dolphin/Source/Core/VideoCommon/MainBase.cpp
degasus eb310cbd1d VideoCommon: disable efb access + perf querys on cph thread
The usual way to handle this kind of request is to rise a flag which the gpu thread polls.
The gpu thread itself either generates the result or just write zeros if disabled.
After this, it rise another flag which says that this work is done.

So if disabled, we still have the cpu-gpu round trip time. This commit just returns 0 on the cpu thread
instead of playing ping pong...
2014-01-09 18:37:59 +01:00

335 lines
7.2 KiB
C++

#include "MainBase.h"
#include "VideoState.h"
#include "VideoConfig.h"
#include "RenderBase.h"
#include "FramebufferManagerBase.h"
#include "TextureCacheBase.h"
#include "VertexLoaderManager.h"
#include "CommandProcessor.h"
#include "PixelEngine.h"
#include "Atomic.h"
#include "Fifo.h"
#include "BPStructs.h"
#include "OnScreenDisplay.h"
#include "VideoBackendBase.h"
#include "ConfigManager.h"
bool s_BackendInitialized = false;
volatile u32 s_swapRequested = false;
u32 s_efbAccessRequested = false;
volatile u32 s_FifoShuttingDown = false;
std::condition_variable s_perf_query_cond;
std::mutex s_perf_query_lock;
static volatile bool s_perf_query_requested;
static volatile struct
{
u32 xfbAddr;
u32 fbWidth;
u32 fbHeight;
} s_beginFieldArgs;
static struct
{
EFBAccessType type;
u32 x;
u32 y;
u32 Data;
} s_accessEFBArgs;
static u32 s_AccessEFBResult = 0;
void VideoBackendHardware::EmuStateChange(EMUSTATE_CHANGE newState)
{
EmulatorState((newState == EMUSTATE_CHANGE_PLAY) ? true : false);
}
// Enter and exit the video loop
void VideoBackendHardware::Video_EnterLoop()
{
RunGpuLoop();
}
void VideoBackendHardware::Video_ExitLoop()
{
ExitGpuLoop();
s_FifoShuttingDown = true;
}
void VideoBackendHardware::Video_SetRendering(bool bEnabled)
{
Fifo_SetRendering(bEnabled);
}
// Run from the graphics thread (from Fifo.cpp)
void VideoFifo_CheckSwapRequest()
{
if(g_ActiveConfig.bUseXFB)
{
if (Common::AtomicLoadAcquire(s_swapRequested))
{
EFBRectangle rc;
g_renderer->Swap(s_beginFieldArgs.xfbAddr, s_beginFieldArgs.fbWidth, s_beginFieldArgs.fbHeight,rc);
Common::AtomicStoreRelease(s_swapRequested, false);
}
}
}
// Run from the graphics thread (from Fifo.cpp)
void VideoFifo_CheckSwapRequestAt(u32 xfbAddr, u32 fbWidth, u32 fbHeight)
{
if (g_ActiveConfig.bUseXFB)
{
if(Common::AtomicLoadAcquire(s_swapRequested))
{
u32 aLower = xfbAddr;
u32 aUpper = xfbAddr + 2 * fbWidth * fbHeight;
u32 bLower = s_beginFieldArgs.xfbAddr;
u32 bUpper = s_beginFieldArgs.xfbAddr + 2 * s_beginFieldArgs.fbWidth * s_beginFieldArgs.fbHeight;
if (addrRangesOverlap(aLower, aUpper, bLower, bUpper))
VideoFifo_CheckSwapRequest();
}
}
}
// Run from the CPU thread (from VideoInterface.cpp)
void VideoBackendHardware::Video_BeginField(u32 xfbAddr, u32 fbWidth, u32 fbHeight)
{
if (s_BackendInitialized && g_ActiveConfig.bUseXFB)
{
if (!SConfig::GetInstance().m_LocalCoreStartupParameter.bCPUThread)
VideoFifo_CheckSwapRequest();
s_beginFieldArgs.xfbAddr = xfbAddr;
s_beginFieldArgs.fbWidth = fbWidth;
s_beginFieldArgs.fbHeight = fbHeight;
}
}
// Run from the CPU thread (from VideoInterface.cpp)
void VideoBackendHardware::Video_EndField()
{
if (s_BackendInitialized)
{
Common::AtomicStoreRelease(s_swapRequested, true);
}
}
void VideoBackendHardware::Video_AddMessage(const char* pstr, u32 milliseconds)
{
OSD::AddMessage(pstr, milliseconds);
}
void VideoBackendHardware::Video_ClearMessages()
{
OSD::ClearMessages();
}
// Screenshot
bool VideoBackendHardware::Video_Screenshot(const char *_szFilename)
{
Renderer::SetScreenshot(_szFilename);
return true;
}
void VideoFifo_CheckEFBAccess()
{
if (Common::AtomicLoadAcquire(s_efbAccessRequested))
{
s_AccessEFBResult = g_renderer->AccessEFB(s_accessEFBArgs.type, s_accessEFBArgs.x, s_accessEFBArgs.y, s_accessEFBArgs.Data);
Common::AtomicStoreRelease(s_efbAccessRequested, false);
}
}
u32 VideoBackendHardware::Video_AccessEFB(EFBAccessType type, u32 x, u32 y, u32 InputData)
{
if (s_BackendInitialized && g_ActiveConfig.bEFBAccessEnable)
{
s_accessEFBArgs.type = type;
s_accessEFBArgs.x = x;
s_accessEFBArgs.y = y;
s_accessEFBArgs.Data = InputData;
Common::AtomicStoreRelease(s_efbAccessRequested, true);
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bCPUThread)
{
while (Common::AtomicLoadAcquire(s_efbAccessRequested) && !s_FifoShuttingDown)
//Common::SleepCurrentThread(1);
Common::YieldCPU();
}
else
VideoFifo_CheckEFBAccess();
return s_AccessEFBResult;
}
return 0;
}
static bool QueryResultIsReady()
{
return !s_perf_query_requested || s_FifoShuttingDown;
}
void VideoFifo_CheckPerfQueryRequest()
{
if (s_perf_query_requested)
{
g_perf_query->FlushResults();
{
std::lock_guard<std::mutex> lk(s_perf_query_lock);
s_perf_query_requested = false;
}
s_perf_query_cond.notify_one();
}
}
u32 VideoBackendHardware::Video_GetQueryResult(PerfQueryType type)
{
if(!g_perf_query->ShouldEmulate())
{
return 0;
}
// TODO: Is this check sane?
if (!g_perf_query->IsFlushed())
{
if (SConfig::GetInstance().m_LocalCoreStartupParameter.bCPUThread)
{
s_perf_query_requested = true;
std::unique_lock<std::mutex> lk(s_perf_query_lock);
s_perf_query_cond.wait(lk, QueryResultIsReady);
}
else
g_perf_query->FlushResults();
}
return g_perf_query->GetQueryResult(type);
}
void VideoBackendHardware::InitializeShared()
{
VideoCommon_Init();
s_swapRequested = 0;
s_efbAccessRequested = 0;
s_perf_query_requested = false;
s_FifoShuttingDown = 0;
memset((void*)&s_beginFieldArgs, 0, sizeof(s_beginFieldArgs));
memset(&s_accessEFBArgs, 0, sizeof(s_accessEFBArgs));
s_AccessEFBResult = 0;
m_invalid = false;
}
// Run from the CPU thread
void VideoBackendHardware::DoState(PointerWrap& p)
{
bool software = false;
p.Do(software);
if (p.GetMode() == PointerWrap::MODE_READ && software == true)
{
// change mode to abort load of incompatible save state.
p.SetMode(PointerWrap::MODE_VERIFY);
}
VideoCommon_DoState(p);
p.DoMarker("VideoCommon");
p.Do(s_swapRequested);
p.Do(s_efbAccessRequested);
p.Do(s_beginFieldArgs);
p.Do(s_accessEFBArgs);
p.Do(s_AccessEFBResult);
p.DoMarker("VideoBackendHardware");
// Refresh state.
if (p.GetMode() == PointerWrap::MODE_READ)
{
m_invalid = true;
RecomputeCachedArraybases();
// Clear all caches that touch RAM
// (? these don't appear to touch any emulation state that gets saved. moved to on load only.)
VertexLoaderManager::MarkAllDirty();
}
}
void VideoBackendHardware::CheckInvalidState()
{
if (m_invalid)
{
m_invalid = false;
BPReload();
TextureCache::Invalidate();
}
}
void VideoBackendHardware::PauseAndLock(bool doLock, bool unpauseOnUnlock)
{
Fifo_PauseAndLock(doLock, unpauseOnUnlock);
}
void VideoBackendHardware::RunLoop(bool enable)
{
VideoCommon_RunLoop(enable);
}
void VideoFifo_CheckAsyncRequest()
{
VideoFifo_CheckSwapRequest();
VideoFifo_CheckEFBAccess();
VideoFifo_CheckPerfQueryRequest();
}
void VideoBackendHardware::Video_GatherPipeBursted()
{
CommandProcessor::GatherPipeBursted();
}
bool VideoBackendHardware::Video_IsPossibleWaitingSetDrawDone()
{
return CommandProcessor::isPossibleWaitingSetDrawDone;
}
bool VideoBackendHardware::Video_IsHiWatermarkActive()
{
return CommandProcessor::isHiWatermarkActive;
}
void VideoBackendHardware::Video_AbortFrame()
{
CommandProcessor::AbortFrame();
}
readFn16 VideoBackendHardware::Video_CPRead16()
{
return CommandProcessor::Read16;
}
writeFn16 VideoBackendHardware::Video_CPWrite16()
{
return CommandProcessor::Write16;
}
readFn16 VideoBackendHardware::Video_PERead16()
{
return PixelEngine::Read16;
}
writeFn16 VideoBackendHardware::Video_PEWrite16()
{
return PixelEngine::Write16;
}
writeFn32 VideoBackendHardware::Video_PEWrite32()
{
return PixelEngine::Write32;
}