#include "trenderer.h"
#include "trasterfx.h"
#include <algorithm>
#include "tpredictivecachemanager.h"
//************************************************************************************************
// Preliminaries
//************************************************************************************************
class TPredictiveCacheManagerGenerator : public TRenderResourceManagerGenerator
{
public:
TPredictiveCacheManagerGenerator() : TRenderResourceManagerGenerator(true) {}
TRenderResourceManager *operator()(void)
{
return new TPredictiveCacheManager;
}
};
MANAGER_FILESCOPE_DECLARATION_DEP(
TPredictiveCacheManager,
TPredictiveCacheManagerGenerator,
TFxCacheManager::deps())
//-------------------------------------------------------------------------
TPredictiveCacheManager *TPredictiveCacheManager::instance()
{
return static_cast<TPredictiveCacheManager *>(
//TPredictiveCacheManager::gen()->getManager(TRenderer::instance())
TPredictiveCacheManager::gen()->getManager(TRenderer::renderId()));
}
//************************************************************************************************
// TPredictiveCacheManager::Imp definition
//************************************************************************************************
//=======================
// PredictionData
//-----------------------
struct PredictionData {
const ResourceDeclaration *m_decl;
int m_usageCount;
PredictionData(const ResourceDeclaration *declaration)
: m_decl(declaration), m_usageCount(1) {}
};
//============================================================================================
//=====================================
// TPredictiveCacheManager::Imp
//-------------------------------------
class TPredictiveCacheManager::Imp
{
public:
int m_renderStatus;
bool m_enabled;
std::map<TCacheResourceP, PredictionData> m_resources;
QMutex m_mutex;
public:
//Active getResource(..) callback
typedef void (TPredictiveCacheManager::Imp::*GetResourceFuncPtr)(TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData);
GetResourceFuncPtr m_getResFuncPtr;
public:
Imp()
: m_renderStatus(TRenderer::IDLE), m_getResFuncPtr(&Imp::getResourceComputing), m_enabled(TRenderer::instance().isPrecomputingEnabled()) {}
void getResourceTestRun(
TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData);
void getResourceComputing(
TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData);
};
//************************************************************************************************
// TPredictiveCacheManager methods
//************************************************************************************************
TPredictiveCacheManager::TPredictiveCacheManager()
: m_imp(new TPredictiveCacheManager::Imp())
{
}
//---------------------------------------------------------------------------
TPredictiveCacheManager::~TPredictiveCacheManager()
{
delete m_imp;
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::setMaxTileSize(int maxTileSize)
{
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::setBPP(int bpp)
{
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::getResource(
TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData)
{
if (!m_imp->m_enabled)
return;
(m_imp->*(m_imp->m_getResFuncPtr))(resource, alias, fx, frame, rs, resData);
}
//************************************************************************************************
// Notification-related functions
//************************************************************************************************
void TPredictiveCacheManager::Imp::getResourceTestRun(
TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData)
{
assert(resData && resData->m_rawData);
if (!(resData && resData->m_rawData))
//This is a very rare case. I've seen it happen once in a 'pathologic' case
//which involved affines truncation while building aliases.
//The rendering system didn't expect the truncated part 'resurface' in a
//downstream fx with a slightly different affine alias.
//TODO: Affines should be coded completely in the aliases... in a compact way though.
return;
if (!resource)
resource = TCacheResourceP(alias, true);
//Lock against concurrent threads
//QMutexLocker locker(&m_mutex); //preComputing is currently single-threaded
std::map<TCacheResourceP, PredictionData>::iterator it =
m_resources.find(resource);
if (it != m_resources.end())
it->second.m_usageCount++;
else {
//Already initializes usageCount at 1
m_resources.insert(std::make_pair(resource, PredictionData(resData))).first;
}
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::Imp::getResourceComputing(
TCacheResourceP &resource, const string &alias,
const TFxP &fx, double frame, const TRenderSettings &rs,
ResourceDeclaration *resData)
{
//If there is no declaration data, either the request can be resolved in one
//computation code (therefore it is uninteresting for us), or it was never declared.
//Anyway, return.
if (!resData)
return;
//NO! The refCount is dynamically depleted - could become 0 from n...
//assert(!(resData->m_tiles.size() == 1 && resData->m_tiles[0].m_refCount == 1));
if (!resource)
resource = TCacheResourceP(alias);
if (!resource)
return;
//Lock against concurrent threads
QMutexLocker locker(&m_mutex);
std::map<TCacheResourceP, PredictionData>::iterator it =
m_resources.find(resource);
if (it == m_resources.end())
return;
if (--it->second.m_usageCount <= 0)
m_resources.erase(it);
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::onRenderStatusStart(int renderStatus)
{
m_imp->m_renderStatus = renderStatus;
switch (renderStatus) {
case TRenderer::TESTRUN:
m_imp->m_getResFuncPtr = &TPredictiveCacheManager::Imp::getResourceTestRun;
CASE TRenderer::COMPUTING : m_imp->m_getResFuncPtr = &TPredictiveCacheManager::Imp::getResourceComputing;
}
}
//---------------------------------------------------------------------------
void TPredictiveCacheManager::onRenderStatusEnd(int renderStatus)
{
switch (renderStatus) {
case TRenderer::TESTRUN:
//All resources which have just 1 computation tile, which is also referenced
//only once, are released.
std::map<TCacheResourceP, PredictionData>::iterator it;
for (it = m_imp->m_resources.begin(); it != m_imp->m_resources.end();) {
const ResourceDeclaration *decl = it->second.m_decl;
if (decl->m_tiles.size() == 1 && decl->m_tiles[0].m_refCount == 1) {
std::map<TCacheResourceP, PredictionData>::iterator jt = it++;
m_imp->m_resources.erase(jt);
} else
it++;
}
}
}