int sc_main(int, char **)
{
sc_signal<bool> a, b, f;
sc_clock clk("Clk", 20, SC_NS); // 时钟周期为 20ns
// 分别定义模块 NAND 和 TB 的实例,并通过局部变量(如 a、b)将这两个实例连接起来
nand NAND("NAND");
NAND.A(a);
NAND.B(b);
NAND.F(f);
tb TB("TB");
TB.clk(clk);
TB.a(a);
TB.b(b);
TB.f(f);
// 生成仿真结果波形文件
sc_trace_file *tf = sc_create_vcd_trace_file("NAND");
sc_trace(tf, NAND.A, "A");
sc_trace(tf, NAND.B, "B");
sc_trace(tf, NAND.F, "F");
sc_trace(tf, TB.clk, "CLK");
sc_start(200, SC_NS); // 仿真时长 200ns
sc_close_vcd_trace_file(tf);
return 0;
}
int sc_main(int ac, char *av[])
{
sc_clock clock("Clock", CLOCK_PERIOD, SC_NS, DUTY_CYCLE, 0, SC_NS);
sc_signal<bool> reset_sig;
sc_signal<int> i1;
sc_signal<int> i2;
sc_signal<int> i3;
sc_signal<int> i4;
sc_signal<int> i5;
sc_signal<bool> cont1;
sc_signal<bool> cont2;
sc_signal<bool> cont3;
sc_signal<int> o1;
sc_signal<int> o2;
sc_signal<int> o3;
sc_signal<int> o4;
sc_signal<int> o5;
test TEST ("TEST", clock, reset_sig, i1, i2, i3, i4, i5,
cont1, cont2, cont3, o1, o2, o3, o4, o5);
tb TB ("TB", clock, reset_sig, i1, i2, i3, i4, i5,
cont1, cont2, cont3, o1, o2, o3, o4, o5);
// Simulation Run Control
sc_start();
return 0;
}
//*********************************
//zwróæ wartoœæ indeksu do tabelek z temperaturami na podstawie bie¿¹cego czasu gt_Time
uint8_t TempBuffCurrIdx(uint8_t pi_BuffType) {
uint16_t vi_Idx;
#if TEMP_USE_BUFF
uint16_t vi_DayNo = TimeGetDayNo(gt_CurrTime[TDay],gt_CurrTime[TMonth],gt_CurrTime[TYear]);
#endif
switch (pi_BuffType) {
case TEMP_BUFF12m: vi_Idx = (gt_CurrTime[THour]*5)+(gt_CurrTime[TMin]/12); break;
#ifdef TEMP_BUFF1h5
case TEMP_BUFF1h5: vi_Idx = gt_CurrTime[TWeekDay]*16+(gt_CurrTime[THour]*2+gt_CurrTime[TMin]/30)/3; break;
#endif
#ifdef TEMP_BUFF6h
case TEMP_BUFF6h: vi_Idx = vi_DayNo*4+gt_CurrTime[THour]/4; break;
#endif
#ifdef TEMP_BUFF1D
case TEMP_BUFF1D: vi_Idx = vi_DayNo; break;
#endif
#ifdef TEMP_BUFF1W
case TEMP_BUFF1W: vi_Idx = (vi_DayNo-2/*TimeGetDayNo(3,1,00)*//*poniedzia³ek*/)/7; break;
#endif
#ifdef TEMP_BUFF1M
case TEMP_BUFF1M: vi_Idx = gt_CurrTime[TYear]*12+gt_CurrTime[TMonth]; break;
#endif
#ifdef TEMP_BUFF3M
case TEMP_BUFF3M: vi_Idx = gt_CurrTime[TYear]*4+TimeSeason(gt_CurrTime[TDay],gt_CurrTime[TMonth],gt_CurrTime[TYear]); break;
#endif
default: case TEMP_BUFF24m: vi_Idx = ((gt_CurrTime[THour]*5)+(gt_CurrTime[TMin]/12))/2; break;
}
return TruncIdx16(vi_Idx,TB(pi_BuffType,Size));
} //TempBuffCurrIdx
void UInputTouchDelegateBinding::BindToInputComponent(UInputComponent* InputComponent) const
{
TArray<FInputTouchBinding> BindsToAdd;
for (int32 BindIndex=0; BindIndex<InputTouchDelegateBindings.Num(); ++BindIndex)
{
const FBlueprintInputTouchDelegateBinding& Binding = InputTouchDelegateBindings[BindIndex];
FInputTouchBinding TB( Binding.InputKeyEvent );
TB.bConsumeInput = Binding.bConsumeInput;
TB.bExecuteWhenPaused = Binding.bExecuteWhenPaused;
TB.TouchDelegate.BindDelegate(InputComponent->GetOwner(), Binding.FunctionNameToBind);
if (Binding.bOverrideParentBinding)
{
for (int32 ExistingIndex = InputComponent->TouchBindings.Num() - 1; ExistingIndex >= 0; --ExistingIndex)
{
if (InputComponent->TouchBindings[ExistingIndex].KeyEvent != TB.KeyEvent)
{
InputComponent->TouchBindings.RemoveAt(ExistingIndex);
}
}
}
// To avoid binds in the same layer being removed by the parent override temporarily put them in this array and add later
BindsToAdd.Add(TB);
}
for (int32 Index=0; Index < BindsToAdd.Num(); ++Index)
{
InputComponent->TouchBindings.Add(BindsToAdd[Index]);
}
}
//*********************************
//zwróæ wartoœæ temperatury jako obliczenie z buforów z mniejsz¹ kompresj¹ czasow¹
void TempBuffGetCurr(
uint8_t pi_BuffType //>12m
,int16_t pt_Temps[]
) {
uint8_t vi_SubBuffType;
int16_t vi_FirstIdx;
uint8_t vi_Idx;
switch (pi_BuffType) {
#ifdef TEMP_BUFF1h5
case TEMP_BUFF1h5: vi_SubBuffType = TEMP_BUFF12m; vi_FirstIdx = ((gt_TempBuffsIdx[TEMP_BUFF12m]*2)-(gt_TempBuffsIdx[TEMP_BUFF12m]*2)%15)/2; break;
#endif
#ifdef TEMP_BUFF6h
case TEMP_BUFF6h: vi_SubBuffType = TEMP_BUFF12m; vi_FirstIdx = gt_TempBuffsIdx[TEMP_BUFF12m]-gt_TempBuffsIdx[TEMP_BUFF12m]%30; break;
#endif
#ifdef TEMP_BUFF1D
case TEMP_BUFF1D: vi_SubBuffType = TEMP_BUFF12m; vi_FirstIdx = 0; break;
#endif
#ifdef TEMP_BUFF1W
case TEMP_BUFF1W: vi_SubBuffType = TEMP_BUFF1D; vi_FirstIdx = gt_TempBuffsIdx[TEMP_BUFF1D]-(gt_Temp1dLastDate[TDay+1]+6)%7; break;
#endif
#ifdef TEMP_BUFF1M
case TEMP_BUFF1M: vi_SubBuffType = TEMP_BUFF1D; vi_FirstIdx = TimeGetDayNo(1,gt_Temp1dLastDate[TMonth],gt_Temp1dLastDate[TYear]); break;
#endif
#ifdef TEMP_BUFF3M
case TEMP_BUFF3M:
vi_SubBuffType = TEMP_BUFF1D;
uint8_t vt_Time[TDay+1];
vt_Time[TYear] = gt_Temp1dLastDate[TYear];
vt_Time[TMonth] = gt_Temp1dLastDate[TMonth];
vt_Time[TDay] = gt_Temp1dLastDate[TDay];
TimeSeasonFirstDay(vt_Time);
vi_FirstIdx = TimeGetDayNo(vt_Time[TDay],vt_Time[TMonth],vt_Time[TYear]);
break;
#endif
default: vi_SubBuffType = 0; vi_FirstIdx = 0; break;
}
TempBuffGet(vi_SubBuffType,TEMP_FULLNO,TruncIdx16(vi_FirstIdx,TB(vi_SubBuffType,Size)),gt_TempBuffsIdx[vi_SubBuffType],pt_Temps,1);
if (TB(pi_BuffType,SubSize)==1) {
pt_Temps[TEMP_MIN] = pt_Temps[TEMP_AVG];
pt_Temps[TEMP_MAX] = pt_Temps[TEMP_AVG];
}
for (vi_Idx=TEMP_MIN; vi_Idx<=TEMP_MAX; vi_Idx++)
gt_TempBuffCurrCache[vi_Idx] = pt_Temps[vi_Idx];
} //TempBuffGetCurr
int main()
{
int x = 0xff;
printf("%d \n",T(x,16));
TB(x);//将x转化为二进制数
printf("\n");
return 0;
}
int TB(int m)
{
if(m>0)
{
TB(m/2);
printf("%d ",m%2);
}
else
return;
}
int sc_main(int, char **)
{
sc_signal<sc_uint<ENABLESIZE> > en_n;
sc_signal<sc_uint<INPUTSIZE> > dataIn;
sc_signal<sc_uint<SELECTSIZE> > selIn;
sc_signal<sc_uint<OUTPUTSIZE> > dataOut;
sc_signal<sc_uint<OUTPUTSIZE> > flag;
sc_clock clk("Clk", 20, SC_NS);
// Connect modules ------------------------------------------
mux_8_1 MUX_8_1("MUX_8_1");
MUX_8_1.en_n(en_n);
MUX_8_1.dataIn(dataIn);
MUX_8_1.selIn(selIn);
MUX_8_1.dataOut(dataOut);
MUX_8_1.flag(flag);
tb TB("TB");
TB.clk(clk);
TB.en_n(en_n);
TB.dataIn(dataIn);
TB.selIn(selIn);
TB.dataOut(dataOut);
TB.flag(flag);
// Initialize keys ------------------------------------------
cout << "Setting up FHEW" << endl;
FHEW::Setup();
cout << "Generating secret key ... " << endl;
//LWE::SecretKey LWEsk;
LWE::KeyGen(LWEsk);
cout << "Done." << endl;
cout << "Generating evaluation key ... this may take a while ... " << endl;
//FHEW::EvalKey Ek;
FHEW::KeyGen(&Ek, LWEsk);
cout << "Done." << endl << endl;
// Create trace files ----------------------------------------
sc_trace_file *tf = sc_create_vcd_trace_file("Mux_8_1");
sc_trace(tf, MUX_8_1.en_n, "en_n");
sc_trace(tf, MUX_8_1.dataIn, "dataIn");
sc_trace(tf, MUX_8_1.selIn, "selIn");
sc_trace(tf, MUX_8_1.dataOut, "dataOut");
sc_trace(tf, MUX_8_1.flag, "flag");
sc_trace(tf, TB.clk, "CLK");
sc_start(400, SC_NS);
sc_close_vcd_trace_file(tf);
return 0;
}
//*********************************
//pobierz temperaturê z bie¿¹cych odczytów
int16_t TempGet(
uint8_t pi_Sensor //numer termometru
,uint8_t pi_TempType //TEMP_TICK/TEMP_CURR/TEMP_MIN/TEMP_AVG/TEMP_MAX
) {
int16_t vt_Temps[TEMP_MAX+1];
if (pi_TempType&0x10) {
uint8_t vi_sreg = SREG;
cli();
if (pi_TempType==TEMP_TICK)
vt_Temps[0] = gt_TempsVar[pi_Sensor].Tick.I12.I12;
else
vt_Temps[0] = gt_TempsVar[pi_Sensor].Curr.I12.I12;
SREG = vi_sreg;
pi_TempType = 0;
}
else
TempBuffGet(TEMP_BUFF12m,pi_Sensor,0,(pi_Sensor==TEMP_FULLNO)?TB(TEMP_BUFF12m,Size)-1:TEMP_12MSIZE-1,vt_Temps,1);
return vt_Temps[pi_TempType];
} //TempGet
int fast_hgt2(suf_t *ISA, suf_t *SA, uchar *T, suf_t *H, i64 n)
{
i64 p,q,h,i,r;
FILE *f;
int w,j;
int CtoB[SIGMA+1], BtoC[SIGMA+1], C[SIGMA+1];
for (i=0; i<=SIGMA; i++) C[i] = 0;
for (i=0; i<n; i++) C[T[i]+1] = 1;
C[0] = 1;
CtoB[-1+1] = 0; BtoC[0] = -1;
r = 1; // 出現する文字の数
for (i=0; i<SIGMA; i++) {
if (C[i+1]>0) { // 文字 i が T に出現
CtoB[i+1] = r; // 文字 i が r にマップされる
BtoC[r] = i; // r の元の文字は i ($ は -1)
r++;
}
}
w = blog(r)+1; // r 個の文字を格納するのに必要なビット数
printf("w = %d\n",w);
for (i=0; i<r; i++) {
printf("%3d (%c) -> ",BtoC[i],isprint(BtoC[i])?BtoC[i]:' ');
for (j=0; j<w; j++) putchar('0' + ((i>>(w-1-j))&1));
printf("\n");
}
for (i=0; i<=n; i++) ISA[SA[i]] = i;
f = fopen("output.hb","wb");
h = 0;
for (p=0; p<=n; p++) {
int c1,c2;
r = 0;
i = ISA[p];
// printf("isa[%ld] = %ld\n",p,i);
if (i == 0) {
H[i] = 0;
} else {
q = SA[i-1];
// printf("h = %ld cmp T[%ld] T[%ld]\n",h,p+h,q+h);
if (h == 0) {
while ((p+h < n) && (q+h < n) && (T[p+h] == T[q+h])) h++;
if (p+h < n) c1 = CtoB[T[p+h]+1]; else c1 = 0;
if (q+h < n) c2 = CtoB[T[q+h]+1]; else c2 = 0;
while (r < w && TB(c1,r,w) == TB(c2,r,w)) r++;
} else {
h--;
while ((p+h < n) && (q+h < n) && (T[p+h] == T[q+h])) h++;
if (p+h < n) c1 = CtoB[T[p+h]+1]; else c1 = 0;
if (q+h < n) c2 = CtoB[T[q+h]+1]; else c2 = 0;
while (r < w && TB(c1,r,w) == TB(c2,r,w)) r++;
}
H[i] = h * w + r;
// printf("H[%ld] = %ld\n",i,h);
r = H[i];
while (r>0) {
fputc('1',f);
r--;
}
fputc('0',f);
}
}
fclose(f);
}
void FileList::ReadFileNames(int KeepSelection, int IgnoreVisible, int DrawMessage)
{
TPreRedrawFuncGuard preRedrawFuncGuard(PR_ReadFileNamesMsg);
TaskBar TB(false);
strOriginalCurDir=strCurDir;
if (!IsVisible() && !IgnoreVisible)
{
UpdateRequired=TRUE;
UpdateRequiredMode=KeepSelection;
return;
}
UpdateRequired=FALSE;
AccessTimeUpdateRequired=FALSE;
DizRead=FALSE;
FAR_FIND_DATA_EX fdata;
FileListItem *CurPtr=0,**OldData=0;
string strCurName, strNextCurName;
int OldFileCount=0;
StopFSWatcher();
if (this!=CtrlObject->Cp()->LeftPanel && this!=CtrlObject->Cp()->RightPanel)
return;
string strSaveDir;
apiGetCurrentDirectory(strSaveDir);
{
string strOldCurDir = strCurDir;
if (!SetCurPath())
{
FlushInputBuffer(); // Очистим буффер ввода, т.к. мы уже можем быть в другом месте...
if (!StrCmp(strCurDir, strOldCurDir)) //?? i??
{
GetPathRoot(strOldCurDir,strOldCurDir);
if (!apiIsDiskInDrive(strOldCurDir))
IfGoHome(strOldCurDir.At(0));
/* При смене каталога путь не изменился */
}
return;
}
}
SortGroupsRead=FALSE;
if (GetFocus())
CtrlObject->CmdLine->SetCurDir(strCurDir);
LastCurFile=-1;
Panel *AnotherPanel=CtrlObject->Cp()->GetAnotherPanel(this);
AnotherPanel->QViewDelTempName();
size_t PrevSelFileCount=SelFileCount;
SelFileCount=0;
SelFileSize=0;
TotalFileCount=0;
TotalFileSize=0;
CacheSelIndex=-1;
CacheSelClearIndex=-1;
if (Opt.ShowPanelFree)
{
unsigned __int64 TotalSize,TotalFree;
if (!apiGetDiskSize(strCurDir,&TotalSize,&TotalFree,&FreeDiskSize))
FreeDiskSize=0;
}
if (FileCount>0)
{
strCurName = ListData[CurFile]->strName;
if (ListData[CurFile]->Selected)
{
for (int i=CurFile+1; i < FileCount; i++)
{
CurPtr = ListData[i];
if (!CurPtr->Selected)
{
strNextCurName = CurPtr->strName;
break;
}
}
}
}
if (KeepSelection || PrevSelFileCount>0)
{
OldData=ListData;
OldFileCount=FileCount;
}
else
DeleteListData(ListData,FileCount);
ListData=nullptr;
int ReadOwners=IsColumnDisplayed(OWNER_COLUMN);
int ReadNumLinks=IsColumnDisplayed(NUMLINK_COLUMN);
int ReadNumStreams=IsColumnDisplayed(NUMSTREAMS_COLUMN);
int ReadStreamsSize=IsColumnDisplayed(STREAMSSIZE_COLUMN);
string strComputerName;
if (ReadOwners)
{
CurPath2ComputerName(strCurDir, strComputerName);
// сбросим кэш SID`ов
SIDCacheFlush();
}
SetLastError(ERROR_SUCCESS);
int AllocatedCount=0;
FileListItem *NewPtr;
// сформируем заголовок вне цикла
wchar_t Title[2048];
int TitleLength=Min((int)X2-X1-1,(int)(ARRAYSIZE(Title))-1);
//wmemset(Title,0x0CD,TitleLength); //BUGBUG
//Title[TitleLength]=0;
MakeSeparator(TitleLength, Title, 9, nullptr);
BOOL IsShowTitle=FALSE;
BOOL NeedHighlight=Opt.Highlight && PanelMode != PLUGIN_PANEL;
if (!Filter)
Filter=new FileFilter(this,FFT_PANEL);
//Рефреш текущему времени для фильтра перед началом операции
Filter->UpdateCurrentTime();
CtrlObject->HiFiles->UpdateCurrentTime();
bool bCurDirRoot = false;
ParsePath(strCurDir, nullptr, &bCurDirRoot);
PATH_TYPE Type = ParsePath(strCurDir, nullptr, &bCurDirRoot);
bool NetRoot = bCurDirRoot && (Type == PATH_REMOTE || Type == PATH_REMOTEUNC);
FileCount = 0;
string strFind = strCurDir;
AddEndSlash(strFind);
strFind+=L'*';
::FindFile Find(strFind, true);
DWORD FindErrorCode = ERROR_SUCCESS;
bool UseFilter=Filter->IsEnabledOnPanel();
bool ReadCustomData=IsColumnDisplayed(CUSTOM_COLUMN0)!=0;
DWORD StartTime = GetTickCount();
while (Find.Get(fdata))
{
FindErrorCode = GetLastError();
if ((Opt.ShowHidden || !(fdata.dwFileAttributes & (FILE_ATTRIBUTE_HIDDEN|FILE_ATTRIBUTE_SYSTEM))) && (!UseFilter || Filter->FileInFilter(fdata, nullptr, &fdata.strFileName)))
{
if (FileCount>=AllocatedCount)
{
AllocatedCount+=4096;
FileListItem **pTemp;
if (!(pTemp=(FileListItem **)xf_realloc(ListData,AllocatedCount*sizeof(*ListData))))
break;
ListData=pTemp;
}
ListData[FileCount] = new FileListItem;
ListData[FileCount]->Clear();
NewPtr=ListData[FileCount];
NewPtr->FileAttr = fdata.dwFileAttributes;
NewPtr->CreationTime = fdata.ftCreationTime;
NewPtr->AccessTime = fdata.ftLastAccessTime;
NewPtr->WriteTime = fdata.ftLastWriteTime;
NewPtr->ChangeTime = fdata.ftChangeTime;
NewPtr->FileSize = fdata.nFileSize;
NewPtr->AllocationSize = fdata.nAllocationSize;
NewPtr->strName = fdata.strFileName;
NewPtr->strShortName = fdata.strAlternateFileName;
NewPtr->Position=FileCount++;
NewPtr->NumberOfLinks=1;
if (fdata.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT)
{
NewPtr->ReparseTag=fdata.dwReserved0; //MSDN
}
if (!(fdata.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY))
{
TotalFileSize += NewPtr->FileSize;
if (ReadNumLinks)
NewPtr->NumberOfLinks=GetNumberOfLinks(fdata.strFileName);
}
else
{
NewPtr->AllocationSize = 0;
}
NewPtr->SortGroup=DEFAULT_SORT_GROUP;
if (ReadOwners)
{
string strOwner;
GetFileOwner(strComputerName, NewPtr->strName,strOwner);
NewPtr->strOwner = strOwner;
}
NewPtr->NumberOfStreams=NewPtr->FileAttr&FILE_ATTRIBUTE_DIRECTORY?0:1;
NewPtr->StreamsSize=NewPtr->FileSize;
if (ReadNumStreams||ReadStreamsSize)
{
EnumStreams(TestParentFolderName(fdata.strFileName)?strCurDir:fdata.strFileName,NewPtr->StreamsSize,NewPtr->NumberOfStreams);
}
if (ReadCustomData)
CtrlObject->Plugins->GetCustomData(NewPtr);
if (!(fdata.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY))
TotalFileCount++;
//memcpy(ListData+FileCount,&NewPtr,sizeof(NewPtr));
// FileCount++;
DWORD CurTime = GetTickCount();
if (CurTime - StartTime > RedrawTimeout)
{
StartTime = CurTime;
if (IsVisible())
{
if (!IsShowTitle)
{
if (!DrawMessage)
{
Text(X1+1,Y1,ColorIndexToColor(COL_PANELBOX),Title);
IsShowTitle=TRUE;
SetColor(Focus ? COL_PANELSELECTEDTITLE:COL_PANELTITLE);
}
}
LangString strReadMsg(MReadingFiles);
strReadMsg << FileCount;
if (DrawMessage)
{
ReadFileNamesMsg(strReadMsg);
}
else
{
TruncStr(strReadMsg,TitleLength-2);
int MsgLength=(int)strReadMsg.GetLength();
GotoXY(X1+1+(TitleLength-MsgLength-1)/2,Y1);
FS<<L" "<<strReadMsg<<L" ";
}
}
if (CheckForEsc())
{
break;
}
}
}
}
if (!(FindErrorCode==ERROR_SUCCESS || FindErrorCode==ERROR_NO_MORE_FILES || FindErrorCode==ERROR_FILE_NOT_FOUND))
Message(MSG_WARNING|MSG_ERRORTYPE,1,MSG(MError),MSG(MReadFolderError),MSG(MOk));
if ((Opt.ShowDotsInRoot || !bCurDirRoot) || (NetRoot && CtrlObject->Plugins->FindPlugin(Opt.KnownIDs.Network))) // NetWork Plugin
{
if (FileCount>=AllocatedCount)
{
FileListItem **pTemp;
if ((pTemp=(FileListItem **)xf_realloc(ListData,(FileCount+1)*sizeof(*ListData))))
ListData=pTemp;
}
if (ListData)
{
ListData[FileCount] = new FileListItem;
string TwoDotsOwner;
if (ReadOwners)
{
GetFileOwner(strComputerName,strCurDir,TwoDotsOwner);
}
FILETIME TwoDotsTimes[4]={};
if(apiGetFindDataEx(strCurDir,fdata))
{
TwoDotsTimes[0]=fdata.ftCreationTime;
TwoDotsTimes[1]=fdata.ftLastAccessTime;
TwoDotsTimes[2]=fdata.ftLastWriteTime;
TwoDotsTimes[3]=fdata.ftChangeTime;
}
AddParentPoint(ListData[FileCount],FileCount,TwoDotsTimes,TwoDotsOwner);
FileCount++;
}
}
if (IsColumnDisplayed(DIZ_COLUMN))
ReadDiz();
if (NeedHighlight)
{
CtrlObject->HiFiles->GetHiColor(ListData, FileCount);
}
if (AnotherPanel->GetMode()==PLUGIN_PANEL)
{
HANDLE hAnotherPlugin=AnotherPanel->GetPluginHandle();
PluginPanelItem *PanelData=nullptr;
string strPath;
size_t PanelCount=0;
strPath = strCurDir;
AddEndSlash(strPath);
if (CtrlObject->Plugins->GetVirtualFindData(hAnotherPlugin,&PanelData,&PanelCount,strPath))
{
FileListItem **pTemp;
if ((pTemp=(FileListItem **)xf_realloc(ListData,(FileCount+PanelCount)*sizeof(*ListData))))
{
ListData=pTemp;
for (size_t i=0; i < PanelCount; i++)
{
CurPtr = ListData[FileCount+i];
PluginPanelItem &pfdata=PanelData[i];
PluginToFileListItem(&PanelData[i],CurPtr);
CurPtr->Position=FileCount;
TotalFileSize += pfdata.FileSize;
CurPtr->PrevSelected=CurPtr->Selected=0;
CurPtr->ShowFolderSize=0;
CurPtr->SortGroup=CtrlObject->HiFiles->GetGroup(CurPtr);
if (!TestParentFolderName(pfdata.FileName) && !(CurPtr->FileAttr & FILE_ATTRIBUTE_DIRECTORY))
TotalFileCount++;
}
// цветовую боевую раскраску в самом конце, за один раз
CtrlObject->HiFiles->GetHiColor(&ListData[FileCount],PanelCount);
FileCount+=static_cast<int>(PanelCount);
}
CtrlObject->Plugins->FreeVirtualFindData(hAnotherPlugin,PanelData,PanelCount);
}
}
InitFSWatcher(false);
CorrectPosition();
if (KeepSelection || PrevSelFileCount>0)
{
MoveSelection(ListData,FileCount,OldData,OldFileCount);
DeleteListData(OldData,OldFileCount);
}
if (SortGroups)
ReadSortGroups(false);
if (!KeepSelection && PrevSelFileCount>0)
{
SaveSelection();
ClearSelection();
}
SortFileList(FALSE);
if (CurFile>=FileCount || StrCmpI(ListData[CurFile]->strName,strCurName))
if (!GoToFile(strCurName) && !strNextCurName.IsEmpty())
GoToFile(strNextCurName);
/* $ 13.02.2002 DJ
SetTitle() - только если мы текущий фрейм!
*/
if (CtrlObject->Cp() == FrameManager->GetCurrentFrame())
SetTitle();
FarChDir(strSaveDir); //???
}
int Build2DTextures( IntroProgressDelegate& _Delegate )
{
return 0;
DrawUtils Draw;
{
TextureBuilder TB( 512, 512 );
Draw.SetupSurface( 512, 512, TB.GetMips()[0] ); // Let's draw into the first mip level !
/* General tests for drawing tools and filtering
Noise N( 1 );
N.Create2DWaveletNoiseTile( 6 ); // If you need to use wavelet noise...
TB.Fill( FillNoise, &N );
Draw.DrawLine( 20.0f, 0.0f, 400.0f, 500.0f, 10.0f, FillLine, NULL );
Draw.SetupContext( 30.0f, 0.0f, 20.0f );
Draw.DrawEllipse( 10.0f, 13.4f, 497.39f, 282.78f, 40.0f, 0.0f, FillEllipse, NULL );
Draw.SetupContext( 250.0f, 0.0f, 30.0f );
Draw.DrawRectangle( 10.0f, 13.4f, 197.39f, 382.78f, 40.0f, 0.5f, FillRectangle, NULL );
// Filters::BlurGaussian( TB, 20.0f, 20.0f, true, 0.5f );
// Filters::UnsharpMask( TB, 20.0f );
// Filters::BrightnessContrastGamma( TB, 0.2f, 0.0f, 2.0f );
// Filters::Emboss( TB, NjFloat2( 1, 1 ), 4.0f );
// Filters::Erode( TB );
// Filters::Dilate( TB );
// // Test the AO converter
// TextureBuilder PipoTemp( TB.GetWidth(), TB.GetHeight() );
// PipoTemp.CopyFrom( TB );
// Generators::ComputeAO( PipoTemp, TB, 2.0f );
//*/
// // Test the dirtyness generator
// Generators::Dirtyness( TB, N, 0.5f, 0.0f, 0.1f, 0.3f, 0.01f );
// Test the secret marble generator
// Generators::Marble( TB, 30, 0.2f, 0.5f, 1.0f, 0.5f, 0.5f );
// Generators::Marble3D( TB, 16, 0.2f );
//* Test advanced drawing
Noise N( 1 );
// Draw scratches
for ( int i=0; i < 10; i++ )
{
NjFloat2 Pos;
Pos.x = _frand( 0.0f, 512.0f );
Pos.y = _frand( 0.0f, 512.0f );
NjFloat2 Dir;
Dir.x = _frand( -1.0f, +1.0f );
Dir.y = _frand( -1.0f, +1.0f );
float Length = _frand( 100.0f, 500.0f );
float Thickness = _frand( 4.0f, 5.0f );
float Curve = _frand( -0.05f, 0.05f );
Draw.DrawScratch( Pos, Dir, Length, Thickness, 0.01f, Curve, 10.0f, FillScratch, &N );
}
// Draw splotches
for ( int Y=0; Y < 20; Y++ )
{
int Count = _rand( 10, 20 );
float Angle = _frand( -180.0f, +180.0f );
float DeltaAngle = _frand( 0.0f, 40.0f ); // Splotches rotate with time
DeltaAngle /= Count;
NjFloat2 Pos;
Pos.x = _frand( -512.0f, 512.0f );
Pos.y = _frand( -512.0f, 512.0f );
NjFloat2 Size;
Size.x = _frand( 40.0f, 50.0f );
Size.y = _frand( 40.0f, 50.0f );
float DeltaSize = _frand( 0.0f, 30.0f ); // Splotches get bigger or smaller with time
DeltaSize /= Count;
float Step = _frand( 0.25f, 1.0f ) * Size.x; // Splotches interpenetrate
for ( int X=0; X < Count; X++ )
{
Draw.SetupTransform( Pos.x, Pos.y, Angle );
Draw.DrawRectangle( 0.0f, 0.0f, Size.x, Size.y, 0.1f * Size.Min(), 0.0f, FillSplotch, &N );
Angle += DeltaAngle;
float AngleRad = DEG2RAD( Angle );
Pos = Pos + Step * NjFloat2( cosf(AngleRad), sinf(AngleRad) );
Size.x += DeltaSize;
}
}
// Draw.DrawRectangle( 0.0f, 0.0f, 100.0f, 100.0f, 10.0f, 0.0f, FillSplotch, &N );
// Filters::BrightnessContrastGamma( TB, 0.1f, 0.7f, 2.0f );
// Filters::Erode( TB, 3 );
//*/
gs_pTexTestNoise = TB.CreateTexture( PixelFormatRGBA16F::DESCRIPTOR, TextureBuilder::CONV_RGBA_NxNyHR_M );
}
return 0; // OK !
}
main()
{
vec_t test;
vec_t tout;
#define TD(i,j) test.put(&d[i], j); cerr << "d is at " << ::dec((unsigned int)d) << endl;
#define TB(i,j) test.put(&b[i], j); cerr << "b is at " << ::dec((unsigned int)b) << endl;
#define TA(i,j) test.put(&a[i], j); cerr << "a is at " << ::dec((unsigned int)a) << endl;
#define TC(i,j) test.put(&c[i], j); cerr << "c is at " << ::dec((unsigned int)c) << endl;
TA(0,10);
TB(0,10);
TC(0,10);
TD(0,10);
V(test, 5, 7, tout);
V(test, 5, 10, tout);
V(test, 5, 22, tout);
V(test, 11, 0, tout);
V(test, 11, 7, tout);
V(test, 11, 9, tout);
V(test, 30, 9, tout);
V(test, 30, 29, tout);
V(test, 30, 40, tout);
V(test, 40, 30, tout);
V(test, 100, 9, tout);
P("{ {1 \"}\" }");
/*{{{*/
P("{ {3 \"}}}\" }}");
P("{ {30 \"xxxxxxxxxxyyyyyyyyyyzzzzzzzzzz\"} }");
P("{ {30 \"xxxxxxxxxxyyyyyyyyyyzzzzzzzzzz\"}{10 \"abcdefghij\"} }");
{
vec_t t;
t.reset();
t.put("abc",3);
for(int i=0; i<t.count(); i++) {
cout <<"vec["<<i<<"]=("
<<::dec((unsigned int)t.ptr(i)) <<"," <<t.len(i) <<")" << endl;
}
cout << "FINAL: "<< t << endl;
}
{
cout << "ZVECS: " << endl;
{
zvec_t z(0);
cout << "z(0).count() = " << z.count() << endl;
cout << "z(0) is zero vec: " << z.is_zvec() << endl;
vec_t zv;
zv.set(z);
cout << "zv.set(z).count() = " << zv.count() << endl;
cout << "zv is zero vec: " << zv.is_zvec() << endl;
}
{
zvec_t z;
cout << "z is zero vec: " << z.is_zvec() << endl;
cout << "z.count() = " << z.count() << endl;
vec_t zv;
zv.set(z);
cout << "zv.set(z).count() = " << zv.count() << endl;
cout << "zv(0) is zero vec: " << zv.is_zvec() << endl;
}
}
{
int n = 0x80000003;
int m = 0xeffffffc;
vec_t num( (void*)&n, sizeof(n));
vec_t num2( (void*)&m, sizeof(m));
cout << "vec containing 0x80000003 prints as: " << num << endl;
cout << "vec containing 0xeffffffc prints as: " << num2 << endl;
}
{
char c = 'h';
char last = (char)'\377';
char last1 = '\377';
char last2 = (char)0xff;
vec_t cv( (void*)&c, sizeof(c));
vec_t lastv( (void*)&last, sizeof(last));
vec_t last1v( (void*)&last1, sizeof(last1));
vec_t last2v( (void*)&last2, sizeof(last2));
bool result = (bool)(cv < lastv);
cout << "cv <= lastv: " << result << endl;
cout << "cv prints as: " << cv <<endl;
cout << "lastv prints as: " << lastv <<endl;
cout << "last1 prints as: " << last1v <<endl;
cout << "last2 prints as: " << last2v <<endl;
}
}
EffectParticles::EffectParticles() : m_ErrorCode( 0 )
{
//////////////////////////////////////////////////////////////////////////
// Create the materials
CHECK_MATERIAL( m_pMatCompute = CreateMaterial( IDR_SHADER_PARTICLES_COMPUTE, "./Resources/Shaders/ParticlesCompute.hlsl", VertexFormatPt4::DESCRIPTOR, "VS", NULL, "PS" ), 1 );
CHECK_MATERIAL( m_pMatDisplay = CreateMaterial( IDR_SHADER_PARTICLES_DISPLAY, "./Resources/Shaders/ParticlesDisplay.hlsl", VertexFormatPt4::DESCRIPTOR, "VS", "GS", "PS" ), 2 );
CHECK_MATERIAL( m_pMatDebugVoronoi = CreateMaterial( IDR_SHADER_PARTICLES_DISPLAY, "./Resources/Shaders/ParticlesDisplay.hlsl", VertexFormatPt4::DESCRIPTOR, "VS_DEBUG", NULL, "PS_DEBUG" ), 3 );
//////////////////////////////////////////////////////////////////////////
// Build the awesome particle primitive
// {
// VertexFormatP3 Vertices;
// m_pPrimParticle = new Primitive( gs_Device, 1, &Vertices, 0, NULL, D3D11_PRIMITIVE_TOPOLOGY_POINTLIST, VertexFormatP3::DESCRIPTOR );
// }
//////////////////////////////////////////////////////////////////////////
// Build our voronoï texture & our initial positions & data
NjFloat2* pCellCenters = new NjFloat2[EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT];
{
TextureBuilder TB( 1024, 1024 );
VertexFormatPt4* pVertices = new VertexFormatPt4[EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT];
BuildVoronoiTexture( TB, pCellCenters, pVertices );
TextureBuilder::ConversionParams Conv =
{
0, // int PosR;
1, // int PosG;
-1, // int PosB;
-1, // int PosA;
false,
// Position of the height & roughness fields
-1, // int PosHeight;
-1, // int PosRoughness;
// Position of the Material ID
-1, // int PosMatID;
// Position of the normal fields
// 1.0f, // float NormalFactor; // Factor to apply to the height to generate the normals
true,
-1, // int PosNormalX;
-1, // int PosNormalY;
-1, // int PosNormalZ;
// Position of the AO field
// 1.0f, // float AOFactor; // Factor to apply to the height to generate the AO
-1, // int PosAO;
};
m_pTexVoronoi = TB.CreateTexture( PixelFormatRG32F::DESCRIPTOR, Conv );
m_pPrimParticle = new Primitive( gs_Device, EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT, pVertices, 0, NULL, D3D11_PRIMITIVE_TOPOLOGY_POINTLIST, VertexFormatPt4::DESCRIPTOR );
// Build cell centers
for ( int ParticleIndex=0; ParticleIndex < EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT; ParticleIndex++ )
pCellCenters[ParticleIndex].Set( 0.5f * (pVertices[ParticleIndex].Pt.x + pVertices[ParticleIndex].Pt.z), 0.5f * (pVertices[ParticleIndex].Pt.y + pVertices[ParticleIndex].Pt.w) );
delete[] pVertices;
}
//////////////////////////////////////////////////////////////////////////
// Build the initial positions & orientations of the particles from the surface of a torus
PixelFormatRGBA32F* pInitialPositions = new PixelFormatRGBA32F[EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT];
PixelFormatRGBA32F* pInitialNormals = new PixelFormatRGBA32F[EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT];
PixelFormatRGBA32F* pInitialTangents = new PixelFormatRGBA32F[EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT];
PixelFormatRGBA32F* pScanlinePosition = pInitialPositions;
PixelFormatRGBA32F* pScanlineNormal = pInitialNormals;
PixelFormatRGBA32F* pScanlineTangent = pInitialTangents;
int TotalCount = EFFECT_PARTICLES_COUNT*EFFECT_PARTICLES_COUNT;
int ParticlesPerDimension = U32(floorf(powf( float(TotalCount), 1.0f/3.0f )));
float R = 0.5f; // Great radius of the torus
float r = 0.2f; // Small radius of the torus
for ( int Y=0; Y < EFFECT_PARTICLES_COUNT; Y++ )
for ( int X=0; X < EFFECT_PARTICLES_COUNT; X++, pScanlinePosition++, pScanlineNormal++, pScanlineTangent++ )
{
NjFloat2& CellCenter = pCellCenters[EFFECT_PARTICLES_COUNT*Y+X];
float Alpha = TWOPI * X / EFFECT_PARTICLES_COUNT; // Angle on the great circle
float Beta = TWOPI * Y / EFFECT_PARTICLES_COUNT; // Angle on the small circle
NjFloat3 T( cosf(Alpha), 0.0f, -sinf(Alpha) ); // Gives the direction to the center on the great circle in the Z^X plane
NjFloat3 Center = NjFloat3( 0, 0.8f, 0 ) + R * T; // Center on the great circle
NjFloat3 Ortho( T.z, 0, -T.x ); // Tangent to the great circle in the Z^X plane
NjFloat3 B( 0, 1, 0 ); // Bitangent is obviously, always the Y vector
NjFloat3 Normal = cosf(Beta) * T + sinf(Beta) * B; // The normal to the small circle, also the direction to the point on the surface
NjFloat3 Tangent = Ortho;
NjFloat3 Pos = Center + r * Normal; // Position on the surface of the small circle
float Radius = R + r * cosf(Beta); // Radius of the circle where the particle is standing
float Perimeter = TWOPI * Radius; // Perimeter of that circle
float ParticleSize = 0.5f * Perimeter; // Size of a single particle on that circle
float ParticleLife = -1.0f - 4.0f * (1.0f - Normal.y); // Start with a negative life depending on height
// DEBUG Generate on a plane for verification
// Pos.x = 2.0f * (CellCenter.x - 0.5f);
// Pos.y = 0.5f;
// Pos.z = -2.0f * (CellCenter.y - 0.5f);
// Normal.Set( 0, 1, 0 ); // Facing up
// Tangent.Set( 1, 0, 0 ); // Right
// ParticleSize = 1.0f;// / EFFECT_PARTICLES_COUNT; // Size of a single particle on that circle
// DEBUG
pScanlinePosition->R = Pos.x;
pScanlinePosition->G = Pos.y;
pScanlinePosition->B = Pos.z;
pScanlinePosition->A = ParticleLife;
pScanlineNormal->R = Normal.x;
pScanlineNormal->G = Normal.y;
pScanlineNormal->B = Normal.z;
// pScanlineNormal->A = (0.025f + 0.002f) * EFFECT_PARTICLES_COUNT; // Half size + a little epsilon to make the tiles join correctly
// pScanlineNormal->A = (0.1f + 0*0.002f) * EFFECT_PARTICLES_COUNT; // Half size + a little epsilon to make the tiles join correctly
pScanlineNormal->A = ParticleSize;
pScanlineTangent->R = Tangent.x;
pScanlineTangent->G = Tangent.y;
pScanlineTangent->B = Tangent.z;
pScanlineTangent->A = Normal.y > 0.0f ? 1.0f : -1.0f; // Determines the particle's behavior...
}
delete[] pCellCenters;
// Unfortunately, we need to create Textures to initialize our RenderTargets
void* ppContentPositions[1];
ppContentPositions[0] = (void*) pInitialPositions;
Texture2D* pTempPositions = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, ppContentPositions );
delete[] pInitialPositions;
void* ppContentNormals[1];
ppContentNormals[0] = (void*) pInitialNormals;
Texture2D* pTempNormals = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, ppContentNormals );
delete[] pInitialNormals;
void* ppContentTangents[1];
ppContentTangents[0] = (void*) pInitialTangents;
Texture2D* pTempTangents = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, ppContentTangents );
delete[] pInitialTangents;
// Finally, create the render targets and initialize them
m_ppRTParticlePositions[0] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticlePositions[1] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticlePositions[2] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticlePositions[0]->CopyFrom( *pTempPositions );
m_ppRTParticlePositions[1]->CopyFrom( *pTempPositions );
m_ppRTParticlePositions[2]->CopyFrom( *pTempPositions );
delete pTempPositions;
m_ppRTParticleNormals[0] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticleNormals[1] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticleNormals[0]->CopyFrom( *pTempNormals );
m_ppRTParticleNormals[1]->CopyFrom( *pTempNormals );
delete pTempNormals;
m_ppRTParticleTangents[0] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticleTangents[1] = new Texture2D( gs_Device, EFFECT_PARTICLES_COUNT, EFFECT_PARTICLES_COUNT, 1, PixelFormatRGBA32F::DESCRIPTOR, 1, NULL );
m_ppRTParticleTangents[0]->CopyFrom( *pTempTangents );
m_ppRTParticleTangents[1]->CopyFrom( *pTempTangents );
delete pTempTangents;
//////////////////////////////////////////////////////////////////////////
// Create the constant buffers
m_pCB_Render = new CB<CBRender>( gs_Device, 10 );
m_pCB_Render->m.DeltaTime.Set( 0, 1 );
}
//*********************************
//pobierz trzy temperatury z dowolnego przedzia³u dowolnego bufora
void TempBuffGet(
uint8_t pi_BuffType //typ bufora TEMP_BUFF12m/...
,uint8_t pi_Sensor //numer termometru
//dla pi_Sensor==TEMP_FULLNO
//bie¿¹cy indeks: gt_TempBuffsIdx[pi_BuffType], rozmiar bufora: TempBuff(pi_BuffType,Size)
//dla pi_Sensor!=TEMP_FULLNO
//bie¿¹cy indeks: gi_Temps12mIdx, rozmiar bufora: TEMP_12MSIZE
,uint8_t pi_FirstIdx //pocz¹tkowy indeks
,uint8_t pi_LastIdx //koñcowy indeks
,int16_t pt_Temps[] //zwrócone temperatury [TEMP_MIN] [TEMP_AVG] [TEMP_MAX] tabelka MUSI mieæ 3 elementy
,uint8_t pi_Type //0: min/max liczone z buff[TEMP_AVG] 1: min/max liczone z buff[TEMP_MIN/TEMP_MAX]
) {
int16_t vt_Temps[TEMP_MAX+1];
int32_t vi_TempAVGSum;
uint8_t vi_TempCount;
uint8_t vi_Buff8Idx,vi_BuffSize,vi_CurrBuffIdx;
uint16_t vi_BuffIdx,vi_LastIdx;
int16_t *vt_TempsBuff;
uint8_t vi_MinTempType,vi_MaxTempType;
if (pi_Type) {
vi_MinTempType = TEMP_MIN;
vi_MaxTempType = TEMP_MAX;
}
else {
vi_MinTempType = TEMP_AVG;
vi_MaxTempType = TEMP_AVG;
}
pt_Temps[TEMP_MIN] = 0x7FFF;
pt_Temps[TEMP_MAX] = 0x8000;
vi_TempAVGSum = 0;
vi_TempCount = 0;
vt_TempsBuff = 0;
vi_CurrBuffIdx = gt_TempBuffsIdx[pi_BuffType];
if (pi_BuffType) {
vi_BuffSize = TB(pi_BuffType,Size);
}
else if (pi_Sensor==TEMP_FULLNO) {
vt_TempsBuff = gt_TempBuff12m;
vi_BuffSize = TB(TEMP_BUFF12m,Size);
}
else {
vt_TempsBuff = gt_TempsVar[pi_Sensor].Buff12m;
vi_BuffSize = TEMP_12MSIZE;
}
vi_LastIdx = pi_LastIdx;
if (vi_LastIdx<pi_FirstIdx)
vi_LastIdx += TB(pi_BuffType,Size);
for (vi_BuffIdx = pi_FirstIdx; vi_BuffIdx<=vi_LastIdx; vi_BuffIdx++) {
vi_Buff8Idx = vi_BuffIdx%vi_BuffSize;
if (pi_BuffType==TEMP_BUFF24m) {
uint8_t vi_Buff8Idx2 = vi_Buff8Idx*2;
TempBuffGet(TEMP_BUFF12m,pi_Sensor,vi_Buff8Idx2,
(vi_Buff8Idx!=gt_TempBuffsIdx[TEMP_BUFF24m] || vi_Buff8Idx2<gt_TempBuffsIdx[TEMP_BUFF12m])?vi_Buff8Idx2+1:vi_Buff8Idx2,
vt_Temps,0);
vt_Temps[TEMP_MIN] = vt_Temps[TEMP_AVG];
vt_Temps[TEMP_MAX] = vt_Temps[TEMP_AVG];
}
else
#if TEMP_USE_BUFF
if (vt_TempsBuff)
#endif //TEMP_USE_BUFF
{
uint8_t vi_sreg = SREG;
cli();
vt_Temps[TEMP_MIN] = vt_TempsBuff[vi_Buff8Idx];
SREG = vi_sreg;
vt_Temps[TEMP_AVG] = vt_Temps[TEMP_MIN];
vt_Temps[TEMP_MAX] = vt_Temps[TEMP_MIN];
}
#if TEMP_USE_BUFF
else
if (vi_Buff8Idx == vi_CurrBuffIdx && gi_TempBuffCurrMode!=TEMP_BCM_READFROMEE)
if (gi_TempBuffCurrMode==TEMP_BCM_READFROMCACHE)
for (uint8_t vi_Idx=TEMP_MIN; vi_Idx<=TEMP_MAX; vi_Idx++)
vt_Temps[vi_Idx] = gt_TempBuffCurrCache[vi_Idx];
else
TempBuffGetCurr(pi_BuffType,vt_Temps);
else
TempBuffRead(pi_BuffType,vi_Buff8Idx,vt_Temps);
#endif //TEMP_USE_BUFF
if (vt_Temps[TEMP_MIN]!=TEMP_NONE16) {
vi_TempCount++;
if (vt_Temps[vi_MinTempType]<pt_Temps[TEMP_MIN]) pt_Temps[TEMP_MIN] = vt_Temps[vi_MinTempType];
vi_TempAVGSum += vt_Temps[TEMP_AVG];
if (vt_Temps[vi_MaxTempType]>pt_Temps[TEMP_MAX]) pt_Temps[TEMP_MAX] = vt_Temps[vi_MaxTempType];
}
}
if (vi_TempCount)
pt_Temps[TEMP_AVG] = DivL(vi_TempAVGSum,vi_TempCount);
else
MemClear_I16(&pt_Temps[TEMP_MIN],3);
} //TempBuffGet
//==============================================================
// PUBLIC PROCEDURES
//==============================================================
//int16_t gt_TempDebug[TEMP_MAX+1];
//*********************************
//inicjalizuj modu³
void TempInit(void) {
uint8_t vi_Idx;
TempStoreCurrTime();
for (vi_Idx=0; vi_Idx<TEMP_COUNT; vi_Idx++) {
MemClear_I16(gt_TempsVar[vi_Idx].Buff12m,TEMP_12MSIZE);
gt_TempsVar[vi_Idx].ErrorCount = TEMP_MAX_ERRORS;
}
MemClear_I16(gt_TempBuff12m,TB(TEMP_BUFF12m,Size));
//ustaw indeksy do buforów temperatur
for (vi_Idx=0; vi_Idx<=TEMP_BUFFCOUNT; vi_Idx++)
gt_TempBuffsIdx[vi_Idx] = TempBuffCurrIdx(vi_Idx);
#if TEMP_USE_BUFF
//wyczyϾ wszystkie bufory EEPROM
for (vi_Idx=1; vi_Idx<TEMP_BUFFCOUNT; vi_Idx++)
if (TB(vi_Idx,EEMem))
if (eeprom_read_byte(&gb_TempBuffsEEInitialized)!=1)
EEMemClear_I8(TBAddr(vi_Idx),TB(vi_Idx,Size)*TB(vi_Idx,SubSize));
else ;
else
MemClear_I8(TBAddr(vi_Idx),TB(vi_Idx,Size)*TB(vi_Idx,SubSize));
eeprom_write_byte(&gb_TempBuffsEEInitialized,1);
#endif //TEMP_USE_BUFF
#ifdef TEMP_BUFF1D
//ustaw w temps12m œredni¹/min/max zapisane w gt_Temps1D
int16_t vt_Temps[TEMP_MAX+1];
TempBuffRead(TEMP_BUFF1D,gt_TempBuffsIdx[TEMP_BUFF1D],vt_Temps);
for (vi_Idx=0; vi_Idx<5*24; vi_Idx++)
gt_TempBuff12m[vi_Idx] = vt_Temps[TEMP_AVG];
gt_TempBuff12m[1] = vt_Temps[TEMP_MIN];
gt_TempBuff12m[2] = vt_Temps[TEMP_MAX];
#endif //TEMP_BUFF1D
#if TEMP_USE_BUFF
gt_Temp1dLastDate[TYear] = gt_CurrTime[TYear];
gt_Temp1dLastDate[TMonth] = gt_CurrTime[TMonth];
gt_Temp1dLastDate[TDay] = gt_CurrTime[TDay];
gt_Temp1dLastDate[TDay+1] = gt_CurrTime[TWeekDay];
#endif //TEMP_USE_BUFF
/* //uzupe³nianie bufora 1W z bufora 1D
gi_TempBuffCurrMode = TEMP_BCM_READFROMEE;
gt_TimeCheck[TDay] = 22;
gt_TimeCheck[TWeekDay] = 0;
gt_Temp1dLastDate[TDay] = 22;
gt_Temp1dLastDate[TDay+1] = 0;
int16_t vt_Temps[10];
for (vi_Idx=0; vi_Idx<10; vi_Idx++) {
TempBuffGetCurr(TEMP_BUFF1W,vt_Temps);
TempBuffWrite(TEMP_BUFF1W,gt_TempBuffsIdx[TEMP_BUFF1W],vt_Temps);
TimeGetDateFromDayNo(TimeGetDayNo(gt_TimeCheck[TDay],gt_TimeCheck[TMonth],gt_TimeCheck[TYear])-7,gt_Temp1dLastDate);
gt_TimeCheck[TMonth] = gt_Temp1dLastDate[TMonth];
gt_TimeCheck[TDay] = gt_Temp1dLastDate[TDay];
gt_TempBuffsIdx[TEMP_BUFF1D] = TempBuffCurrIdx(TEMP_BUFF1D);
gt_TempBuffsIdx[TEMP_BUFF1W] = TempBuffCurrIdx(TEMP_BUFF1W);
}
while (1);*/
TimeAddHthProcedure(&TempExecuteHthSec);
} //TempInit
