/*
* Copyright (c) Souldbminer, Lightos_ and Horizon OC Contributors
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*
*/
/* --------------------------------------------------------------------------
* "THE BEER-WARE LICENSE" (Revision 42):
* , ,
* wrote this file. As long as you retain this notice you can do whatever you
* want with this stuff. If you meet any of us some day, and you think this
* stuff is worth it, you can buy us a beer in return. - The sys-clk authors
* --------------------------------------------------------------------------
*/
#include "clock_manager.h"
#include
#include "file_utils.h"
#include "board.h"
#include "process_management.h"
#include "errors.h"
#include "ipc_service.h"
#include "kip.h"
#include
#include "notification.h"
#include
#include
#include
#include
#define HOSPPC_HAS_BOOST (hosversionAtLeast(7,0,0))
// governor constants
#define POLL_NS 5'000'000 // 5 ms – governor poll rate
#define DOWN_HOLD_TICKS 10 // 50 ms – how long to in POLL_NS to hold while ramping down
#define STEP_UTIL 900 // multiplier for step calculations
bool isGpuGovernorEnabled = false;
bool isCpuGovernorEnabled = false;
bool lastGpuGovernorState = false;
bool lastCpuGovernorState = false;
bool lastVrrGovernorState = false;
bool hasChanged = true;
ClockManager *ClockManager::instance = NULL;
Thread cpuGovernorTHREAD;
Thread gpuGovernorTHREAD;
Thread vrrTHREAD;
u32 initialConfigValues[SysClkConfigValue_EnumMax]; // initial config. used for safety checks
bool kipAvailable = false;
bool isCpuGovernorInBoostMode = false;
bool isVRREnabled = false;
ClockManager *ClockManager::GetInstance()
{
return instance;
}
void ClockManager::Exit()
{
if (instance)
{
delete instance;
}
}
void ClockManager::Initialize()
{
if (!instance)
{
instance = new ClockManager();
}
}
ClockManager::ClockManager()
{
this->config = Config::CreateDefault();
this->context = new SysClkContext;
this->context->applicationId = 0;
this->context->profile = SysClkProfile_Handheld;
for (unsigned int module = 0; module < SysClkModule_EnumMax; module++)
{
this->context->freqs[module] = 0;
this->context->realFreqs[module] = 0;
this->context->overrideFreqs[module] = 0;
this->RefreshFreqTableRow((SysClkModule)module);
}
this->running = false;
this->lastTempLogNs = 0;
this->lastCsvWriteNs = 0;
this->sysDockIntegration = new SysDockIntegration;
this->saltyNXIntegration = new SaltyNXIntegration;
memset(&initialConfigValues, 0, sizeof(initialConfigValues));
this->GetKipData();
threadCreate(
&cpuGovernorTHREAD,
ClockManager::CpuGovernorThread,
this,
NULL,
0x2000,
0x3F,
-2
);
threadCreate(
&gpuGovernorTHREAD,
ClockManager::GovernorThread,
this,
NULL,
0x2000,
0x3F,
-2
);
threadCreate(
&vrrTHREAD,
ClockManager::VRRThread,
this,
NULL,
0x2000,
0x3F,
-2
);
for(int i = 0; i < HorizonOCSpeedo_EnumMax; i++) {
this->context->speedos[i] = Board::getSpeedo((HorizonOCSpeedo)i);
this->context->iddq[i] = Board::getIDDQ((HorizonOCSpeedo)i);
}
this->context->dramID = Board::GetDramID();
this->context->isDram8GB = Board::IsDram8GB();
Board::SetGpuSchedulingMode((GpuSchedulingMode)this->config->GetConfigValue(HorizonOCConfigValue_GPUScheduling), (GpuSchedulingOverrideMethod)this->config->GetConfigValue(HorizonOCConfigValue_GPUSchedulingMethod));
this->context->gpuSchedulingMode = (GpuSchedulingMode)this->config->GetConfigValue(HorizonOCConfigValue_GPUScheduling);
this->context->isSysDockInstalled = this->sysDockIntegration->getCurrentSysDockState();
this->context->isSaltyNXInstalled = this->saltyNXIntegration->getCurrentSaltyNXState();
if(this->context->isSaltyNXInstalled) {
this->saltyNXIntegration->LoadSaltyNX();
}
this->context->isUsingRetroSuper = Board::IsUsingRetroSuperDisplay();
threadStart(&cpuGovernorTHREAD);
threadStart(&gpuGovernorTHREAD);
threadStart(&vrrTHREAD);
}
ClockManager::~ClockManager()
{
threadClose(&cpuGovernorTHREAD);
threadClose(&gpuGovernorTHREAD);
threadClose(&vrrTHREAD);
delete this->sysDockIntegration;
delete this->saltyNXIntegration;
delete this->config;
delete this->context;
}
SysClkContext ClockManager::GetCurrentContext()
{
std::scoped_lock lock{this->contextMutex};
return *this->context;
}
Config *ClockManager::GetConfig()
{
return this->config;
}
void ClockManager::SetRunning(bool running)
{
this->running = running;
}
bool ClockManager::Running()
{
return this->running;
}
void ClockManager::GetFreqList(SysClkModule module, std::uint32_t *list, std::uint32_t maxCount, std::uint32_t *outCount)
{
ASSERT_ENUM_VALID(SysClkModule, module);
*outCount = std::min(maxCount, this->freqTable[module].count);
memcpy(list, &this->freqTable[module].list[0], *outCount * sizeof(this->freqTable[0].list[0]));
}
bool ClockManager::IsAssignableHz(SysClkModule module, std::uint32_t hz)
{
switch (module)
{
case SysClkModule_CPU:
return hz >= 500000000;
case SysClkModule_MEM:
return hz >= 665600000;
default:
return true;
}
}
std::uint32_t ClockManager::GetMaxAllowedHz(SysClkModule module, SysClkProfile profile)
{
if (this->config->GetConfigValue(HocClkConfigValue_UncappedClocks))
{
return ~0; // Integer limit, uncapped clocks ON
}
else
{
if (module == SysClkModule_GPU)
{
if (profile < SysClkProfile_HandheldCharging)
{
switch(Board::GetSocType()) {
case SysClkSocType_Erista:
return 460800000;
case SysClkSocType_Mariko:
switch(this->config->GetConfigValue(KipConfigValue_marikoGpuUV)) {
case 0:
return 614400000;
case 1:
return 691200000;
case 2:
return 768000000;
default:
return 614400000;
}
default:
return 460800000;
}
}
else if (profile <= SysClkProfile_HandheldChargingUSB)
{
switch(Board::GetSocType()) {
case SysClkSocType_Erista:
return 768000000;
case SysClkSocType_Mariko:
switch(this->config->GetConfigValue(KipConfigValue_marikoGpuUV)) {
case 0:
return 844800000;
case 1:
return 921600000;
case 2:
return 998400000;
default:
return 844800000;
}
default:
return 768000000;
}
}
} else if(module == SysClkModule_CPU) {
if(profile < SysClkProfile_HandheldCharging && Board::GetSocType() == SysClkSocType_Erista) {
return 1581000000;
} else {
return ~0;
}
}
}
return 0;
}
std::uint32_t ClockManager::GetNearestHz(SysClkModule module, std::uint32_t inHz, std::uint32_t maxHz)
{
std::uint32_t *freqs = &this->freqTable[module].list[0];
size_t count = this->freqTable[module].count - 1;
size_t i = 0;
while (i < count)
{
if (maxHz > 0 && freqs[i] >= maxHz)
{
break;
}
if (inHz <= ((std::uint64_t)freqs[i] + freqs[i + 1]) / 2)
{
break;
}
i++;
}
return freqs[i];
}
bool ClockManager::ConfigIntervalTimeout(SysClkConfigValue intervalMsConfigValue, std::uint64_t ns, std::uint64_t *lastLogNs)
{
std::uint64_t logInterval = this->GetConfig()->GetConfigValue(intervalMsConfigValue) * 1000000ULL;
bool shouldLog = logInterval && ((ns - *lastLogNs) > logInterval);
if (shouldLog)
{
*lastLogNs = ns;
}
return shouldLog;
}
void ClockManager::RefreshFreqTableRow(SysClkModule module)
{
std::scoped_lock lock{this->contextMutex};
std::uint32_t freqs[SYSCLK_FREQ_LIST_MAX];
std::uint32_t count;
FileUtils::LogLine("[mgr] %s freq list refresh", Board::GetModuleName(module, true));
Board::GetFreqList(module, &freqs[0], SYSCLK_FREQ_LIST_MAX, &count);
std::uint32_t *hz = &this->freqTable[module].list[0];
this->freqTable[module].count = 0;
for (std::uint32_t i = 0; i < count; i++)
{
if (!this->IsAssignableHz(module, freqs[i]))
{
continue;
}
*hz = freqs[i];
FileUtils::LogLine("[mgr] %02u - %u - %u.%u MHz", this->freqTable[module].count, *hz, *hz / 1000000, *hz / 100000 - *hz / 1000000 * 10);
this->freqTable[module].count++;
hz++;
}
FileUtils::LogLine("[mgr] count = %u", this->freqTable[module].count);
}
u32 ClockManager::SchedutilTargetHz(u32 util, u32 tableMaxHz) {
u64 hz = (u64)tableMaxHz * util / STEP_UTIL;
return (u32)(std::min(hz, static_cast(tableMaxHz)));
}
u32 ClockManager::TableIndexForHz(const FreqTable& table, u32 targetHz) { // must pass in a freqTable as tables are different for cpu/gpu
for (u32 i = 0; i < table.count; i++)
if (table.list[i] >= targetHz)
return i;
return table.count - 1;
}
u32 ClockManager::ResolveTargetHz(ClockManager* mgr, SysClkModule module) {
u32 hz = mgr->context->overrideFreqs[module];
if (!hz)
hz = mgr->config->GetAutoClockHz(
mgr->context->applicationId, module,
mgr->context->profile, false);
if (!hz)
hz = mgr->config->GetAutoClockHz(
GLOBAL_PROFILE_ID, module,
mgr->context->profile, false);
return hz;
}
void ClockManager::CpuGovernorThread(void* arg) {
ClockManager* mgr = static_cast(arg);
u32 downHoldRemaining = 0;
u32 lastHz = 0;
u32 minHz = 612;
u32 tick = 0;
for (;;) {
if (!mgr->running || !isCpuGovernorEnabled) {
downHoldRemaining = 0;
lastHz = 0;
svcSleepThread(POLL_NS);
continue;
}
u32 mode = 0;
Result rc = apmExtGetCurrentPerformanceConfiguration(&mode);
if (R_SUCCEEDED(rc) && apmExtIsBoostMode(mode)) {
isCpuGovernorInBoostMode = true;
downHoldRemaining = 0;
lastHz = 0;
continue; // TODO: figure out a way to get boost clock easily and set it instead of just skipping the governor
} else if(!apmExtIsBoostMode(mode)) {
isCpuGovernorInBoostMode = false;
}
auto& table = mgr->freqTable[SysClkModule_CPU];
if (table.count == 0)
continue;
std::scoped_lock lock{mgr->contextMutex};
u32 cpuLoad = Board::GetPartLoad(HocClkPartLoad_CPUMax);
u32 tableMaxHz = table.list[table.count - 1];
u32 desiredHz = ClockManager::SchedutilTargetHz(cpuLoad, tableMaxHz);
u32 targetHz = ClockManager::ResolveTargetHz(mgr, SysClkModule_CPU);
u32 maxHz = mgr->GetMaxAllowedHz(SysClkModule_CPU, mgr->context->profile);
if (targetHz && desiredHz > targetHz)
desiredHz = targetHz;
if (maxHz && desiredHz > maxHz)
desiredHz = maxHz;
u32 newHz = table.list[ClockManager::TableIndexForHz(table, desiredHz)];
// ramp up fast, go down slow
bool goingDown = (lastHz != 0) && (newHz < lastHz);
if (!goingDown)
downHoldRemaining = 0;
else if (downHoldRemaining == 0)
downHoldRemaining = DOWN_HOLD_TICKS;
if (downHoldRemaining > 0)
downHoldRemaining--;
if(++tick > 50) {
minHz = mgr->config->GetConfigValue(HorizonOCConfigValue_CpuGovernorMinimumFreq);
tick = 0;
}
if(newHz < minHz)
newHz = minHz;
if ((!goingDown || (downHoldRemaining == 0)) && mgr->IsAssignableHz(SysClkModule_CPU, newHz)) {
Board::SetHz(SysClkModule_CPU, newHz);
mgr->context->freqs[SysClkModule_CPU] = newHz;
lastHz = newHz;
}
svcSleepThread(POLL_NS);
}
}
void ClockManager::GovernorThread(void* arg) {
ClockManager* mgr = static_cast(arg);
u32 downHoldRemaining = 0;
u32 lastHz = 0;
for (;;) {
if (!mgr->running || !isGpuGovernorEnabled) {
downHoldRemaining = 0;
lastHz = 0;
svcSleepThread(POLL_NS);
continue;
}
auto& table = mgr->freqTable[SysClkModule_GPU];
if (table.count == 0)
continue;
std::scoped_lock lock{mgr->contextMutex};
u32 gpuLoad = Board::GetPartLoad(HocClkPartLoad_GPU);
u32 tableMaxHz = table.list[table.count - 1];
u32 desiredHz = ClockManager::SchedutilTargetHz(gpuLoad, tableMaxHz);
u32 targetHz = ClockManager::ResolveTargetHz(mgr, SysClkModule_GPU);
u32 maxHz = mgr->GetMaxAllowedHz(SysClkModule_GPU, mgr->context->profile);
if (targetHz && desiredHz > targetHz)
desiredHz = targetHz;
if (maxHz && desiredHz > maxHz)
desiredHz = maxHz;
u32 newHz = table.list[ClockManager::TableIndexForHz(table, desiredHz)];
bool goingDown = (lastHz != 0) && (newHz < lastHz);
if (!goingDown)
downHoldRemaining = 0;
else if (downHoldRemaining == 0)
downHoldRemaining = DOWN_HOLD_TICKS;
if (downHoldRemaining > 0)
downHoldRemaining--;
if ((!goingDown || (downHoldRemaining == 0)) && mgr->IsAssignableHz(SysClkModule_GPU, newHz)) {
Board::SetHz(SysClkModule_GPU, newHz);
mgr->context->freqs[SysClkModule_GPU] = newHz;
lastHz = newHz;
}
svcSleepThread(POLL_NS);
}
}
void ClockManager::VRRThread(void* arg) {
ClockManager* mgr = static_cast(arg);
u8 tick = 0;
for (;;) {
if (!mgr->running || mgr->context->profile == SysClkProfile_Docked || !isVRREnabled) {
svcSleepThread(POLL_NS);
continue;
}
std::scoped_lock lock{mgr->contextMutex};
u8 fps;
if(mgr->context->isSaltyNXInstalled) {
fps = mgr->saltyNXIntegration->GetFPS();
} else {
svcSleepThread(~0ULL); // effectively disable the thread if SaltyNX isn't installed, as there's no point in it running
continue;
}
if(fps == 254) {
svcSleepThread(POLL_NS);
continue;
}
// if(appletGetFocusState() != AppletFocusState_InFocus) {
// Board::ResetToStockDisplay();
// continue;
// }
u32 targetHz = mgr->context->overrideFreqs[HorizonOCModule_Display];
if (!targetHz)
{
targetHz = mgr->config->GetAutoClockHz(mgr->context->applicationId, HorizonOCModule_Display, mgr->context->profile, false);
if(!targetHz)
targetHz = mgr->config->GetAutoClockHz(GLOBAL_PROFILE_ID, HorizonOCModule_Display, mgr->context->profile, false);
}
u8 maxDisplay;
if(targetHz) {
maxDisplay = targetHz;
} else {
maxDisplay = 60;
}
u8 minDisplay = Board::GetConsoleType() == HorizonOCConsoleType_Aula ? 45 : 40;
if(maxDisplay == minDisplay)
continue;
if(fps >= minDisplay && fps <= maxDisplay) {
Board::SetHz(HorizonOCModule_Display, fps);
mgr->context->freqs[HorizonOCModule_Display] = fps;
mgr->context->realFreqs[HorizonOCModule_Display] = fps;
} else {
for(u32 i = 0; i < 10; i++) {
u32 compareHz = fps * i;
if(compareHz >= minDisplay && compareHz <= maxDisplay) {
Board::SetHz(HorizonOCModule_Display, compareHz);
mgr->context->freqs[HorizonOCModule_Display] = compareHz;
mgr->context->realFreqs[HorizonOCModule_Display] = compareHz;
break;
}
}
}
if(++tick > 50) {
Board::SetHz(HorizonOCModule_Display, maxDisplay);
tick = 0;
svcSleepThread(25'000'000);
}
svcSleepThread(POLL_NS);
}
}
void ClockManager::HandleSafetyFeatures() {
AppletOperationMode opMode = appletGetOperationMode();
if(this->config->GetConfigValue(HocClkConfigValue_HandheldTDP) && opMode == AppletOperationMode_Handheld) {
if(Board::GetConsoleType() == HorizonOCConsoleType_Hoag) {
if(Board::GetPowerMw(SysClkPowerSensor_Avg) < -(int)this->config->GetConfigValue(HocClkConfigValue_LiteTDPLimit)) {
ResetToStockClocks();
return;
}
} else {
if(Board::GetPowerMw(SysClkPowerSensor_Avg) < -(int)this->config->GetConfigValue(HocClkConfigValue_HandheldTDPLimit)) {
ResetToStockClocks();
return;
}
}
}
if(((tmp451TempSoc() / 1000) > (int)this->config->GetConfigValue(HocClkConfigValue_ThermalThrottleThreshold)) && this->config->GetConfigValue(HocClkConfigValue_ThermalThrottle)) {
ResetToStockClocks();
return;
}
}
void ClockManager::HandleMiscFeatures() {
if(this->config->GetConfigValue(HorizonOCConfigValue_BatteryChargeCurrent)) {
I2c_Bq24193_SetFastChargeCurrentLimit(this->config->GetConfigValue(HorizonOCConfigValue_BatteryChargeCurrent));
}
}
void ClockManager::HandleGovernor(uint32_t targetHz) {
u32 tempTargetHz = this->context->overrideFreqs[HorizonOCModule_Governor];
if (!tempTargetHz)
{
tempTargetHz = this->config->GetAutoClockHz(this->context->applicationId, HorizonOCModule_Governor, this->context->profile, true);
if (!tempTargetHz)
tempTargetHz = this->config->GetAutoClockHz(GLOBAL_PROFILE_ID, HorizonOCModule_Governor, this->context->profile, true);
}
auto resolve = [](u8 app, u8 temp) -> u8 {
if (temp == ComponentGovernor_Disabled) return ComponentGovernor_Disabled;
if (temp != ComponentGovernor_DoNotOverride) return temp;
return app;
};
u8 effectiveCpu = resolve(GovernorStateCpu(targetHz), GovernorStateCpu(tempTargetHz));
u8 effectiveGpu = resolve(GovernorStateGpu(targetHz), GovernorStateGpu(tempTargetHz));
u8 effectiveVrr = resolve(GovernorStateVrr(targetHz), GovernorStateVrr(tempTargetHz));
bool newCpuGovernorState = (effectiveCpu == ComponentGovernor_Enabled);
bool newGpuGovernorState = (effectiveGpu == ComponentGovernor_Enabled);
bool newVrrGovernorState = (effectiveVrr == ComponentGovernor_Enabled);
isCpuGovernorEnabled = newCpuGovernorState;
isGpuGovernorEnabled = newGpuGovernorState;
isVRREnabled = newVrrGovernorState;
if(newCpuGovernorState == false && lastCpuGovernorState == true) {
svcSleepThread(100'000'000); // thread syncing. probably a cleaner way to do this but hey, it works!
Board::ResetToStockCpu();
}
if(newGpuGovernorState == false && lastGpuGovernorState == true) {
svcSleepThread(100'000'000);
Board::ResetToStockGpu();
}
if (newVrrGovernorState == false && lastVrrGovernorState == true) {
svcSleepThread(100'000'000);
Board::ResetToStockDisplay();
}
if(newCpuGovernorState != lastCpuGovernorState || newGpuGovernorState != lastGpuGovernorState || newVrrGovernorState != lastVrrGovernorState) {
FileUtils::LogLine("[mgr] Governor state changed: CPU %s, GPU %s, VRR %s", newCpuGovernorState ? "enabled" : "disabled", newGpuGovernorState ? "enabled" : "disabled", newVrrGovernorState ? "enabled" : "disabled");
lastCpuGovernorState = newCpuGovernorState;
lastGpuGovernorState = newGpuGovernorState;
lastVrrGovernorState = newVrrGovernorState;
}
}
void ClockManager::DVFSBeforeSet(u32 targetHz) {
s32 dvfsOffset = this->config->GetConfigValue(HorizonOCConfigValue_DVFSOffset);
u32 vmin = Board::GetMinimumGpuVoltage(targetHz / 1000000) + dvfsOffset;
Board::PcvHijackDvfs(vmin);
/* Update the voltage. */
if (I2c_BuckConverter_GetMvOut(&I2c_Mariko_GPU) < vmin) {
I2c_BuckConverter_SetMvOut(&I2c_Mariko_GPU, vmin);
}
this->context->voltages[HocClkVoltage_GPU] = vmin * 1000;
}
void ClockManager::DVFSAfterSet(u32 targetHz) {
s32 dvfsOffset = this->config->GetConfigValue(HorizonOCConfigValue_DVFSOffset);
dvfsOffset = std::max(dvfsOffset, -80);
u32 vmin = Board::GetMinimumGpuVoltage(targetHz / 1000000);
if (vmin) {
vmin += dvfsOffset;
}
u32 maxHz = this->GetMaxAllowedHz(SysClkModule_GPU, this->context->profile);
u32 nearestHz = this->GetNearestHz(SysClkModule_GPU, targetHz, maxHz);
Board::PcvHijackDvfs(vmin);
if (targetHz) {
Board::SetHz(SysClkModule_GPU, ~0);
Board::SetHz(SysClkModule_GPU, nearestHz);
} else {
Board::SetHz(SysClkModule_GPU, ~0);
Board::ResetToStockGpu();
}
}
void ClockManager::HandleCpuUv() {
if(Board::GetSocType() == SysClkSocType_Erista)
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_eristaCpuUV), 0, 1581000000);
else
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_marikoCpuUVLow), this->config->GetConfigValue(KipConfigValue_marikoCpuUVHigh), Board::CalculateTbreak(this->config->GetConfigValue(KipConfigValue_tableConf)));
}
void ClockManager::DVFSReset() {
if (Board::GetSocType() == SysClkSocType_Mariko && this->config->GetConfigValue(HorizonOCConfigValue_DVFSMode) == DVFSMode_Hijack) {
Board::PcvHijackDvfs(0);
u32 targetHz = this->context->overrideFreqs[SysClkModule_GPU];
if (!targetHz) {
targetHz = this->config->GetAutoClockHz(this->context->applicationId, SysClkModule_GPU, this->context->profile, false);
if(!targetHz) {
targetHz = this->config->GetAutoClockHz(GLOBAL_PROFILE_ID, SysClkModule_GPU, this->context->profile, false);
}
}
u32 maxHz = this->GetMaxAllowedHz(SysClkModule_GPU, this->context->profile);
u32 nearestHz = this->GetNearestHz(SysClkModule_GPU, targetHz, maxHz);
Board::SetHz(SysClkModule_GPU, ~0);
if(targetHz) {
Board::SetHz(SysClkModule_GPU, nearestHz);
} else {
Board::ResetToStockGpu();
}
}
}
void ClockManager::HandleFreqReset(SysClkModule module, bool isBoost) {
switch (module)
{
case SysClkModule_CPU:
if(!(isBoost || (this->config->GetConfigValue(HocClkConfigValue_OverwriteBoostMode) && isBoost)))
Board::ResetToStockCpu();
if(this->config->GetConfigValue(HorizonOCConfigValue_LiveCpuUv)) {
if(Board::GetSocType() == SysClkSocType_Erista)
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_eristaCpuUV), 0, 1581000000);
else
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_marikoCpuUVLow), this->config->GetConfigValue(KipConfigValue_marikoCpuUVHigh), Board::CalculateTbreak(this->config->GetConfigValue(KipConfigValue_tableConf)));
}
break;
case SysClkModule_GPU:
Board::ResetToStockGpu();
break;
case SysClkModule_MEM:
Board::ResetToStockMem();
DVFSReset();
break;
case HorizonOCModule_Display:
if(this->config->GetConfigValue(HorizonOCConfigValue_OverwriteRefreshRate)) {
Board::ResetToStockDisplay();
}
break;
default:
break;
}
}
void ClockManager::SetClocks(bool isBoost) {
std::uint32_t targetHz = 0;
std::uint32_t maxHz = 0;
std::uint32_t nearestHz = 0;
if(isBoost && !this->config->GetConfigValue(HocClkConfigValue_OverwriteBoostMode)) {
u32 boostFreq = Board::GetHz(SysClkModule_CPU);
if (boostFreq / 1000000 > 1785) {
Board::SetHz(SysClkModule_CPU, boostFreq);
}
return; // Return if we are't overwriting boost mode
}
bool returnRaw = false; // Return a value scaled to MHz instead of raw value
for (unsigned int module = 0; module < SysClkModule_EnumMax; module++)
{
u32 oldHz = Board::GetHz((SysClkModule)module); // Get Old hz (used primarily for DVFS Logic)
if(module > SysClkModule_MEM)
returnRaw = true;
else
returnRaw = false;
targetHz = this->context->overrideFreqs[module];
if (!targetHz)
{
targetHz = this->config->GetAutoClockHz(this->context->applicationId, (SysClkModule)module, this->context->profile, returnRaw);
if(!targetHz)
targetHz = this->config->GetAutoClockHz(GLOBAL_PROFILE_ID, (SysClkModule)module, this->context->profile, returnRaw);
}
if(module == HorizonOCModule_Governor) {
HandleGovernor(targetHz);
}
bool noCPU = isCpuGovernorEnabled;
bool noGPU = isGpuGovernorEnabled;
bool noDisp = isVRREnabled;
if(noDisp && module == HorizonOCModule_Display)
continue;
if(module == HorizonOCModule_Display && this->config->GetConfigValue(HorizonOCConfigValue_OverwriteRefreshRate) && !noDisp) {
if(targetHz) {
Board::SetHz(HorizonOCModule_Display, targetHz);
this->context->freqs[HorizonOCModule_Display] = targetHz;
this->context->realFreqs[HorizonOCModule_Display] = targetHz;
} else {
HandleFreqReset(HorizonOCModule_Display, isBoost);
}
}
// Skip GPU and CPU if governors handle them
if(module > SysClkModule_MEM) {
continue;
}
if(noCPU && module == SysClkModule_CPU)
continue;
if(noGPU && module == SysClkModule_GPU)
continue;
if (targetHz)
{
maxHz = this->GetMaxAllowedHz((SysClkModule)module, this->context->profile);
nearestHz = this->GetNearestHz((SysClkModule)module, targetHz, maxHz);
if (nearestHz != this->context->freqs[module]) {
FileUtils::LogLine(
"[mgr] %s clock set : %u.%u MHz (target = %u.%u MHz)",
Board::GetModuleName((SysClkModule)module, true),
nearestHz / 1000000, nearestHz / 100000 - nearestHz / 1000000 * 10,
targetHz / 1000000, targetHz / 100000 - targetHz / 1000000 * 10
);
if(module == SysClkModule_MEM && Board::GetSocType() == SysClkSocType_Mariko && targetHz > oldHz && this->config->GetConfigValue(HorizonOCConfigValue_DVFSMode) == DVFSMode_Hijack) {
DVFSBeforeSet(targetHz);
}
Board::SetHz((SysClkModule)module, nearestHz);
this->context->freqs[module] = nearestHz;
if(module == SysClkModule_CPU && (this->config->GetConfigValue(HorizonOCConfigValue_LiveCpuUv))) {
HandleCpuUv();
}
if(module == SysClkModule_MEM && Board::GetSocType() == SysClkSocType_Mariko && targetHz < oldHz && this->config->GetConfigValue(HorizonOCConfigValue_DVFSMode) == DVFSMode_Hijack) {
DVFSAfterSet(targetHz);
}
}
} else {
HandleFreqReset((SysClkModule)module, isBoost);
}
}
}
void ClockManager::Tick()
{
std::scoped_lock lock{this->contextMutex};
std::uint32_t mode = 0;
Result rc = apmExtGetCurrentPerformanceConfiguration(&mode);
ASSERT_RESULT_OK(rc, "apmExtGetCurrentPerformanceConfiguration");
bool isBoost = apmExtIsBoostMode(mode);
HandleSafetyFeatures();
if (this->RefreshContext() || this->config->Refresh())
{
HandleMiscFeatures();
SetClocks(isBoost);
}
}
void ClockManager::ResetToStockClocks() {
Board::ResetToStockCpu();
if(this->config->GetConfigValue(HorizonOCConfigValue_LiveCpuUv))
{
if(Board::GetSocType() == SysClkSocType_Erista)
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_eristaCpuUV), 0, 1581000000);
else
Board::SetCpuUvLevel(this->config->GetConfigValue(KipConfigValue_marikoCpuUVLow), this->config->GetConfigValue(KipConfigValue_marikoCpuUVHigh), Board::CalculateTbreak(this->config->GetConfigValue(KipConfigValue_tableConf)));
}
Board::ResetToStockGpu();
}
void ClockManager::WaitForNextTick()
{
if(!(Board::GetHz(SysClkModule_MEM) < 665000000))
svcSleepThread(this->GetConfig()->GetConfigValue(SysClkConfigValue_PollingIntervalMs) * 1000000ULL);
else
svcSleepThread(5000 * 1000000ULL); // 5 seconds in sleep mode
}
bool ClockManager::RefreshContext()
{
bool hasChanged = false;
std::uint32_t mode = 0;
Result rc = apmExtGetCurrentPerformanceConfiguration(&mode);
ASSERT_RESULT_OK(rc, "apmExtGetCurrentPerformanceConfiguration");
std::uint64_t applicationId = ProcessManagement::GetCurrentApplicationId();
if (applicationId != this->context->applicationId)
{
FileUtils::LogLine("[mgr] TitleID change: %016lX", applicationId);
this->context->applicationId = applicationId;
hasChanged = true;
}
SysClkProfile profile = Board::GetProfile();
if (profile != this->context->profile)
{
FileUtils::LogLine("[mgr] Profile change: %s", Board::GetProfileName(profile, true));
this->context->profile = profile;
hasChanged = true;
}
// restore clocks to stock values on app or profile change
if (hasChanged)
{
Board::ResetToStock();
if (Board::GetSocType() == SysClkSocType_Mariko && this->config->GetConfigValue(HorizonOCConfigValue_DVFSMode) == DVFSMode_Hijack) {
Board::PcvHijackDvfs(0);
Board::SetHz(SysClkModule_GPU, ~0);
Board::ResetToStockGpu();
}
this->WaitForNextTick();
}
std::uint32_t hz = 0;
for (unsigned int module = 0; module < SysClkModule_EnumMax; module++)
{
hz = Board::GetHz((SysClkModule)module);
if (hz != 0 && hz != this->context->freqs[module])
{
FileUtils::LogLine("[mgr] %s clock change: %u.%u MHz", Board::GetModuleName((SysClkModule)module, true), hz / 1000000, hz / 100000 - hz / 1000000 * 10);
this->context->freqs[module] = hz;
hasChanged = true;
}
hz = this->GetConfig()->GetOverrideHz((SysClkModule)module);
if (hz != this->context->overrideFreqs[module])
{
if (hz)
{
FileUtils::LogLine("[mgr] %s override change: %u.%u MHz", Board::GetModuleName((SysClkModule)module, true), hz / 1000000, hz / 100000 - hz / 1000000 * 10);
}
this->context->overrideFreqs[module] = hz;
hasChanged = true;
}
}
std::uint64_t ns = armTicksToNs(armGetSystemTick());
// temperatures do not and should not force a refresh, hasChanged untouched
std::uint32_t millis = 0;
bool shouldLogTemp = this->ConfigIntervalTimeout(SysClkConfigValue_TempLogIntervalMs, ns, &this->lastTempLogNs);
for (unsigned int sensor = 0; sensor < SysClkThermalSensor_EnumMax; sensor++)
{
millis = Board::GetTemperatureMilli((SysClkThermalSensor)sensor);
if (shouldLogTemp)
{
FileUtils::LogLine("[mgr] %s temp: %u.%u °C", Board::GetThermalSensorName((SysClkThermalSensor)sensor, true), millis / 1000, (millis - millis / 1000 * 1000) / 100);
}
this->context->temps[sensor] = millis;
}
// power stats do not and should not force a refresh, hasChanged untouched
std::int32_t mw = 0;
bool shouldLogPower = this->ConfigIntervalTimeout(SysClkConfigValue_PowerLogIntervalMs, ns, &this->lastPowerLogNs);
for (unsigned int sensor = 0; sensor < SysClkPowerSensor_EnumMax; sensor++)
{
mw = Board::GetPowerMw((SysClkPowerSensor)sensor);
if (shouldLogPower)
{
FileUtils::LogLine("[mgr] Power %s: %d mW", Board::GetPowerSensorName((SysClkPowerSensor)sensor, false), mw);
}
this->context->power[sensor] = mw;
}
// real freqs do not and should not force a refresh, hasChanged untouched
std::uint32_t realHz = 0;
bool shouldLogFreq = this->ConfigIntervalTimeout(SysClkConfigValue_FreqLogIntervalMs, ns, &this->lastFreqLogNs);
for (unsigned int module = 0; module < SysClkModule_EnumMax; module++)
{
realHz = Board::GetRealHz((SysClkModule)module);
if (shouldLogFreq)
{
FileUtils::LogLine("[mgr] %s real freq: %u.%u MHz", Board::GetModuleName((SysClkModule)module, true), realHz / 1000000, realHz / 100000 - realHz / 1000000 * 10);
}
this->context->realFreqs[module] = realHz;
}
// ram load do not and should not force a refresh, hasChanged untouched
for (unsigned int loadSource = 0; loadSource < SysClkPartLoad_EnumMax; loadSource++)
{
this->context->partLoad[loadSource] = Board::GetPartLoad((SysClkPartLoad)loadSource);
}
for (unsigned int voltageSource = 0; voltageSource < HocClkVoltage_EnumMax; voltageSource++)
{
this->context->voltages[voltageSource] = Board::GetVoltage((HocClkVoltage)voltageSource);
}
if (this->ConfigIntervalTimeout(SysClkConfigValue_CsvWriteIntervalMs, ns, &this->lastCsvWriteNs))
{
FileUtils::WriteContextToCsv(this->context);
}
// this->context->maxDisplayFreq = Board::GetHighestDockedDisplayRate();
u32 targetHz = this->context->overrideFreqs[HorizonOCModule_Display];
if (!targetHz)
{
targetHz = this->config->GetAutoClockHz(this->context->applicationId, HorizonOCModule_Display, this->context->profile, true);
if(!targetHz)
targetHz = this->config->GetAutoClockHz(GLOBAL_PROFILE_ID, HorizonOCModule_Display, this->context->profile, true);
}
if(targetHz && this->context->realFreqs[HorizonOCModule_Display] > targetHz && this->context->profile != SysClkProfile_Docked) {
this->context->realFreqs[HorizonOCModule_Display] = targetHz; // clean up display real freqs, should probably be moved to the real freqs loop?
hasChanged = true;
}
if(!Board::IsHoag())
Board::SetDisplayRefreshDockedState(this->context->profile == SysClkProfile_Docked);
if(this->context->isSaltyNXInstalled)
this->context->fps = saltyNXIntegration->GetFPS();
else
this->context->fps = 254; // N/A
if(this->context->isSaltyNXInstalled)
this->context->resolutionHeight = saltyNXIntegration->GetResolutionHeight();
else
this->context->resolutionHeight = 0; // N/A
return hasChanged;
}
void ClockManager::SetKipData() {
// TODO: figure out if this REALLY causes issues (i doubt it)
// if(Board::GetSocType() == SysClkSocType_Mariko) {
// if(R_FAILED(I2c_BuckConverter_SetMvOut(&I2c_Mariko_DRAM_VDDQ, this->config->GetConfigValue(KipConfigValue_marikoEmcVddqVolt) / 1000))) {
// FileUtils::LogLine("[clock_manager] Failed set i2c vddq");
// writeNotification("Horizon OC\nFailed to write I2C\nwhile setting vddq");
// }
// }
CustomizeTable table;
FILE* fp;
fp = fopen("sdmc:/atmosphere/kips/hoc.kip", "r");
if (fp == NULL) {
writeNotification("Horizon OC\nKip opening failed");
kipAvailable = false;
return;
} else {
kipAvailable = true;
fclose(fp);
}
if (!cust_read_and_cache("sdmc:/atmosphere/kips/hoc.kip", &table)) {
FileUtils::LogLine("[clock_manager] Failed to read KIP file");
writeNotification("Horizon OC\nKip read failed");
return;
}
CUST_WRITE_FIELD_BATCH(&table, custRev, this->config->GetConfigValue(KipConfigValue_custRev));
// CUST_WRITE_FIELD_BATCH(&table, mtcConf, this->config->GetConfigValue(KipConfigValue_mtcConf));
CUST_WRITE_FIELD_BATCH(&table, hpMode, this->config->GetConfigValue(KipConfigValue_hpMode));
CUST_WRITE_FIELD_BATCH(&table, commonEmcMemVolt, this->config->GetConfigValue(KipConfigValue_commonEmcMemVolt));
CUST_WRITE_FIELD_BATCH(&table, eristaEmcMaxClock, this->config->GetConfigValue(KipConfigValue_eristaEmcMaxClock));
CUST_WRITE_FIELD_BATCH(&table, eristaEmcMaxClock1, this->config->GetConfigValue(KipConfigValue_eristaEmcMaxClock1));
CUST_WRITE_FIELD_BATCH(&table, eristaEmcMaxClock2, this->config->GetConfigValue(KipConfigValue_eristaEmcMaxClock2));
CUST_WRITE_FIELD_BATCH(&table, marikoEmcMaxClock, this->config->GetConfigValue(KipConfigValue_marikoEmcMaxClock));
CUST_WRITE_FIELD_BATCH(&table, marikoEmcVddqVolt, this->config->GetConfigValue(KipConfigValue_marikoEmcVddqVolt));
CUST_WRITE_FIELD_BATCH(&table, emcDvbShift, this->config->GetConfigValue(KipConfigValue_emcDvbShift));
CUST_WRITE_FIELD_BATCH(&table, t1_tRCD, this->config->GetConfigValue(KipConfigValue_t1_tRCD));
CUST_WRITE_FIELD_BATCH(&table, t2_tRP, this->config->GetConfigValue(KipConfigValue_t2_tRP));
CUST_WRITE_FIELD_BATCH(&table, t3_tRAS, this->config->GetConfigValue(KipConfigValue_t3_tRAS));
CUST_WRITE_FIELD_BATCH(&table, t4_tRRD, this->config->GetConfigValue(KipConfigValue_t4_tRRD));
CUST_WRITE_FIELD_BATCH(&table, t5_tRFC, this->config->GetConfigValue(KipConfigValue_t5_tRFC));
CUST_WRITE_FIELD_BATCH(&table, t6_tRTW, this->config->GetConfigValue(KipConfigValue_t6_tRTW));
CUST_WRITE_FIELD_BATCH(&table, t7_tWTR, this->config->GetConfigValue(KipConfigValue_t7_tWTR));
CUST_WRITE_FIELD_BATCH(&table, t8_tREFI, this->config->GetConfigValue(KipConfigValue_t8_tREFI));
CUST_WRITE_FIELD_BATCH(&table, mem_burst_read_latency, this->config->GetConfigValue(KipConfigValue_mem_burst_read_latency));
CUST_WRITE_FIELD_BATCH(&table, mem_burst_write_latency, this->config->GetConfigValue(KipConfigValue_mem_burst_write_latency));
CUST_WRITE_FIELD_BATCH(&table, eristaCpuUV, this->config->GetConfigValue(KipConfigValue_eristaCpuUV));
CUST_WRITE_FIELD_BATCH(&table, eristaCpuVmin, this->config->GetConfigValue(KipConfigValue_eristaCpuVmin));
CUST_WRITE_FIELD_BATCH(&table, eristaCpuMaxVolt, this->config->GetConfigValue(KipConfigValue_eristaCpuMaxVolt));
CUST_WRITE_FIELD_BATCH(&table, eristaCpuUnlock, this->config->GetConfigValue(KipConfigValue_eristaCpuUnlock));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuUVLow, this->config->GetConfigValue(KipConfigValue_marikoCpuUVLow));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuUVHigh, this->config->GetConfigValue(KipConfigValue_marikoCpuUVHigh));
CUST_WRITE_FIELD_BATCH(&table, tableConf, this->config->GetConfigValue(KipConfigValue_tableConf));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuLowVmin, this->config->GetConfigValue(KipConfigValue_marikoCpuLowVmin));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuHighVmin, this->config->GetConfigValue(KipConfigValue_marikoCpuHighVmin));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuMaxVolt, this->config->GetConfigValue(KipConfigValue_marikoCpuMaxVolt));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuMaxClock, this->config->GetConfigValue(KipConfigValue_marikoCpuMaxClock));
CUST_WRITE_FIELD_BATCH(&table, eristaCpuBoostClock, this->config->GetConfigValue(KipConfigValue_eristaCpuBoostClock));
CUST_WRITE_FIELD_BATCH(&table, marikoCpuBoostClock, this->config->GetConfigValue(KipConfigValue_marikoCpuBoostClock));
CUST_WRITE_FIELD_BATCH(&table, eristaGpuUV, this->config->GetConfigValue(KipConfigValue_eristaGpuUV));
CUST_WRITE_FIELD_BATCH(&table, eristaGpuVmin, this->config->GetConfigValue(KipConfigValue_eristaGpuVmin));
CUST_WRITE_FIELD_BATCH(&table, marikoGpuUV, this->config->GetConfigValue(KipConfigValue_marikoGpuUV));
CUST_WRITE_FIELD_BATCH(&table, marikoGpuVmin, this->config->GetConfigValue(KipConfigValue_marikoGpuVmin));
CUST_WRITE_FIELD_BATCH(&table, marikoGpuVmax, this->config->GetConfigValue(KipConfigValue_marikoGpuVmax));
CUST_WRITE_FIELD_BATCH(&table, commonGpuVoltOffset, this->config->GetConfigValue(KipConfigValue_commonGpuVoltOffset));
CUST_WRITE_FIELD_BATCH(&table, gpuSpeedo, this->config->GetConfigValue(KipConfigValue_gpuSpeedo));
for (int i = 0; i < 24; i++) {
table.marikoGpuVoltArray[i] = this->config->GetConfigValue((SysClkConfigValue)(KipConfigValue_g_volt_76800 + i));
}
for (int i = 0; i < 27; i++) {
table.eristaGpuVoltArray[i] = this->config->GetConfigValue((SysClkConfigValue)(KipConfigValue_g_volt_e_76800 + i));
}
CUST_WRITE_FIELD_BATCH(&table, t6_tRTW_fine_tune, this->config->GetConfigValue(KipConfigValue_t6_tRTW_fine_tune));
CUST_WRITE_FIELD_BATCH(&table, t7_tWTR_fine_tune, this->config->GetConfigValue(KipConfigValue_t7_tWTR_fine_tune));
if (!cust_write_table("sdmc:/atmosphere/kips/hoc.kip", &table)) {
FileUtils::LogLine("[clock_manager] Failed to write KIP file");
writeNotification("Horizon OC\nKip write failed");
}
SysClkConfigValueList configValues;
this->config->GetConfigValues(&configValues);
configValues.values[KipCrc32] = (u64)checksum_file("sdmc:/atmosphere/kips/hoc.kip"); // write checksum
if (this->config->SetConfigValues(&configValues, false)) {
FileUtils::LogLine("[clock_manager] Successfully loaded KIP data into config");
} else {
FileUtils::LogLine("[clock_manager] Warning: Failed to set config values from KIP");
writeNotification("Horizon OC\nKip config set failed");
}
}
// I know this is very hacky, but the config system in the sysmodule doesn't really support writing
void ClockManager::GetKipData() {
FILE* fp;
if(this->config->Refresh()) {
fp = fopen("sdmc:/atmosphere/kips/hoc.kip", "r");
if (fp == NULL) {
writeNotification("Horizon OC\nKip opening failed");
kipAvailable = false;
return;
} else {
kipAvailable = true;
fclose(fp);
}
SysClkConfigValueList configValues;
this->config->GetConfigValues(&configValues);
CustomizeTable table;
if (!cust_read_and_cache("sdmc:/atmosphere/kips/hoc.kip", &table)) {
FileUtils::LogLine("[clock_manager] Failed to read KIP file for GetKipData");
writeNotification("Horizon OC\nKip read failed");
return;
}
if((u64)checksum_file("sdmc:/atmosphere/kips/hoc.kip") != this->config->GetConfigValue(KipCrc32) && !this->config->GetConfigValue(HocClkConfigValue_IsFirstLoad)) {
SetKipData();
writeNotification("Horizon OC\nKIP has been updated");
writeNotification("Horizon OC\nPlease reboot your console");
writeNotification("Horizon OC\nto complete the update");
return;
}
if(this->config->GetConfigValue(HocClkConfigValue_IsFirstLoad) == true) {
configValues.values[HocClkConfigValue_IsFirstLoad] = (u64)false;
writeNotification("Horizon OC has been installed");
}
static bool writeBootConfigValues = true;
configValues.values[KipCrc32] = (u64)checksum_file("sdmc:/atmosphere/kips/hoc.kip"); // write checksum
if(writeBootConfigValues) {
writeBootConfigValues = false;
// initialConfigValues[KipConfigValue_mtcConf] = cust_get_mtc_conf(&table);
initialConfigValues[KipConfigValue_hpMode] = cust_get_hp_mode(&table);
initialConfigValues[KipConfigValue_commonEmcMemVolt] = cust_get_common_emc_volt(&table);
initialConfigValues[KipConfigValue_eristaEmcMaxClock] = cust_get_erista_emc_max(&table);
initialConfigValues[KipConfigValue_eristaEmcMaxClock1] = cust_get_erista_emc_max1(&table);
initialConfigValues[KipConfigValue_eristaEmcMaxClock2] = cust_get_erista_emc_max2(&table);
initialConfigValues[KipConfigValue_marikoEmcMaxClock] = cust_get_mariko_emc_max(&table);
initialConfigValues[KipConfigValue_marikoEmcVddqVolt] = cust_get_mariko_emc_vddq(&table);
initialConfigValues[KipConfigValue_emcDvbShift] = cust_get_emc_dvb_shift(&table);
initialConfigValues[KipConfigValue_t1_tRCD] = cust_get_tRCD(&table);
initialConfigValues[KipConfigValue_t2_tRP] = cust_get_tRP(&table);
initialConfigValues[KipConfigValue_t3_tRAS] = cust_get_tRAS(&table);
initialConfigValues[KipConfigValue_t4_tRRD] = cust_get_tRRD(&table);
initialConfigValues[KipConfigValue_t5_tRFC] = cust_get_tRFC(&table);
initialConfigValues[KipConfigValue_t6_tRTW] = cust_get_tRTW(&table);
initialConfigValues[KipConfigValue_t7_tWTR] = cust_get_tWTR(&table);
initialConfigValues[KipConfigValue_t8_tREFI] = cust_get_tREFI(&table);
initialConfigValues[KipConfigValue_mem_burst_read_latency] = cust_get_burst_read_lat(&table);
initialConfigValues[KipConfigValue_mem_burst_write_latency] = cust_get_burst_write_lat(&table);
initialConfigValues[KipConfigValue_eristaCpuUV] = cust_get_erista_cpu_uv(&table);
initialConfigValues[KipConfigValue_eristaCpuVmin] = cust_get_eristaCpuVmin(&table);
initialConfigValues[KipConfigValue_eristaCpuMaxVolt] = cust_get_erista_cpu_max_volt(&table);
initialConfigValues[KipConfigValue_eristaCpuUnlock] = cust_get_eristaCpuUnlock(&table);
initialConfigValues[KipConfigValue_marikoCpuUVLow] = cust_get_mariko_cpu_uv_low(&table);
initialConfigValues[KipConfigValue_marikoCpuUVHigh] = cust_get_mariko_cpu_uv_high(&table);
initialConfigValues[KipConfigValue_tableConf] = cust_get_table_conf(&table);
initialConfigValues[KipConfigValue_marikoCpuLowVmin] = cust_get_mariko_cpu_low_vmin(&table);
initialConfigValues[KipConfigValue_marikoCpuHighVmin] = cust_get_mariko_cpu_high_vmin(&table);
initialConfigValues[KipConfigValue_marikoCpuMaxVolt] = cust_get_mariko_cpu_max_volt(&table);
initialConfigValues[KipConfigValue_marikoCpuMaxClock] = cust_get_marikoCpuMaxClock(&table);
initialConfigValues[KipConfigValue_eristaCpuBoostClock] = cust_get_erista_cpu_boost(&table);
initialConfigValues[KipConfigValue_marikoCpuBoostClock] = cust_get_mariko_cpu_boost(&table);
initialConfigValues[KipConfigValue_eristaGpuUV] = cust_get_erista_gpu_uv(&table);
initialConfigValues[KipConfigValue_eristaGpuVmin] = cust_get_erista_gpu_vmin(&table);
initialConfigValues[KipConfigValue_marikoGpuUV] = cust_get_mariko_gpu_uv(&table);
initialConfigValues[KipConfigValue_marikoGpuVmin] = cust_get_mariko_gpu_vmin(&table);
initialConfigValues[KipConfigValue_marikoGpuVmax] = cust_get_mariko_gpu_vmax(&table);
initialConfigValues[KipConfigValue_commonGpuVoltOffset] = cust_get_common_gpu_offset(&table);
initialConfigValues[KipConfigValue_gpuSpeedo] = cust_get_gpu_speedo(&table);
initialConfigValues[KipConfigValue_t6_tRTW_fine_tune] = cust_get_tRTW_fine_tune(&table);
initialConfigValues[KipConfigValue_t7_tWTR_fine_tune] = cust_get_tWTR_fine_tune(&table);
}
// configValues.values[KipConfigValue_mtcConf] = cust_get_mtc_conf(&table);
configValues.values[KipConfigValue_hpMode] = cust_get_hp_mode(&table);
configValues.values[KipConfigValue_commonEmcMemVolt] = cust_get_common_emc_volt(&table);
configValues.values[KipConfigValue_eristaEmcMaxClock] = cust_get_erista_emc_max(&table);
configValues.values[KipConfigValue_eristaEmcMaxClock1] = cust_get_erista_emc_max1(&table);
configValues.values[KipConfigValue_eristaEmcMaxClock2] = cust_get_erista_emc_max2(&table);
configValues.values[KipConfigValue_marikoEmcMaxClock] = cust_get_mariko_emc_max(&table);
configValues.values[KipConfigValue_marikoEmcVddqVolt] = cust_get_mariko_emc_vddq(&table);
configValues.values[KipConfigValue_emcDvbShift] = cust_get_emc_dvb_shift(&table);
configValues.values[KipConfigValue_t1_tRCD] = cust_get_tRCD(&table);
configValues.values[KipConfigValue_t2_tRP] = cust_get_tRP(&table);
configValues.values[KipConfigValue_t3_tRAS] = cust_get_tRAS(&table);
configValues.values[KipConfigValue_t4_tRRD] = cust_get_tRRD(&table);
configValues.values[KipConfigValue_t5_tRFC] = cust_get_tRFC(&table);
configValues.values[KipConfigValue_t6_tRTW] = cust_get_tRTW(&table);
configValues.values[KipConfigValue_t7_tWTR] = cust_get_tWTR(&table);
configValues.values[KipConfigValue_t8_tREFI] = cust_get_tREFI(&table);
configValues.values[KipConfigValue_mem_burst_read_latency] = cust_get_burst_read_lat(&table);
configValues.values[KipConfigValue_mem_burst_write_latency] = cust_get_burst_write_lat(&table);
configValues.values[KipConfigValue_eristaCpuUV] = cust_get_erista_cpu_uv(&table);
configValues.values[KipConfigValue_eristaCpuVmin] = cust_get_eristaCpuVmin(&table);
configValues.values[KipConfigValue_eristaCpuMaxVolt] = cust_get_erista_cpu_max_volt(&table);
configValues.values[KipConfigValue_eristaCpuUnlock] = cust_get_eristaCpuUnlock(&table);
configValues.values[KipConfigValue_marikoCpuUVLow] = cust_get_mariko_cpu_uv_low(&table);
configValues.values[KipConfigValue_marikoCpuUVHigh] = cust_get_mariko_cpu_uv_high(&table);
configValues.values[KipConfigValue_tableConf] = cust_get_table_conf(&table);
configValues.values[KipConfigValue_marikoCpuLowVmin] = cust_get_mariko_cpu_low_vmin(&table);
configValues.values[KipConfigValue_marikoCpuHighVmin] = cust_get_mariko_cpu_high_vmin(&table);
configValues.values[KipConfigValue_marikoCpuMaxVolt] = cust_get_mariko_cpu_max_volt(&table);
configValues.values[KipConfigValue_marikoCpuMaxClock] = cust_get_marikoCpuMaxClock(&table);
configValues.values[KipConfigValue_eristaCpuBoostClock] = cust_get_erista_cpu_boost(&table);
configValues.values[KipConfigValue_marikoCpuBoostClock] = cust_get_mariko_cpu_boost(&table);
configValues.values[KipConfigValue_eristaGpuUV] = cust_get_erista_gpu_uv(&table);
configValues.values[KipConfigValue_eristaGpuVmin] = cust_get_erista_gpu_vmin(&table);
configValues.values[KipConfigValue_marikoGpuUV] = cust_get_mariko_gpu_uv(&table);
configValues.values[KipConfigValue_marikoGpuVmin] = cust_get_mariko_gpu_vmin(&table);
configValues.values[KipConfigValue_marikoGpuVmax] = cust_get_mariko_gpu_vmax(&table);
configValues.values[KipConfigValue_commonGpuVoltOffset] = cust_get_common_gpu_offset(&table);
configValues.values[KipConfigValue_gpuSpeedo] = Board::getSpeedo(HorizonOCSpeedo_GPU); // cust_get_gpu_speedo(&table);
for (int i = 0; i < 24; i++) {
configValues.values[KipConfigValue_g_volt_76800 + i] = cust_get_mariko_gpu_volt(&table, i);
initialConfigValues[KipConfigValue_g_volt_76800 + i] = cust_get_mariko_gpu_volt(&table, i);
}
for (int i = 0; i < 27; i++) {
configValues.values[KipConfigValue_g_volt_e_76800 + i] = cust_get_erista_gpu_volt(&table, i);
initialConfigValues[KipConfigValue_g_volt_e_76800 + i] = cust_get_erista_gpu_volt(&table, i);
}
configValues.values[KipConfigValue_t7_tWTR_fine_tune] = cust_get_tWTR_fine_tune(&table);
configValues.values[KipConfigValue_t6_tRTW_fine_tune] = cust_get_tRTW_fine_tune(&table);
// if(cust_get_cust_rev(&table) == KIP_CUST_REV)
// return;
if (sizeof(SysClkConfigValueList) <= sizeof(configValues)) {
if (this->config->SetConfigValues(&configValues, false)) {
FileUtils::LogLine("[clock_manager] Successfully loaded KIP data into config");
} else {
FileUtils::LogLine("[clock_manager] Warning: Failed to set config values from KIP");
writeNotification("Horizon OC\nKip config set failed");
}
} else {
FileUtils::LogLine("[clock_manager] Error: Config value list buffer size mismatch");
writeNotification("Horizon OC\nConfig Buffer Mismatch");
}
} else {
FileUtils::LogLine("[clock_manager] Config refresh error in GetKipData!");
writeNotification("Horizon OC\nConfig refresh failed");
}
}