mirror of
https://github.com/hrydgard/ppsspp.git
synced 2024-11-27 15:30:35 +00:00
527 lines
14 KiB
C++
527 lines
14 KiB
C++
// Copyright (c) 2012- PPSSPP Project.
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// This program is free software: you can redistribute it and/or modify
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// it under the terms of the GNU General Public License as published by
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// the Free Software Foundation, version 2.0 or later versions.
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// This program is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU General Public License 2.0 for more details.
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// A copy of the GPL 2.0 should have been included with the program.
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// If not, see http://www.gnu.org/licenses/
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// Official git repository and contact information can be found at
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// https://github.com/hrydgard/ppsspp and http://www.ppsspp.org/.
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#include <algorithm>
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#include <list>
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#include "Common/Serialize/Serializer.h"
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#include "Common/Serialize/SerializeFuncs.h"
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#include "Common/Serialize/SerializeList.h"
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#include "Core/CoreTiming.h"
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#include "Core/MemMapHelpers.h"
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#include "Core/Reporting.h"
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#include "Core/HLE/sceKernel.h"
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#include "Core/HLE/sceKernelInterrupt.h"
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#include "Core/HLE/sceKernelMemory.h"
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#include "Core/HLE/sceKernelVTimer.h"
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#include "Core/HLE/HLE.h"
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static int vtimerTimer = -1;
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static SceUID runningVTimer = 0;
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static std::list<SceUID> vtimers;
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struct NativeVTimer {
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SceSize_le size;
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char name[KERNELOBJECT_MAX_NAME_LENGTH+1];
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s32_le active;
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u64_le base;
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u64_le current;
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u64_le schedule;
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u32_le handlerAddr;
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u32_le commonAddr;
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};
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struct VTimer : public KernelObject {
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const char *GetName() override { return nvt.name; }
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const char *GetTypeName() override { return GetStaticTypeName(); }
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static const char *GetStaticTypeName() { return "VTimer"; }
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static u32 GetMissingErrorCode() { return SCE_KERNEL_ERROR_UNKNOWN_VTID; }
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static int GetStaticIDType() { return SCE_KERNEL_TMID_VTimer; }
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int GetIDType() const override { return SCE_KERNEL_TMID_VTimer; }
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void DoState(PointerWrap &p) override {
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auto s = p.Section("VTimer", 1, 2);
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if (!s)
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return;
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Do(p, nvt);
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if (s < 2) {
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u32 memoryPtr;
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Do(p, memoryPtr);
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}
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}
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NativeVTimer nvt;
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};
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KernelObject *__KernelVTimerObject() {
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return new VTimer;
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}
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static u64 __getVTimerRunningTime(VTimer *vt) {
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if (vt->nvt.active == 0)
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return 0;
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return CoreTiming::GetGlobalTimeUs() - vt->nvt.base;
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}
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static u64 __getVTimerCurrentTime(VTimer* vt) {
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return vt->nvt.current + __getVTimerRunningTime(vt);
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}
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static int __KernelCancelVTimer(SceUID id) {
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(id, error);
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if (!vt)
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return error;
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CoreTiming::UnscheduleEvent(vtimerTimer, id);
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vt->nvt.handlerAddr = 0;
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return 0;
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}
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static void __KernelScheduleVTimer(VTimer *vt, u64 schedule) {
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CoreTiming::UnscheduleEvent(vtimerTimer, vt->GetUID());
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vt->nvt.schedule = schedule;
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if (vt->nvt.active == 1 && vt->nvt.handlerAddr != 0) {
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// The "real" base is base + current. But when setting the time, base is important.
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// The schedule is relative to those.
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u64 cyclesIntoFuture;
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if (schedule < 250) {
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schedule = 250;
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}
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s64 goalUs = (u64)vt->nvt.base + schedule - (u64)vt->nvt.current;
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s64 minGoalUs = CoreTiming::GetGlobalTimeUs() + 250;
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if (goalUs < minGoalUs) {
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cyclesIntoFuture = usToCycles(250);
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} else {
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cyclesIntoFuture = usToCycles(goalUs - CoreTiming::GetGlobalTimeUs());
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}
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CoreTiming::ScheduleEvent(cyclesIntoFuture, vtimerTimer, vt->GetUID());
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}
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}
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static void __rescheduleVTimer(SceUID id, u32 delay) {
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(id, error);
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if (error)
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return;
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__KernelScheduleVTimer(vt, vt->nvt.schedule + delay);
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}
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class VTimerIntrHandler : public IntrHandler
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{
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static const int HANDLER_STACK_SPACE = 48;
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public:
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VTimerIntrHandler() : IntrHandler(PSP_SYSTIMER1_INTR) {}
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bool run(PendingInterrupt &pend) override {
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u32 error;
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SceUID vtimerID = vtimers.front();
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VTimer *vtimer = kernelObjects.Get<VTimer>(vtimerID, error);
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if (error)
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return false;
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// Reserve some stack space for arguments.
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u32 argArea = currentMIPS->r[MIPS_REG_SP];
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currentMIPS->r[MIPS_REG_SP] -= HANDLER_STACK_SPACE;
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Memory::Write_U64(vtimer->nvt.schedule, argArea - 16);
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Memory::Write_U64(__getVTimerCurrentTime(vtimer), argArea - 8);
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currentMIPS->pc = vtimer->nvt.handlerAddr;
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currentMIPS->r[MIPS_REG_A0] = vtimer->GetUID();
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currentMIPS->r[MIPS_REG_A1] = argArea - 16;
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currentMIPS->r[MIPS_REG_A2] = argArea - 8;
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currentMIPS->r[MIPS_REG_A3] = vtimer->nvt.commonAddr;
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runningVTimer = vtimerID;
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return true;
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}
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void handleResult(PendingInterrupt &pend) override {
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u32 result = currentMIPS->r[MIPS_REG_V0];
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currentMIPS->r[MIPS_REG_SP] += HANDLER_STACK_SPACE;
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int vtimerID = vtimers.front();
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vtimers.pop_front();
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runningVTimer = 0;
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if (result == 0)
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__KernelCancelVTimer(vtimerID);
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else
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__rescheduleVTimer(vtimerID, result);
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}
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};
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static void __KernelTriggerVTimer(u64 userdata, int cyclesLate) {
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SceUID uid = (SceUID) userdata;
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (vt) {
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vtimers.push_back(uid);
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__TriggerInterrupt(PSP_INTR_IMMEDIATE, PSP_SYSTIMER1_INTR);
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}
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}
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void __KernelVTimerDoState(PointerWrap &p) {
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auto s = p.Section("sceKernelVTimer", 1, 2);
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if (!s)
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return;
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Do(p, vtimerTimer);
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Do(p, vtimers);
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CoreTiming::RestoreRegisterEvent(vtimerTimer, "VTimer", __KernelTriggerVTimer);
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if (s >= 2)
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Do(p, runningVTimer);
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else
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runningVTimer = 0;
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}
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void __KernelVTimerInit() {
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vtimers.clear();
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__RegisterIntrHandler(PSP_SYSTIMER1_INTR, new VTimerIntrHandler());
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vtimerTimer = CoreTiming::RegisterEvent("VTimer", __KernelTriggerVTimer);
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// Intentionally starts at 0. This explains the behavior where 0 is treated differently outside a timer.
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runningVTimer = 0;
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}
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u32 sceKernelCreateVTimer(const char *name, u32 optParamAddr) {
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if (!name) {
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WARN_LOG_REPORT(SCEKERNEL, "%08x=sceKernelCreateVTimer(): invalid name", SCE_KERNEL_ERROR_ERROR);
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return SCE_KERNEL_ERROR_ERROR;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelCreateVTimer(%s, %08x)", name, optParamAddr);
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VTimer *vtimer = new VTimer;
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SceUID id = kernelObjects.Create(vtimer);
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memset(&vtimer->nvt, 0, sizeof(NativeVTimer));
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vtimer->nvt.size = sizeof(NativeVTimer);
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strncpy(vtimer->nvt.name, name, KERNELOBJECT_MAX_NAME_LENGTH);
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vtimer->nvt.name[KERNELOBJECT_MAX_NAME_LENGTH] = '\0';
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if (optParamAddr != 0) {
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u32 size = Memory::Read_U32(optParamAddr);
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if (size > 4)
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WARN_LOG_REPORT(SCEKERNEL, "sceKernelCreateVTimer(%s) unsupported options parameter, size = %d", name, size);
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}
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return id;
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}
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u32 sceKernelDeleteVTimer(SceUID uid) {
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DEBUG_LOG(SCEKERNEL, "sceKernelDeleteVTimer(%08x)", uid);
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u32 error;
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VTimer* vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelDeleteVTimer(%08x)", error, uid);
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return error;
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}
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for (std::list<SceUID>::iterator it = vtimers.begin(); it != vtimers.end(); ++it) {
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if (*it == vt->GetUID()) {
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vtimers.erase(it);
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break;
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}
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}
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return kernelObjects.Destroy<VTimer>(uid);
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}
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u32 sceKernelGetVTimerBase(SceUID uid, u32 baseClockAddr) {
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DEBUG_LOG(SCEKERNEL, "sceKernelGetVTimerBase(%08x, %08x)", uid, baseClockAddr);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelGetVTimerBase(%08x, %08x)", error, uid, baseClockAddr);
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return error;
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}
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if (Memory::IsValidAddress(baseClockAddr))
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Memory::Write_U64(vt->nvt.base, baseClockAddr);
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return 0;
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}
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u64 sceKernelGetVTimerBaseWide(SceUID uid) {
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DEBUG_LOG(SCEKERNEL, "sceKernelGetVTimerBaseWide(%08x)", uid);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelGetVTimerBaseWide(%08x)", error, uid);
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return -1;
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}
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return vt->nvt.base;
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}
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u32 sceKernelGetVTimerTime(SceUID uid, u32 timeClockAddr) {
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DEBUG_LOG(SCEKERNEL, "sceKernelGetVTimerTime(%08x, %08x)", uid, timeClockAddr);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelGetVTimerTime(%08x, %08x)", error, uid, timeClockAddr);
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return error;
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}
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u64 time = __getVTimerCurrentTime(vt);
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if (Memory::IsValidAddress(timeClockAddr))
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Memory::Write_U64(time, timeClockAddr);
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return 0;
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}
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u64 sceKernelGetVTimerTimeWide(SceUID uid) {
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DEBUG_LOG(SCEKERNEL, "sceKernelGetVTimerTimeWide(%08x)", uid);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelGetVTimerTimeWide(%08x)", error, uid);
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return -1;
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}
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u64 time = __getVTimerCurrentTime(vt);
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return time;
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}
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static u64 __KernelSetVTimer(VTimer *vt, u64 time) {
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u64 current = __getVTimerCurrentTime(vt);
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vt->nvt.current = time - __getVTimerRunningTime(vt);
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// Run if we're now passed the schedule.
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__KernelScheduleVTimer(vt, vt->nvt.schedule);
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return current;
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}
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u32 sceKernelSetVTimerTime(SceUID uid, u32 timeClockAddr) {
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DEBUG_LOG(SCEKERNEL, "sceKernelSetVTimerTime(%08x, %08x)", uid, timeClockAddr);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelSetVTimerTime(%08x, %08x)", error, uid, timeClockAddr);
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return error;
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}
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u64 time = Memory::Read_U64(timeClockAddr);
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if (Memory::IsValidAddress(timeClockAddr))
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Memory::Write_U64(__KernelSetVTimer(vt, time), timeClockAddr);
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return 0;
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}
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u64 sceKernelSetVTimerTimeWide(SceUID uid, u64 timeClock) {
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if (__IsInInterrupt()) {
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WARN_LOG(SCEKERNEL, "sceKernelSetVTimerTimeWide(%08x, %llu): in interrupt", uid, timeClock);
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return -1;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelSetVTimerTimeWide(%08x, %llu)", uid, timeClock);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error || vt == NULL) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelSetVTimerTimeWide(%08x, %llu)", error, uid, timeClock);
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return -1;
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}
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return __KernelSetVTimer(vt, timeClock);
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}
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static void __startVTimer(VTimer *vt) {
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vt->nvt.active = 1;
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vt->nvt.base = CoreTiming::GetGlobalTimeUs();
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if (vt->nvt.handlerAddr != 0)
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__KernelScheduleVTimer(vt, vt->nvt.schedule);
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}
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u32 sceKernelStartVTimer(SceUID uid) {
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hleEatCycles(12200);
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if (uid == runningVTimer) {
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WARN_LOG(SCEKERNEL, "sceKernelStartVTimer(%08x): invalid vtimer", uid);
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return SCE_KERNEL_ERROR_ILLEGAL_VTID;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelStartVTimer(%08x)", uid);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (vt) {
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if (vt->nvt.active != 0)
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return 1;
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__startVTimer(vt);
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return 0;
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}
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return error;
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}
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static void __stopVTimer(VTimer *vt) {
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// This increases (__getVTimerCurrentTime includes nvt.current.)
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vt->nvt.current = __getVTimerCurrentTime(vt);
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vt->nvt.active = 0;
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vt->nvt.base = 0;
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}
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u32 sceKernelStopVTimer(SceUID uid) {
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if (uid == runningVTimer) {
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WARN_LOG(SCEKERNEL, "sceKernelStopVTimer(%08x): invalid vtimer", uid);
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return SCE_KERNEL_ERROR_ILLEGAL_VTID;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelStopVTimer(%08x)", uid);
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (vt) {
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if (vt->nvt.active == 0)
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return 0;
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__stopVTimer(vt);
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return 1;
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}
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return error;
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}
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u32 sceKernelSetVTimerHandler(SceUID uid, u32 scheduleAddr, u32 handlerFuncAddr, u32 commonAddr) {
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hleEatCycles(900);
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if (uid == runningVTimer) {
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WARN_LOG(SCEKERNEL, "sceKernelSetVTimerHandler(%08x, %08x, %08x, %08x): invalid vtimer", uid, scheduleAddr, handlerFuncAddr, commonAddr);
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return SCE_KERNEL_ERROR_ILLEGAL_VTID;
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}
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelSetVTimerHandler(%08x, %08x, %08x, %08x)", error, uid, scheduleAddr, handlerFuncAddr, commonAddr);
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return error;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelSetVTimerHandler(%08x, %08x, %08x, %08x)", uid, scheduleAddr, handlerFuncAddr, commonAddr);
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hleEatCycles(2000);
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u64 schedule = Memory::Read_U64(scheduleAddr);
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vt->nvt.handlerAddr = handlerFuncAddr;
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if (handlerFuncAddr) {
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vt->nvt.commonAddr = commonAddr;
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__KernelScheduleVTimer(vt, schedule);
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} else {
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__KernelScheduleVTimer(vt, vt->nvt.schedule);
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}
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return 0;
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}
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u32 sceKernelSetVTimerHandlerWide(SceUID uid, u64 schedule, u32 handlerFuncAddr, u32 commonAddr) {
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hleEatCycles(900);
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if (uid == runningVTimer) {
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WARN_LOG(SCEKERNEL, "sceKernelSetVTimerHandlerWide(%08x, %llu, %08x, %08x): invalid vtimer", uid, schedule, handlerFuncAddr, commonAddr);
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return SCE_KERNEL_ERROR_ILLEGAL_VTID;
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}
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u32 error;
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VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
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if (error) {
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WARN_LOG(SCEKERNEL, "%08x=sceKernelSetVTimerHandlerWide(%08x, %llu, %08x, %08x)", error, uid, schedule, handlerFuncAddr, commonAddr);
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return error;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelSetVTimerHandlerWide(%08x, %llu, %08x, %08x)", uid, schedule, handlerFuncAddr, commonAddr);
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vt->nvt.handlerAddr = handlerFuncAddr;
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if (handlerFuncAddr) {
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vt->nvt.commonAddr = commonAddr;
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__KernelScheduleVTimer(vt, schedule);
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} else {
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__KernelScheduleVTimer(vt, vt->nvt.schedule);
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}
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return 0;
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}
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u32 sceKernelCancelVTimerHandler(SceUID uid) {
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if (uid == runningVTimer) {
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WARN_LOG(SCEKERNEL, "sceKernelCancelVTimerHandler(%08x): invalid vtimer", uid);
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return SCE_KERNEL_ERROR_ILLEGAL_VTID;
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}
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DEBUG_LOG(SCEKERNEL, "sceKernelCancelVTimerHandler(%08x)", uid);
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//__cancelVTimer checks if uid is valid
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return __KernelCancelVTimer(uid);
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}
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u32 sceKernelReferVTimerStatus(SceUID uid, u32 statusAddr) {
|
|
DEBUG_LOG(SCEKERNEL, "sceKernelReferVTimerStatus(%08x, %08x)", uid, statusAddr);
|
|
|
|
u32 error;
|
|
VTimer *vt = kernelObjects.Get<VTimer>(uid, error);
|
|
|
|
if (error) {
|
|
WARN_LOG(SCEKERNEL, "%08x=sceKernelReferVTimerStatus(%08x, %08x)", error, uid, statusAddr);
|
|
return error;
|
|
}
|
|
|
|
if (Memory::IsValidAddress(statusAddr)) {
|
|
NativeVTimer status = vt->nvt;
|
|
u32 size = Memory::Read_U32(statusAddr);
|
|
status.current = __getVTimerCurrentTime(vt);
|
|
Memory::Memcpy(statusAddr, &status, std::min(size, (u32)sizeof(status)), "VTimerStatus");
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
// Not sure why this is exposed...
|
|
void _sceKernelReturnFromTimerHandler() {
|
|
ERROR_LOG_REPORT(SCEKERNEL,"_sceKernelReturnFromTimerHandler - should not be called!");
|
|
}
|