->pbData = (NvU8*) datv;
i2cInfo->cbRead = 5;
i2cInfo->cbSize = 1;
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
ret = NvAPI_DLL_I2CWriteEx(phys[devNum], i2cInfo, datw);
usleep(delay1);
has_rgb_ok = (ret == NVAPI_OK);
}
if (rgb.y != prgb.y || ignorePrevState) {
data[2] = 6;
data[3] = 1;
datv[0] = rgb.x | 0x4000;
i2cInfo->i2cDevAddress = 0x52;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 1;
i2cInfo->pbData = (NvU8*) datv;
i2cInfo->cbRead = 5;
i2cInfo->cbSize = 1;
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
ret = NvAPI_DLL_I2CWriteEx(phys[devNum], i2cInfo, datw);
usleep(delay1);
has_rgb_ok = (ret == NVAPI_OK);
}
if (rgb.w && ignorePrevState) {
data[2] = 7;
data[3] = 1;
datv[0] = rgb.w | 0x4000;
i2cInfo->i2cDevAddress = 0x52;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 1;
i2cInfo->pbData = (NvU8*) datv;
i2cInfo->cbRead = 5;
i2cInfo->cbSize = 1;
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
ret = NvAPI_DLL_I2CWriteEx(phys[devNum], i2cInfo, datw);
usleep(delay1);
has_rgb_ok = (ret == NVAPI_OK);
}
usleep(delay2);
free(i2cInfo);
return (int) ret;
}
static int SetGigabyteRGBLogo(unsigned int devNum, uint32_t RGB)
{
NvAPI_Status ret;
NV_I2C_INFO_EX* i2cInfo;
NV_INIT_STRUCT_ALLOC(NV_I2C_INFO_EX, i2cInfo);
if (i2cInfo == NULL)
return -ENOMEM;
NvU32 readBuf[25] = { 0 };
NvU32 data[5] = { 0 };
data[0] = 1;
data[2] = swab32(RGB & 0xfcfcfcU) | 0x40;
i2cInfo->i2cDevAddress = 0x48 << 1;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 4; // NVAPI_MAX_SIZEOF_I2C_REG_ADDRESS
i2cInfo->pbData = (NvU8*) readBuf;
i2cInfo->cbRead = 2;
i2cInfo->cbSize = sizeof(readBuf);
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
//ret = NvAPI_DLL_I2CWriteEx(phys[devNum], i2cInfo, data);
ret = NvAPI_DLL_I2CReadEx(phys[devNum], i2cInfo, data);
usleep(20000);
free(i2cInfo);
return (int) ret;
}
static int SetZotacRGBLogo(unsigned int devNum, uint32_t RGB)
{
NvAPI_Status ret;
NV_I2C_INFO* i2cInfo;
NV_INIT_STRUCT_ALLOC(NV_I2C_INFO, i2cInfo);
if (i2cInfo == NULL)
return -ENOMEM;
NvU32 buf[25] = { 0 };
NvU32 data[5] = { 0 };
uint32_t color = 0, level = 0x40;
uchar4 rgb = { 0 };
memcpy(&rgb, &RGB, 4);
level = rgb.x & 0xF0;
level |= rgb.y & 0xF0;
level |= rgb.z & 0xF0;
//applog(LOG_DEBUG, "R %u G %u B %u", rgb.z, rgb.y, rgb.x);
// Not really RGB custom, only some basic colors, so convert
// 0: Red, 1: Yellow, 2: Green, 3: Cyan, 4: Blue, 5: magenta, 6: white
if ((RGB & 0xFF0000) && (RGB & 0xFF00) && (RGB & 0xFF)) color = 6;
else if ((RGB & 0xFF0000) && (RGB & 0xFF)) color = 5;
else if ((RGB & 0xFF00) && (RGB & 0xFF)) color = 3;
else if ((RGB & 0xFF0000) && (RGB & 0xFF00)) color = 1;
else if (RGB & 0xFF) color = 4;
else if (RGB & 0xFF00) color = 2;
buf[0] = 0xF0; // F0 set colors
buf[0] |= (color << 8); // logo
buf[0] |= (1 << 16); // top
if (RGB != 0) // level : 0x10 to 0xF0
buf[0] |= (level << 24);
else
buf[0] |= (0x10U << 24);
// todo: i2c data crc ?
i2cInfo->displayMask = 1;
i2cInfo->bIsDDCPort = 1;
i2cInfo->i2cDevAddress = 0x48 << 1;
i2cInfo->pbI2cRegAddress = (NvU8*) (&data[2]);
i2cInfo->regAddrSize = 1;
i2cInfo->pbData = (NvU8*) buf;
i2cInfo->cbSize = 4;
i2cInfo->i2cSpeed = NVAPI_I2C_SPEED_DEPRECATED;
i2cInfo->i2cSpeedKhz = NVAPI_I2C_SPEED_100KHZ; // 4
i2cInfo->portId = 1;
i2cInfo->bIsPortIdSet = 1;
ret = NvAPI_I2CWrite(phys[devNum], i2cInfo);
// required to prevent i2c lock
usleep(20000);
#if 0
buf[0] = 0xF7; // F7 toggle leds
if (RGB == 0)
buf[0] |= (1 << 8); // 0 logo on, 1 off
buf[0] |= (1 << 16); // 1 top off
ret = NvAPI_I2CWrite(phys[devNum], i2cInfo);
usleep(20000);
#endif
// other modes:
// 0xF1 breathing green (0x070202F1)
// 0xF2 strobe green (0x070202F2)
// 0xF3 cycle (0x000000F3)
free(i2cInfo);
return (int) ret;
}
int nvapi_set_led(unsigned int devNum, int RGB, char *device_name)
{
uint16_t vid = 0, pid = 0;
NvAPI_Status ret;
if (strstr(device_name, "Gigabyte GTX 10")) {
if (opt_debug)
applog(LOG_DEBUG, "GPU %x: Set RGB led to %06x", (int) phys[devNum], RGB);
return SetGigabyteRGBLogo(devNum, (uint32_t) RGB);
} else if (strstr(device_name, "ASUS GTX 10")) {
if (opt_debug)
applog(LOG_DEBUG, "GPU %x: Set RGB led to %06x", (int) phys[devNum], RGB);
return SetAsusRGBLogo(devNum, (uint32_t) RGB, !has_rgb_ok);
} else if (strstr(device_name, "Zotac GTX 10")) {
if (opt_debug)
applog(LOG_DEBUG, "GPU %x: Set RGB led to %06x", (int) phys[devNum], RGB);
return SetZotacRGBLogo(devNum, (uint32_t) RGB);
} else {
NV_GPU_QUERY_ILLUMINATION_SUPPORT_PARM* illu;
NV_INIT_STRUCT_ALLOC(NV_GPU_QUERY_ILLUMINATION_SUPPORT_PARM, illu);
illu->hPhysicalGpu = phys[devNum];
illu->Attribute = NV_GPU_IA_LOGO_BRIGHTNESS;
ret = NvAPI_GPU_QueryIlluminationSupport(illu);
if (!ret && illu->bSupported) {
NV_GPU_GET_ILLUMINATION_PARM *led;
NV_INIT_STRUCT_ALLOC(NV_GPU_GET_ILLUMINATION_PARM, led);
led->hPhysicalGpu = phys[devNum];
led->Attribute = NV_GPU_IA_LOGO_BRIGHTNESS;
NvAPI_GPU_GetIllumination(led);
if (opt_debug)
applog(LOG_DEBUG, "GPU %x: Led level was %d, set to %d", (int) phys[devNum], led->Value, RGB);
led->Value = (uint32_t) RGB;
ret = NvAPI_GPU_SetIllumination((NV_GPU_SET_ILLUMINATION_PARM*) led);
free(led);
}
free(illu);
return ret;
}
}
int nvapi_pstateinfo(unsigned int devNum)
{
uint32_t n;
NvAPI_Status ret;
uint32_t* mem = (uint32_t*) calloc(1, 0x4000);
if (!mem)
return -ENOMEM;
unsigned int current = 0xFF;
// useless on init but...
nvapi_getpstate(devNum, &current);
#if 0
// try :p
uint32_t* buf = (uint32_t*) calloc(1, 0x8000);
for (int i=8; i < 0x8000 && buf; i+=4) {
buf[0] = 0x10000 + i;
NV_GPU_PERF_PSTATE_ID pst = NVAPI_GPU_PERF_PSTATE_P0;
ret = NvAPI_DLL_GetPstateClientLimits(phys[devNum], pst, buf);
if (ret != NVAPI_INCOMPATIBLE_STRUCT_VERSION) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
applog(LOG_BLUE, "struct size is %06x : %s", buf[0], string);
for (int n=0; n < i/32; n++)
applog_hex(&buf[n*(32/4)], 32);
break;
}
}
free(buf);
#endif
#if 0
// Unsure of the meaning of these values
NVAPI_GPU_POWER_TOPO topo = { 0 };
topo.version = NVAPI_GPU_POWER_TOPO_VER;
if ((ret = NvAPI_DLL_ClientPowerTopologyGetStatus(phys[devNum], &topo)) == NVAPI_OK) {
if (topo.count)
applog(LOG_RAW, " GPU TDP is %.1f~%.1f W ?",
(double) topo.entries[0].power/1000, (double) topo.entries[1].power/1000);
// Ok on 970, not pascal
NV_GPU_PERF_PSTATES20_INFO_V2 pset2 = { 0 };
pset2.version = NV_GPU_PERF_PSTATES20_INFO_VER2;
pset2.ov.numVoltages = 1;
pset2.ov.voltages[0].voltDelta_uV.value = 3000; // gpu + 3000 uv;
ret = NvAPI_DLL_SetPstates20v2(phys[devNum], &pset2);
#endif
NV_GPU_PERF_PSTATES20_INFO* info;
NV_INIT_STRUCT_ON(NV_GPU_PERF_PSTATES20_INFO, info, mem);
if ((ret = NvAPI_GPU_GetPstates20(phys[devNum], info)) != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_RAW, "NVAPI GetPstates20: %s", string);
return -1;
}
for (n=0; n < info->numPstates; n++) {
NV_GPU_PSTATE20_CLOCK_ENTRY_V1* clocks = info->pstates[n].clocks;
applog(LOG_RAW, "%sP%d: MEM %4u MHz%s GPU %6.1f MHz%s %4u mV%s \x7F %d/%d",
info->pstates[n].pstateId == current ? ">":" ", (int) info->pstates[n].pstateId,
clocks[1].data.single.freq_kHz/1000, clocks[1].bIsEditable ? "*":" ",
(double) clocks[0].data.single.freq_kHz/1000, clocks[0].bIsEditable ? "*":" ",
info->pstates[n].baseVoltages[0].volt_uV/1000, info->pstates[n].baseVoltages[0].bIsEditable ? "*": " ",
info->pstates[n].baseVoltages[0].voltDelta_uV.valueRange.min/1000, // range if editable
info->pstates[n].baseVoltages[0].voltDelta_uV.valueRange.max/1000);
if (clocks[1].freqDelta_kHz.value || clocks[0].freqDelta_kHz.value) {
applog(LOG_RAW, " OC %+4d MHz %+6.1f MHz",
clocks[1].freqDelta_kHz.value/1000, (double) clocks[0].freqDelta_kHz.value/1000);
}
}
// boost over volting (GTX 9xx only ?)
for (n=0; n < info->ov.numVoltages; n++) {
applog(LOG_RAW, " OV: %u%+d mV%s \x7F %d/%d",
info->ov.voltages[n].volt_uV/1000, info->ov.voltages[n].voltDelta_uV.value/1000, info->ov.voltages[n].bIsEditable ? "*":" ",
info->ov.voltages[n].voltDelta_uV.valueRange.min/1000, info->ov.voltages[n].voltDelta_uV.valueRange.max/1000);
}
NV_GPU_CLOCK_FREQUENCIES *freqs;
NV_INIT_STRUCT_ON(NV_GPU_CLOCK_FREQUENCIES, freqs, mem);
freqs->ClockType = NV_GPU_CLOCK_FREQUENCIES_BASE_CLOCK;
ret = NvAPI_GPU_GetAllClockFrequencies(phys[devNum], freqs);
applog(LOG_RAW, " MEM %4.0f MHz GPU %6.1f MHz Base Clocks",
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_MEMORY].frequency / 1000,
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS].frequency / 1000);
freqs->ClockType = NV_GPU_CLOCK_FREQUENCIES_BOOST_CLOCK;
ret = NvAPI_GPU_GetAllClockFrequencies(phys[devNum], freqs);
applog(LOG_RAW, " MEM %4.0f MHz GPU %6.1f MHz Boost Clocks",
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_MEMORY].frequency / 1000,
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS].frequency / 1000);
freqs->ClockType = NV_GPU_CLOCK_FREQUENCIES_CURRENT_FREQ;
ret = NvAPI_GPU_GetAllClockFrequencies(phys[devNum], freqs);
applog(LOG_RAW, " MEM %4.0f MHz GPU %6.1f MHz >Current",
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_MEMORY].frequency / 1000,
(double) freqs->domain[NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS].frequency / 1000);
// Other clock values ??
NVAPI_GPU_PERF_CLOCKS *pcl;
NV_INIT_STRUCT_ALLOC(NVAPI_GPU_PERF_CLOCKS, pcl);
int numClock=0; ret = NVAPI_OK;
while (ret == NVAPI_OK) {
if ((ret = NvAPI_DLL_GetPerfClocks(phys[devNum], numClock, pcl)) == NVAPI_OK) {
applog(LOG_RAW, " C%d: MEM %4.0f MHz GPU %6.1f MHz [%5.1f/%6.1f]", numClock,
(double) pcl->memFreq1/1000, (double) pcl->gpuFreq1/1000, (double) pcl->gpuFreqMin/1000, (double) pcl->gpuFreqMax/1000);
// ret = NvAPI_DLL_SetPerfClocks(phys[devNum], numClock, pcl); // error
}
numClock++;
}
// Pascal only
NVAPI_VOLTBOOST_PERCENT *pvb;
NV_INIT_STRUCT_ON(NVAPI_VOLTBOOST_PERCENT, pvb, mem);
if ((ret = NvAPI_DLL_GetCoreVoltageBoostPercent(phys[devNum], pvb)) == NVAPI_OK) {
NVAPI_VOLTAGE_STATUS *pvdom;
NV_INIT_STRUCT_ALLOC(NVAPI_VOLTAGE_STATUS, pvdom);
NvAPI_DLL_GetCurrentVoltage(phys[devNum], pvdom);
if (pvdom && pvdom->value_uV)
applog(LOG_RAW, " GPU Voltage is %u mV %+d%% boost", pvdom->value_uV/1000, pvb->percent);
else if (pvdom)
applog(LOG_RAW, " GPU Voltage is %u mV", pvdom->value_uV/1000);
free(pvdom);
} else {
// Maxwell 9xx
NVAPI_VOLT_STATUS *mvdom, *mvstep;
NV_INIT_STRUCT_ALLOC(NVAPI_VOLT_STATUS, mvdom);
if (mvdom && (ret = NvAPI_DLL_GetVoltageDomainsStatus(phys[devNum], mvdom)) == NVAPI_OK) {
NV_INIT_STRUCT_ALLOC(NVAPI_VOLT_STATUS, mvstep);
NvAPI_DLL_GetVoltageStep(phys[devNum], mvstep);
if (mvdom->value_uV) applog(LOG_RAW, " GPU Voltage is %.1f mV with %.3f mV resolution",
(double) mvdom->value_uV/1000, (double) mvstep->value_uV/1000);
free(mvstep);
}
free(mvdom);
}
uint32_t plim = nvapi_get_plimit(devNum);
applog(LOG_RAW, " Power limit is set to %u%%", plim);
#if 0
NVAPI_COOLER_SETTINGS *cooler;
NV_INIT_STRUCT_ON(NVAPI_COOLER_SETTINGS, cooler, mem);
ret = NvAPI_DLL_GetCoolerSettings(phys[devNum], 7, cooler);
if (ret == NVAPI_OK) {
applog(LOG_RAW, " Fan level is set to %u%%", cooler->level); // wrong val, seems 1 (auto ?)
NVAPI_COOLER_LEVEL *fan;
NV_INIT_STRUCT_ALLOC(NVAPI_COOLER_LEVEL, fan);
fan->level = 100;
fan->count = 1;
ret = NvAPI_DLL_SetCoolerLevels(phys[devNum], 7, fan);
free(fan);
sleep(10);
ret = NvAPI_DLL_RestoreCoolerSettings(phys[devNum], cooler, 7);
}
#endif
NV_GPU_THERMAL_SETTINGS *tset;
NV_INIT_STRUCT_ON(NV_GPU_THERMAL_SETTINGS, tset, mem);
NVAPI_GPU_THERMAL_INFO *tnfo;
NV_INIT_STRUCT_ALLOC(NVAPI_GPU_THERMAL_INFO, tnfo);
NVAPI_GPU_THERMAL_LIMIT *tlim;
NV_INIT_STRUCT_ALLOC(NVAPI_GPU_THERMAL_LIMIT, tlim);
NvAPI_GPU_GetThermalSettings(phys[devNum], 0, tset);
NvAPI_DLL_ClientThermalPoliciesGetInfo(phys[devNum], tnfo);
if ((ret = NvAPI_DLL_ClientThermalPoliciesGetLimit(phys[devNum], tlim)) == NVAPI_OK) {
applog(LOG_RAW, " Thermal limit is set to %u, current Tc %d, range [%u-%u]",
tlim->entries[0].value >> 8, tset->sensor[0].currentTemp,
tnfo->entries[0].min_temp >> 8, tnfo->entries[0].max_temp >> 8);
}
free(tnfo);
free(tlim);
#if 1
// Read pascal Clocks Table, Empty on 9xx
//NVAPI_CLOCKS_RANGE* ranges;
//NV_INIT_STRUCT_ON(NVAPI_CLOCKS_RANGE, ranges, mem);
//ret = NvAPI_DLL_GetClockBoostRanges(phys[devNum], ranges);
NVAPI_CLOCK_MASKS* boost;
NV_INIT_STRUCT_ON(NVAPI_CLOCK_MASKS, boost, mem);
ret = NvAPI_DLL_GetClockBoostMask(phys[devNum], boost);
int gpuClocks = 0, memClocks = 0;
for (n=0; n < 80+23; n++) {
if (boost->clocks[n].memDelta) memClocks++;
if (boost->clocks[n].gpuDelta) gpuClocks++;
}
// PASCAL GTX ONLY
if (gpuClocks || memClocks) {
NVAPI_CLOCK_TABLE *table;
NV_INIT_STRUCT_ALLOC(NVAPI_CLOCK_TABLE, table);
memcpy(table->mask, boost->mask, 12);
ret = NvAPI_DLL_GetClockBoostTable(phys[devNum], table);
gpuClocks = 0, memClocks = 0;
for (n=0; n < 12; n++) {
if (table->buf0[n] != 0) applog(LOG_RAW, "boost table 0[%u] not empty (%u)", n, table->buf0[n]);
}
for (n=0; n < 80; n++) {
if (table->gpuDeltas[n].freqDelta) {
// note: gpu delta value seems to be x2, not the memory
//applog(LOG_RAW, " Boost gpu clock delta %u set to %d MHz", n, table->gpuDeltas[n].freqDelta/2000);
gpuClocks++;
}
}
for (n=0; n < 23; n++) {
if (table->memFilled[n]) {
//applog(LOG_RAW, " Boost mem clock delta %u set to %d MHz", n, table->memDeltas[n]/1000);
memClocks++;
}
}
for (n=0; n < 1529; n++) {
if (table->buf1[n] != 0) applog(LOG_RAW, "boost table 1[%u] not empty (%u)", n, table->buf1[n]);
}
applog(LOG_RAW, " Boost table contains %d gpu and %d mem levels.", gpuClocks, memClocks);
free(table);
NVAPI_VFP_CURVE *curve;
NV_INIT_STRUCT_ALLOC(NVAPI_VFP_CURVE, curve);
memcpy(curve->mask, boost->mask, 12);
ret = NvAPI_DLL_GetVFPCurve(phys[devNum], curve);
gpuClocks = 0, memClocks = 0;
for (n=0; n < 80; n++) {
if (curve->gpuEntries[n].freq_kHz || curve->gpuEntries[n].volt_uV) {
// applog(LOG_RAW, "gpu volt table %2u %4u MHz - %6u mV", n, curve->gpuEntries[n].freq_kHz/1000, curve->gpuEntries[n].volt_uV/1000);
gpuClocks++;
}
}
for (n=0; n < 23; n++) {
if (curve->memEntries[n].freq_kHz || curve->memEntries[n].volt_uV) {
// applog(LOG_RAW, "mem volt table %2u %4u MHz - %6u mV", n, curve->memEntries[n].freq_kHz/1000, curve->memEntries[n].volt_uV/1000);
memClocks++;
}
}
for (n=0; n < 1064; n++) {
if (curve->buf1[n] != 0) applog(LOG_RAW, "volt table buf1[%u] not empty (%u)", n, curve->buf1[n]);
}
applog(LOG_RAW, " Volts table contains %d gpu and %d mem levels.", gpuClocks, memClocks);
free(curve);
}
// Maxwell
else {
NVAPI_VOLTAGES_TABLE* volts;
NV_INIT_STRUCT_ALLOC(NVAPI_VOLTAGES_TABLE, volts);
int entries = 0;
ret = NvAPI_DLL_GetVoltages(phys[devNum], volts);
for (n=0; n < 128; n++) {
if (volts->entries[n].volt_uV)
entries++;
}
applog(LOG_RAW, " Volts table contains %d gpu levels.", entries);
free(volts);
}
NV_DISPLAY_DRIVER_MEMORY_INFO* meminfo;
NV_INIT_STRUCT_ON(NV_DISPLAY_DRIVER_MEMORY_INFO, meminfo, mem);
meminfo->version = NV_DISPLAY_DRIVER_MEMORY_INFO_VER;
if ((ret = NvAPI_GPU_GetMemoryInfo(phys[devNum], meminfo)) == NVAPI_OK) {
applog(LOG_RAW, " Memory: %u MB, %.1f used", meminfo->dedicatedVideoMemory/1024,
(double) (meminfo->availableDedicatedVideoMemory - meminfo->curAvailableDedicatedVideoMemory)/1024);
}
#if 0 /* some undetermined stats */
NVAPI_GPU_PERF_INFO pi = { 0 };
pi.version = NVAPI_GPU_PERF_INFO_VER;
ret = NvAPI_DLL_PerfPoliciesGetInfo(phys[devNum], &pi);
NVAPI_GPU_PERF_STATUS ps = { 0 };
ps.version = NVAPI_GPU_PERF_STATUS_VER;
ret = NvAPI_DLL_PerfPoliciesGetStatus(phys[devNum], &ps);
applog(LOG_BLUE, "%llx %lld. %lld. %llx %llx %llx", ps.timeRef, ps.val1, ps.val2, ps.values[0], ps.values[1], ps.values[2]);
#endif
#endif
free(mem);
return 0;
}
uint8_t nvapi_get_plimit(unsigned int devNum)
{
NvAPI_Status ret = NVAPI_OK;
NVAPI_GPU_POWER_STATUS pol = { 0 };
pol.version = NVAPI_GPU_POWER_STATUS_VER;
if ((ret = NvAPI_DLL_ClientPowerPoliciesGetStatus(phys[devNum], &pol)) != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI PowerPoliciesGetStatus: %s", string);
return 0;
}
return (uint8_t) (pol.entries[0].power / 1000); // in percent
}
int nvapi_set_plimit(unsigned int devNum, uint16_t percent)
{
NvAPI_Status ret = NVAPI_OK;
uint32_t val = percent * 1000;
NVAPI_GPU_POWER_INFO nfo = { 0 };
nfo.version = NVAPI_GPU_POWER_INFO_VER;
ret = NvAPI_DLL_ClientPowerPoliciesGetInfo(phys[devNum], &nfo);
if (ret == NVAPI_OK) {
if (val == 0)
val = nfo.entries[0].def_power;
else if (val < nfo.entries[0].min_power)
val = nfo.entries[0].min_power;
else if (val > nfo.entries[0].max_power)
val = nfo.entries[0].max_power;
}
NVAPI_GPU_POWER_STATUS pol = { 0 };
pol.version = NVAPI_GPU_POWER_STATUS_VER;
pol.flags = 1;
pol.entries[0].power = val;
if ((ret = NvAPI_DLL_ClientPowerPoliciesSetStatus(phys[devNum], &pol)) != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI PowerPoliciesSetStatus: %s", string);
return -1;
}
return ret;
}
int nvapi_set_tlimit(unsigned int devNum, uint8_t limit)
{
NvAPI_Status ret;
uint32_t val = limit;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
NV_GPU_THERMAL_SETTINGS tset = { 0 };
NVAPI_GPU_THERMAL_INFO tnfo = { 0 };
NVAPI_GPU_THERMAL_LIMIT tlim = { 0 };
tset.version = NV_GPU_THERMAL_SETTINGS_VER;
NvAPI_GPU_GetThermalSettings(phys[devNum], 0, &tset);
tnfo.version = NVAPI_GPU_THERMAL_INFO_VER;
NvAPI_DLL_ClientThermalPoliciesGetInfo(phys[devNum], &tnfo);
tlim.version = NVAPI_GPU_THERMAL_LIMIT_VER;
if ((ret = NvAPI_DLL_ClientThermalPoliciesGetLimit(phys[devNum], &tlim)) == NVAPI_OK) {
tlim.entries[0].value = val << 8;
tlim.flags = 1;
ret = NvAPI_DLL_ClientThermalPoliciesSetLimit(phys[devNum], &tlim);
if (ret == NVAPI_OK) {
applog(LOG_INFO, "GPU #%u: thermal limit set to %u, current Tc %d, range [%u-%u]",
devNum, val, tset.sensor[0].currentTemp,
tnfo.entries[0].min_temp >> 8, tnfo.entries[0].max_temp >> 8);
} else {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
applog(LOG_WARNING, "GPU #%u: thermal limit: %s, valid range is [%u-%u]", devNum, string,
tnfo.entries[0].min_temp >> 8, tnfo.entries[0].max_temp >> 8);
}
}
return (int) ret;
}
int nvapi_set_gpuclock(unsigned int devNum, uint32_t clock)
{
NvAPI_Status ret;
NvS32 delta = 0;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
#if 0
// wrong api to get default base clock when modified, cuda props seems fine
NV_GPU_CLOCK_FREQUENCIES freqs = { 0 };
freqs.version = NV_GPU_CLOCK_FREQUENCIES_VER;
freqs.ClockType = NV_GPU_CLOCK_FREQUENCIES_BASE_CLOCK;
ret = NvAPI_GPU_GetAllClockFrequencies(phys[devNum], &freqs);
if (ret == NVAPI_OK) {
delta = (clock * 1000) - freqs.domain[NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS].frequency;
}
NV_GPU_PERF_PSTATES_INFO deffreqs = { 0 };
deffreqs.version = NV_GPU_PERF_PSTATES_INFO_VER;
ret = NvAPI_GPU_GetPstatesInfoEx(phys[devNum], &deffreqs, 0); // we want default clock grr!
if (ret == NVAPI_OK) {
if (deffreqs.pstates[0].clocks[1].domainId == NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS)
delta = (clock * 1000) - deffreqs.pstates[0].clocks[1].freq*2;
}
#endif
cudaDeviceProp props = { 0 };
NvU32 busId = 0xFFFF;
ret = NvAPI_GPU_GetBusId(phys[devNum], &busId);
for (int d=0; d < (int) nvapi_dev_cnt; d++) {
// unsure about devNum, so be safe
cudaGetDeviceProperties(&props, d);
if (props.pciBusID == busId) {
delta = (clock * 1000) - props.clockRate;
break;
}
}
if (delta == (clock * 1000))
return ret;
NV_GPU_PERF_PSTATES20_INFO_V1 pset1 = { 0 };
pset1.version = NV_GPU_PERF_PSTATES20_INFO_VER1;
pset1.numPstates = 1;
pset1.numClocks = 1;
// Ok on both 1080 and 970
pset1.pstates[0].clocks[0].domainId = NVAPI_GPU_PUBLIC_CLOCK_GRAPHICS;
pset1.pstates[0].clocks[0].freqDelta_kHz.value = delta;
ret = NvAPI_DLL_SetPstates20v1(phys[devNum], &pset1);
if (ret == NVAPI_OK) {
applog(LOG_INFO, "GPU #%u: boost gpu clock set to %u (delta %d)", devNum, clock, delta/1000);
}
return ret;
}
int nvapi_set_memclock(unsigned int devNum, uint32_t clock)
{
NvAPI_Status ret;
NvS32 delta = 0;
if (devNum >= nvapi_dev_cnt)
return -ENODEV;
// wrong to get default base clock (when modified) on maxwell (same as cuda props one)
NV_GPU_CLOCK_FREQUENCIES freqs = { 0 };
freqs.version = NV_GPU_CLOCK_FREQUENCIES_VER;
freqs.ClockType = NV_GPU_CLOCK_FREQUENCIES_BASE_CLOCK;
ret = NvAPI_GPU_GetAllClockFrequencies(phys[devNum], &freqs); // wrong base clocks, useless
if (ret == NVAPI_OK) {
delta = (clock * 1000) - freqs.domain[NVAPI_GPU_PUBLIC_CLOCK_MEMORY].frequency;
}
// seems ok on maxwell and pascal for the mem clocks
NV_GPU_PERF_PSTATES_INFO deffreqs = { 0 };
deffreqs.version = NV_GPU_PERF_PSTATES_INFO_VER;
ret = NvAPI_GPU_GetPstatesInfoEx(phys[devNum], &deffreqs, 0x1); // deprecated but req for def clocks
if (ret == NVAPI_OK) {
if (deffreqs.pstates[0].clocks[0].domainId == NVAPI_GPU_PUBLIC_CLOCK_MEMORY)
delta = (clock * 1000) - deffreqs.pstates[0].clocks[0].freq;
}
if (delta == (clock * 1000))
return ret;
// todo: bounds check with GetPstates20
NV_GPU_PERF_PSTATES20_INFO_V1 pset1 = { 0 };
pset1.version = NV_GPU_PERF_PSTATES20_INFO_VER1;
pset1.numPstates = 1;
pset1.numClocks = 1;
pset1.pstates[0].clocks[0].domainId = NVAPI_GPU_PUBLIC_CLOCK_MEMORY;
pset1.pstates[0].clocks[0].freqDelta_kHz.value = delta;
ret = NvAPI_DLL_SetPstates20v1(phys[devNum], &pset1);
if (ret == NVAPI_OK) {
applog(LOG_INFO, "GPU #%u: Boost mem clock set to %u (delta %d)", devNum, clock, delta/1000);
}
return ret;
}
// Replacement for WIN32 CUDA 6.5 on pascal
int nvapiMemGetInfo(int dev_id, uint64_t *free, uint64_t *total)
{
NvAPI_Status ret = NVAPI_OK;
NV_DISPLAY_DRIVER_MEMORY_INFO mem = { 0 };
mem.version = NV_DISPLAY_DRIVER_MEMORY_INFO_VER;
unsigned int devNum = nvapi_dev_map[dev_id % MAX_GPUS];
if ((ret = NvAPI_GPU_GetMemoryInfo(phys[devNum], &mem)) == NVAPI_OK) {
*total = (uint64_t) mem.dedicatedVideoMemory;// mem.availableDedicatedVideoMemory;
*free = (uint64_t) mem.curAvailableDedicatedVideoMemory;
}
return (int) ret;
}
int nvapi_init()
{
int num_gpus = cuda_num_devices();
NvAPI_Status ret = NvAPI_Initialize();
if (!ret == NVAPI_OK){
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI NvAPI_Initialize: %s", string);
return -1;
}
ret = NvAPI_EnumPhysicalGPUs(phys, &nvapi_dev_cnt);
if (ret != NVAPI_OK) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
if (opt_debug)
applog(LOG_DEBUG, "NVAPI NvAPI_EnumPhysicalGPUs: %s", string);
return -1;
}
for (int g = 0; g < num_gpus; g++) {
cudaDeviceProp props;
if (cudaGetDeviceProperties(&props, g) == cudaSuccess) {
device_bus_ids[g] = props.pciBusID;
}
nvapi_dev_map[g] = g; // default mapping
}
for (NvU8 i = 0; i < nvapi_dev_cnt; i++) {
NvAPI_ShortString name;
ret = NvAPI_GPU_GetFullName(phys[i], name);
if (ret == NVAPI_OK) {
for (int g = 0; g < num_gpus; g++) {
NvU32 busId;
ret = NvAPI_GPU_GetBusId(phys[i], &busId);
if (ret == NVAPI_OK && busId == device_bus_ids[g]) {
nvapi_dev_map[g] = i;
if (opt_debug)
applog(LOG_DEBUG, "CUDA GPU %d matches NVAPI GPU %d by busId %u",
g, i, busId);
break;
}
}
} else {
NvAPI_ShortString string;
NvAPI_GetErrorMessage(ret, string);
applog(LOG_DEBUG, "NVAPI NvAPI_GPU_GetFullName: %s", string);
}
}
#if 0
if (opt_debug) {
NvAPI_ShortString ver;
NvAPI_GetInterfaceVersionString(ver);
applog(LOG_DEBUG, "%s", ver);
}
#endif
NvU32 udv;
NvAPI_ShortString str;
ret = NvAPI_SYS_GetDriverAndBranchVersion(&udv, str);
if (ret == NVAPI_OK) {
sprintf(driver_version,"%d.%02d", udv / 100, udv % 100);
}
return 0;
}
int nvapi_init_settings()
{
// nvapi.dll
int ret = nvapi_dll_init();
if (ret != NVAPI_OK)
return ret;
if (!opt_n_threads) {
opt_n_threads = active_gpus;
}
for (int n=0; n < opt_n_threads; n++) {
int dev_id = device_map[n % MAX_GPUS];
if (device_plimit[dev_id]) {
if (nvapi_set_plimit(nvapi_dev_map[dev_id], device_plimit[dev_id]) == NVAPI_OK) {
uint32_t res = nvapi_get_plimit(nvapi_dev_map[dev_id]);
gpulog(LOG_INFO, n, "Power limit is set to %u%%", res);
}
}
if (device_tlimit[dev_id]) {
nvapi_set_tlimit(nvapi_dev_map[dev_id], device_tlimit[dev_id]);
}
if (device_gpu_clocks[dev_id]) {
ret = nvapi_set_gpuclock(nvapi_dev_map[dev_id], device_gpu_clocks[dev_id]);
if (ret) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage((NvAPI_Status) ret, string);
gpulog(LOG_WARNING, n, "Boost gpu clock %s", string);
}
}
if (device_mem_clocks[dev_id]) {
ret = nvapi_set_memclock(nvapi_dev_map[dev_id], device_mem_clocks[dev_id]);
if (ret) {
NvAPI_ShortString string;
NvAPI_GetErrorMessage((NvAPI_Status) ret, string);
gpulog(LOG_WARNING, n, "Boost mem clock %s", string);
}
}
if (device_pstate[dev_id]) {
// dunno how via nvapi or/and pascal
}
if (device_led[dev_id] != -1) {
int err = nvapi_set_led(nvapi_dev_map[dev_id], device_led[dev_id], device_name[dev_id]);
if (err != 0) {
gpulog(LOG_WARNING, n, "Unable to set led value (err %d)", err);
}
device_led_state[dev_id] = device_led[dev_id];
}
}
return ret;
}
unsigned int nvapi_devnum(int dev_id)
{
return nvapi_dev_map[dev_id];
}
int nvapi_devid(unsigned int devNum)
{
for (int i=0; i < opt_n_threads; i++) {
int dev_id = device_map[i % MAX_GPUS];
if (nvapi_dev_map[dev_id] = devNum)
return dev_id;
}
return 0;
}
#endif /* WIN32 : Windows specific (nvapi) */
/* api functions -------------------------------------- */
// assume 2500 rpm as default, auto-updated if more
static unsigned int fan_speed_max = 2500;
unsigned int gpu_fanpercent(struct cgpu_info *gpu)
{
unsigned int pct = 0;
if (hnvml) {
nvml_get_fanpcnt(hnvml, gpu->gpu_id, &pct);
}
#ifdef WIN32
else {
unsigned int rpm = 0;
nvapi_fanspeed(nvapi_dev_map[gpu->gpu_id], &rpm);
pct = (rpm * 100) / fan_speed_max;
if (pct > 100) {
pct = 100;
fan_speed_max = rpm;
}
}
#endif
return pct;
}
unsigned int gpu_fanrpm(struct cgpu_info *gpu)
{
unsigned int rpm = 0;
#ifdef WIN32
nvapi_fanspeed(nvapi_dev_map[gpu->gpu_id], &rpm);
#endif
return rpm;
}
float gpu_temp(struct cgpu_info *gpu)
{
float tc = 0.0;
unsigned int tmp = 0;
if (hnvml) {
nvml_get_tempC(hnvml, gpu->gpu_id, &tmp);
tc = (float)tmp;
}
#ifdef WIN32
else {
nvapi_temperature(nvapi_dev_map[gpu->gpu_id], &tmp);
tc = (float)tmp;
}
#endif
return tc;
}
int gpu_pstate(struct cgpu_info *gpu)
{
int pstate = -1;
int support = -1;
if (hnvml) {
support = nvml_get_pstate(hnvml, gpu->gpu_id, &pstate);
}
#ifdef WIN32
if (support == -1) {
unsigned int pst = 0;
nvapi_getpstate(nvapi_dev_map[gpu->gpu_id], &pst);
pstate = (int) pst;
}
#endif
return pstate;
}
int gpu_busid(struct cgpu_info *gpu)
{
int busid = -1;
int support = -1;
if (hnvml) {
support = nvml_get_busid(hnvml, gpu->gpu_id, &busid);
}
#ifdef WIN32
if (support == -1) {
busid = device_bus_ids[gpu->gpu_id];
}
#endif
return busid;
}
unsigned int gpu_power(struct cgpu_info *gpu)
{
unsigned int mw = 0;
int support = -1;
if (hnvml) {
support = nvml_get_power_usage(hnvml, gpu->gpu_id, &mw);
}
#ifdef WIN32
if (support == -1) {
unsigned int pct = 0;
nvapi_getusage(nvapi_dev_map[gpu->gpu_id], &pct);
pct *= nvapi_get_plimit(nvapi_dev_map[gpu->gpu_id]);
pct /= 100;
mw = pct; // to fix
}
#endif
if (gpu->gpu_power > 0) {
// average
mw = (gpu->gpu_power + mw) / 2;
}
return mw;
}
static int translate_vendor_id(uint16_t vid, char *vendorname)
{
struct VENDORS {
const uint16_t vid;
const char *name;
} vendors[] = {
{ 0x1043, "ASUS" },
{ 0x1048, "Elsa" },
{ 0x107D, "Leadtek" },
{ 0x10B0, "Gainward" },
// { 0x10DE, "NVIDIA" },
{ 0x1458, "Gigabyte" },
{ 0x1462, "MSI" },
{ 0x154B, "PNY" }, // maybe storage devices
{ 0x1569, "Palit" },
{ 0x1682, "XFX" },
{ 0x196D, "Club3D" },
{ 0x196E, "PNY" },
{ 0x19DA, "Zotac" },
{ 0x19F1, "BFG" },
{ 0x1ACC, "PoV" },
{ 0x1B4C, "Galax" }, // KFA2 in EU, to check on Pascal cards
{ 0x3842, "EVGA" },
{ 0x7377, "Colorful" },
{ 0, "" }
};
if (!vendorname)
return -EINVAL;
for(int v=0; v < ARRAY_SIZE(vendors); v++) {
if (vid == vendors[v].vid) {
strcpy(vendorname, vendors[v].name);
return vid;
}
}
if (opt_debug && vid != 0x10DE)
applog(LOG_DEBUG, "nvml: Unknown vendor %04x\n", vid);
return 0;
}
int gpu_vendor(uint8_t pci_bus_id, char *vendorname)
{
uint16_t vid = 0, pid = 0;
if (hnvml) { // may not be initialized on start...
for (int id=0; id < hnvml->nvml_gpucount; id++) {
if (hnvml->nvml_pci_bus_id[id] == pci_bus_id) {
int dev_id = hnvml->nvml_cuda_device_id[id];
nvml_get_info(hnvml, dev_id, vid, pid);
}
}
} else {
#ifdef WIN32
for (unsigned id = 0; id < nvapi_dev_cnt; id++) {
if (device_bus_ids[id] == pci_bus_id) {
nvapi_getinfo(nvapi_dev_map[id], vid, pid);
break;
}
}
#endif
}
return translate_vendor_id(vid, vendorname);
}
int gpu_info(struct cgpu_info *gpu)
{
char vendorname[32] = { 0 };
int id = gpu->gpu_id;
uint8_t bus_id = 0;
gpu->nvml_id = -1;
gpu->nvapi_id = -1;
if (id < 0)
return -1;
if (hnvml) {
gpu->nvml_id = (int8_t) hnvml->cuda_nvml_device_id[id];
nvml_get_info(hnvml, id, gpu->gpu_vid, gpu->gpu_pid);
nvml_get_serial(hnvml, id, gpu->gpu_sn, sizeof(gpu->gpu_sn));
nvml_get_bios(hnvml, id, gpu->gpu_desc, sizeof(gpu->gpu_desc));
}
#ifdef WIN32
gpu->nvapi_id = (int8_t) nvapi_dev_map[id];
nvapi_getinfo(nvapi_dev_map[id], gpu->gpu_vid, gpu->gpu_pid);
nvapi_getserial(nvapi_dev_map[id], gpu->gpu_sn, sizeof(gpu->gpu_sn));
nvapi_getbios(nvapi_dev_map[id], gpu->gpu_desc, sizeof(gpu->gpu_desc));
#endif
return 0;
}
#endif /* USE_WRAPNVML */
static int rgb_percent(int RGB, int percent)
{
uint8_t* comp = (uint8_t*) &RGB;
int res = ((percent*comp[2]) / 100) << 16;
res += ((percent*comp[1]) / 100) << 8;
return res + ((percent*comp[0]) / 100);
}
void gpu_led_on(int dev_id)
{
#if defined(WIN32) && defined(USE_WRAPNVML)
int value = device_led[dev_id];
if (device_led_state[dev_id] != value) {
if (nvapi_set_led(nvapi_dev_map[dev_id], value, device_name[dev_id]) == 0)
device_led_state[dev_id] = value;
}
#endif
}
void gpu_led_percent(int dev_id, int percent)
{
#if defined(WIN32) && defined(USE_WRAPNVML)
int value = rgb_percent(device_led[dev_id], percent);
if (device_led_state[dev_id] != value) {
if (nvapi_set_led(nvapi_dev_map[dev_id], value, device_name[dev_id]) == 0)
device_led_state[dev_id] = value;
}
#endif
}
void gpu_led_off(int dev_id)
{
#if defined(WIN32) && defined(USE_WRAPNVML)
if (device_led_state[dev_id]) {
if (nvapi_set_led(nvapi_dev_map[dev_id], 0, device_name[dev_id]) == 0)
device_led_state[dev_id] = 0;
}
#endif
}
#ifdef USE_WRAPNVML
extern double thr_hashrates[MAX_GPUS];
extern bool opt_debug_threads;
extern bool opt_hwmonitor;
extern int num_cpus;
void *monitor_thread(void *userdata)
{
int thr_id = -1;
while (!abort_flag && !opt_quiet)
{
// This thread monitors card's power lazily during scans, one at a time...
thr_id = (thr_id + 1) % opt_n_threads;
struct cgpu_info *cgpu = &thr_info[thr_id].gpu;
int dev_id = cgpu->gpu_id; cudaSetDevice(dev_id);
if (hnvml != NULL && cgpu)
{
char khw[32] = { 0 };
uint64_t clock = 0, mem_clock = 0;
uint32_t fanpercent = 0, power = 0;
double tempC = 0, khs_per_watt = 0;
uint32_t counter = 0;
int max_loops = 2000;
pthread_cond_wait(&cgpu->monitor.sampling_signal, &cgpu->monitor.lock);
do {
uint32_t tmp_clock, tmp_memclock;
nvml_get_current_clocks(dev_id, &tmp_clock, &tmp_memclock);
clock += tmp_clock;
mem_clock += tmp_memclock;
tempC += gpu_temp(cgpu);
fanpercent += gpu_fanpercent(cgpu);
power += gpu_power(cgpu);
counter++;
usleep(50000);
if (abort_flag) goto abort;
} while (cgpu->monitor.sampling_flag && (--max_loops));
cgpu->monitor.gpu_temp = (uint32_t) (tempC/counter);
cgpu->monitor.gpu_fan = fanpercent/counter;
cgpu->monitor.gpu_power = power/counter;
cgpu->monitor.gpu_clock = (uint32_t) (clock/counter);
cgpu->monitor.gpu_memclock = (uint32_t) (mem_clock/counter);
if (power) {
khs_per_watt = stats_get_speed(thr_id, thr_hashrates[thr_id]);
khs_per_watt = khs_per_watt / ((double)power / counter);
format_hashrate(khs_per_watt * 1000, khw);
if (strlen(khw)) khw[strlen(khw)-1] = 'W';
}
if (opt_hwmonitor && (time(NULL) - cgpu->monitor.tm_displayed) > 60) {
gpulog(LOG_INFO, thr_id, "%u MHz %s %uW %uC FAN %u%%",
cgpu->monitor.gpu_clock/*, cgpu->monitor.gpu_memclock*/,
khw, cgpu->monitor.gpu_power / 1000,
cgpu->monitor.gpu_temp, cgpu->monitor.gpu_fan
);
cgpu->monitor.tm_displayed = (uint32_t)time(NULL);
}
pthread_mutex_unlock(&cgpu->monitor.lock);
}
usleep(500); // safety
}
abort:
if (opt_debug_threads)
applog(LOG_DEBUG, "%s() died", __func__);
return NULL;
}
#endif