BOOL CSerialPDD::Open()
{
PHYSICAL_ADDRESS ioPhysicalBase = { S3C6410_BASE_REG_PA_GPIO, 0};
ULONG inIoSpace = 0;
if (InterlockedExchange(&m_lOpenCount,1) !=0)
return FALSE;
PREFAST_ASSERT(m_PowerHelperHandle!=INVALID_HANDLE_VALUE);
ASSERT(m_hPowerLock==NULL);
m_hPowerLock= DDKPwr_RequestLevel( m_PowerHelperHandle, D0 );
ASSERT(m_hPowerLock!=NULL);
SetDefaultConfiguration();
InitLine(TRUE);
InitReceive(TRUE);
InitXmit(TRUE);
if(cUart_Index==3)
{
if (TranslateBusAddr(m_hParent,Internal,0, ioPhysicalBase,&inIoSpace,&ioPhysicalBase))
{
// Map it if it is Memeory Mapped IO.
g_pIOPregs = (S3C6410_GPIO_REG *)DrvLib_MapIoSpace(ioPhysicalBase.LowPart , sizeof(S3C6410_GPIO_REG),FALSE);
g_pIOPregs->GPCCON &= ~(0xf<<28); ///< Clear Bit
g_pIOPregs->GPCCON |= (0x1<<28); ///< Select UART IP
g_pIOPregs->GPCPUD &= ~(0x3<<14); ///< Pull-Up/Down Disable
//g_pIOPregs->GPCDAT |=1<<7;
}
}
return TRUE;
}
void CDebug::Initialize()
{
m_pDevice = _SINGLE(CDevice)->GetDevice();
if(!m_pDevice)
return;
_SINGLE(CTimeManager)->Init();
//CreateVertexBuffer();
//memset(&m_tGridMaterial, 0, sizeof(D3DMATERIAL9));
//m_tGridMaterial.Diffuse.a = 1.f;
//m_tGridMaterial.Diffuse.r = 1.f;
//m_tGridMaterial.Diffuse.g = 0.8f;
//m_tGridMaterial.Diffuse.b = 1.f;
//m_tGridMaterial.Power = 0.2f;
//m_tGridMaterial.Specular = m_tGridMaterial.Diffuse;
//m_tGridMaterial.Ambient = m_tGridMaterial.Diffuse;
//m_pTerrain = new CTerrainMesh;
//m_pTerrain->Initialize();
InitFont();
InitLog();
InitLine();
//AddText3D( D3DXVECTOR3(10, 3, 10), _T("3D텍스트다!") );
}
LinkComp::LinkComp (Line* line) {
if (line != nil) {
Coord x0, y0, x1, y1;
float fx0, fy0, fx1, fy1;
line->GetOriginal(x0, y0, x1, y1);
Transformer* t = line->GetTransformer();
Graphic* parent = new Picture(line);
parent->SetTransformer(nil);
if (t == nil) {
fx0 = x0; fy0 = y0; fx1 = x1; fy1 = y1;
} else {
t->Transform(float(x0), float(y0), fx0, fy0);
t->Transform(float(x1), float(y1), fx1, fy1);
}
delete line;
line = new Line(0, 0, 1, 1);
InitLine(line, fx0, fy0, fx1, fy1);
PinGraphic* pg1 = new PinGraphic;
PinGraphic* pg2 = new PinGraphic;
pg1->SetBrush(psnonebr);
pg2->SetBrush(psnonebr);
pg1->Translate(fx0, fy0);
pg2->Translate(fx1, fy1);
_conn1 = new PinComp(pg1);
_conn2 = new PinComp(pg2);
parent->Append(line, pg1, pg2);
SetGraphic(parent);
}
}
void CPdd6410Uart::PostInit()
{
DWORD dwCount=0;
m_HardwareLock.Lock();
m_pReg6410Uart->Write_UCON(0); // Set to Default;
DisableInterrupt(S6410UART_INT_RXD | S6410UART_INT_TXD | S6410UART_INT_ERR | S6410UART_INT_MODEM);
// Mask all interrupt.
while ((GetInterruptStatus() & (S6410UART_INT_RXD | S6410UART_INT_TXD | S6410UART_INT_ERR | S6410UART_INT_MODEM))!=0 && dwCount <MAX_RETRY)
{
InitReceive(TRUE);
InitLine(TRUE);
ClearInterrupt(S6410UART_INT_RXD | S6410UART_INT_TXD | S6410UART_INT_ERR | S6410UART_INT_MODEM);
dwCount++;
}
ASSERT((GetInterruptStatus() & (S6410UART_INT_RXD | S6410UART_INT_TXD | S6410UART_INT_ERR | S6410UART_INT_MODEM))==0);
m_HardwareLock.Unlock();
CSerialPDD::PostInit();
CeSetPriority(m_dwPriority256);
#ifdef DEBUG
if ( ZONE_INIT )
{
m_pReg6410Uart->DumpRegister();
}
#endif
ThreadStart(); // Start IST.
}
static void PreprocessLine (void)
/* Translate one line. */
{
/* Trim whitespace and remove comments. The function returns the number of
* identifiers found. If there were any, we will have to check for macros.
*/
SB_Clear (MLine);
if (Pass1 (Line, MLine) > 0) {
MLine = InitLine (MLine);
SB_Reset (Line);
SB_Clear (MLine);
MacroReplacement (Line, MLine);
}
/* Read from the new line */
SB_Reset (MLine);
MLine = InitLine (MLine);
}
static void
InitLines (void)
{
InitReduce (INITLINES1);
if (ltoken_getCode (nextToken) != LEOFTOKEN)
{
InitLine ();
InitReduce (INITLINES2);
}
while (ltoken_getCode (nextToken) != LEOFTOKEN)
{
InitLine ();
InitReduce (INITLINES3);
}
}
void CSerialPDD::Reset()
{
InitialPower(TRUE);
InitModem(TRUE);
InitLine(TRUE);
InitReceive(TRUE);
InitXmit(TRUE);
InitialEnableInterrupt(TRUE);
}
void LinkComp::Update () {
float fx0, fy0, fx1, fy1;
Transformer* t1 = _conn1->GetGraphic()->GetTransformer();
Transformer* t2 = _conn2->GetGraphic()->GetTransformer();
t1->Transform(0., 0., fx0, fy0);
t2->Transform(0., 0., fx1, fy1);
InitLine(GetLine(), fx0, fy0, fx1, fy1);
Notify();
}
static void MacroReplacement (StrBuf* Source, StrBuf* Target)
/* Perform macro replacement. */
{
ident Ident;
Macro* M;
/* Remember the current input and switch to Source */
StrBuf* OldSource = InitLine (Source);
/* Loop substituting macros */
while (CurC != '\0') {
/* If we have an identifier, check if it's a macro */
if (IsSym (Ident)) {
/* Check if it's a macro */
if ((M = FindMacro (Ident)) != 0 && !M->Expanding) {
/* It's a macro, expand it */
ExpandMacro (Target, M);
} else {
/* An identifier, keep it */
SB_AppendStr (Target, Ident);
}
} else if (IsQuote (CurC)) {
CopyQuotedString (Target);
} else if (IsSpace (CurC)) {
if (!IsSpace (SB_LookAtLast (Target))) {
SB_AppendChar (Target, CurC);
}
NextChar ();
} else {
SB_AppendChar (Target, CurC);
NextChar ();
}
}
/* Switch back the input */
InitLine (OldSource);
}
void CAdActor::FollowPath()
{
// skip current position
m_Path->GetFirst();
while(m_Path->GetCurrent()!=NULL)
{
if(m_Path->GetCurrent()->x != m_PosX || m_Path->GetCurrent()->y != m_PosY) break;
m_Path->GetNext();
}
// are there points to follow?
if(m_Path->GetCurrent() != NULL)
{
m_State = STATE_FOLLOWING_PATH;;
InitLine(CBPoint(m_PosX, m_PosY), *m_Path->GetCurrent());
}
else
{
if(m_AfterWalkDir!=DI_NONE) TurnTo(m_AfterWalkDir);
else m_State = STATE_READY;
}
}
static void DoPragma (void)
/* Handle a #pragma line by converting the #pragma preprocessor directive into
* the _Pragma() compiler operator.
*/
{
/* Skip blanks following the #pragma directive */
SkipWhitespace (0);
/* Copy the remainder of the line into MLine removing comments and ws */
SB_Clear (MLine);
Pass1 (Line, MLine);
/* Convert the directive into the operator */
SB_CopyStr (Line, "_Pragma (");
SB_Reset (MLine);
Stringize (MLine, Line);
SB_AppendChar (Line, ')');
/* Initialize reading from line */
SB_Reset (Line);
InitLine (Line);
}
BOOL CSerialPDD::Close()
{
if (InterlockedExchange(&m_lOpenCount,0) !=1)
return FALSE;
InitXmit(FALSE);
InitReceive(FALSE);
InitLine(FALSE);
PREFAST_ASSERT(m_PowerHelperHandle!=INVALID_HANDLE_VALUE);
ASSERT(m_hPowerLock!=NULL);
DDKPwr_ReleaseLevel(m_PowerHelperHandle, m_hPowerLock);
m_hPowerLock=NULL;
if(cUart_Index==3)
{
//g_pIOPregs->GPCDAT &=~(1<<7);
if (g_pIOPregs!=NULL)
{
DrvLib_UnmapIoSpace((PVOID)g_pIOPregs);
}
}
return TRUE;
}
static unsigned Pass1 (StrBuf* Source, StrBuf* Target)
/* Preprocessor pass 1. Remove whitespace. Handle old and new style comments
* and the "defined" operator.
*/
{
unsigned IdentCount;
ident Ident;
int HaveParen;
/* Switch to the new input source */
StrBuf* OldSource = InitLine (Source);
/* Loop removing ws and comments */
IdentCount = 0;
while (CurC != '\0') {
if (SkipWhitespace (0)) {
/* Squeeze runs of blanks */
if (!IsSpace (SB_LookAtLast (Target))) {
SB_AppendChar (Target, ' ');
}
} else if (IsSym (Ident)) {
if (Preprocessing && strcmp (Ident, "defined") == 0) {
/* Handle the "defined" operator */
SkipWhitespace (0);
HaveParen = 0;
if (CurC == '(') {
HaveParen = 1;
NextChar ();
SkipWhitespace (0);
}
if (IsSym (Ident)) {
SB_AppendChar (Target, IsMacro (Ident)? '1' : '0');
if (HaveParen) {
SkipWhitespace (0);
if (CurC != ')') {
PPError ("`)' expected");
} else {
NextChar ();
}
}
} else {
PPError ("Identifier expected");
SB_AppendChar (Target, '0');
}
} else {
++IdentCount;
SB_AppendStr (Target, Ident);
}
} else if (IsQuote (CurC)) {
CopyQuotedString (Target);
} else if (CurC == '/' && NextC == '*') {
if (!IsSpace (SB_LookAtLast (Target))) {
SB_AppendChar (Target, ' ');
}
OldStyleComment ();
} else if (IS_Get (&Standard) >= STD_C99 && CurC == '/' && NextC == '/') {
if (!IsSpace (SB_LookAtLast (Target))) {
SB_AppendChar (Target, ' ');
}
NewStyleComment ();
} else {
SB_AppendChar (Target, CurC);
NextChar ();
}
}
/* Switch back to the old source */
InitLine (OldSource);
/* Return the number of identifiers found in the line */
return IdentCount;
}
static void MacroArgSubst (MacroExp* E)
/* Argument substitution according to ISO/IEC 9899:1999 (E), 6.10.3.1ff */
{
ident Ident;
int ArgIdx;
StrBuf* OldSource;
StrBuf* Arg;
int HaveSpace;
/* Remember the current input and switch to the macro replacement. */
int OldIndex = SB_GetIndex (&E->M->Replacement);
SB_Reset (&E->M->Replacement);
OldSource = InitLine (&E->M->Replacement);
/* Argument handling loop */
while (CurC != '\0') {
/* If we have an identifier, check if it's a macro */
if (IsSym (Ident)) {
/* Check if it's a macro argument */
if ((ArgIdx = FindMacroArg (E->M, Ident)) >= 0) {
/* A macro argument. Get the corresponding actual argument. */
Arg = ME_GetActual (E, ArgIdx);
/* Copy any following whitespace */
HaveSpace = SkipWhitespace (0);
/* If a ## operator follows, we have to insert the actual
* argument as is, otherwise it must be macro replaced.
*/
if (CurC == '#' && NextC == '#') {
/* ### Add placemarker if necessary */
SB_Append (&E->Replacement, Arg);
} else {
/* Replace the formal argument by a macro replaced copy
* of the actual.
*/
SB_Reset (Arg);
MacroReplacement (Arg, &E->Replacement);
/* If we skipped whitespace before, re-add it now */
if (HaveSpace) {
SB_AppendChar (&E->Replacement, ' ');
}
}
} else {
/* An identifier, keep it */
SB_AppendStr (&E->Replacement, Ident);
}
} else if (CurC == '#' && NextC == '#') {
/* ## operator. */
NextChar ();
NextChar ();
SkipWhitespace (0);
/* Since we need to concatenate the token sequences, remove
* any whitespace that was added to target, since it must come
* from the input.
*/
while (IsSpace (SB_LookAtLast (&E->Replacement))) {
SB_Drop (&E->Replacement, 1);
}
/* If the next token is an identifier which is a macro argument,
* replace it, otherwise do nothing.
*/
if (IsSym (Ident)) {
/* Check if it's a macro argument */
if ((ArgIdx = FindMacroArg (E->M, Ident)) >= 0) {
/* Get the corresponding actual argument and add it. */
SB_Append (&E->Replacement, ME_GetActual (E, ArgIdx));
} else {
/* Just an ordinary identifier - add as is */
SB_AppendStr (&E->Replacement, Ident);
}
}
} else if (CurC == '#' && E->M->ArgCount >= 0) {
/* A # operator within a macro expansion of a function like
* macro. Read the following identifier and check if it's a
* macro parameter.
*/
NextChar ();
SkipWhitespace (0);
if (!IsSym (Ident) || (ArgIdx = FindMacroArg (E->M, Ident)) < 0) {
PPError ("`#' is not followed by a macro parameter");
} else {
/* Make a valid string from Replacement */
Arg = ME_GetActual (E, ArgIdx);
SB_Reset (Arg);
Stringize (Arg, &E->Replacement);
}
} else if (IsQuote (CurC)) {
CopyQuotedString (&E->Replacement);
} else {
SB_AppendChar (&E->Replacement, CurC);
NextChar ();
}
}
#if 0
/* Remove whitespace from the end of the line */
while (IsSpace (SB_LookAtLast (&E->Replacement))) {
SB_Drop (&E->Replacement, 1);
}
#endif
/* Switch back the input */
InitLine (OldSource);
SB_SetIndex (&E->M->Replacement, OldIndex);
}
void ModelClass::SetFromXml(wxXmlNode* ModelNode, bool zeroBased)
{
wxString tempstr,channelstr;
wxString customModel,RGBorder;
long degrees, StartChannel, channel;
size_t i;
ModelXml=ModelNode;
TreeDegrees=0;
StrobeRate=0;
Nodes.clear();
name=ModelNode->GetAttribute("name");
DisplayAs=ModelNode->GetAttribute("DisplayAs");
if (ModelNode->HasAttribute("StringType"))
{
// post 3.1.4
StringType=ModelNode->GetAttribute("StringType");
}
else
{
// 3.1.4 and earlier
StringType=ModelNode->GetAttribute("Order","RGB")+" Nodes";
}
SingleNode=HasSingleNode(StringType);
SingleChannel=HasSingleChannel(StringType);
RGBorder=SingleNode ? "RGB" : RGBorder=StringType.Left(3);
rgbidx[0]=std::max(RGBorder.Find('R'),0);
rgbidx[1]=std::max(RGBorder.Find('G'),0);
rgbidx[2]=std::max(RGBorder.Find('B'),0);
tempstr=ModelNode->GetAttribute("parm1");
tempstr.ToLong(&parm1);
tempstr=ModelNode->GetAttribute("parm2");
tempstr.ToLong(&parm2);
tempstr=ModelNode->GetAttribute("parm3");
tempstr.ToLong(&parm3);
tempstr=ModelNode->GetAttribute("StartChannel","1");
tempstr.ToLong(&StartChannel);
tempstr=ModelNode->GetAttribute("Dir");
IsLtoR=tempstr != "R";
if (ModelNode->HasAttribute("StartSide"))
{
tempstr=ModelNode->GetAttribute("StartSide");
isBotToTop = (tempstr == "B");
}
else
{
isBotToTop=true;
}
tempstr=ModelNode->GetAttribute("Antialias","0");
tempstr.ToLong(&Antialias);
AliasFactor=1 << Antialias;
MyDisplay=IsMyDisplay(ModelNode);
tempstr=ModelNode->GetAttribute("offsetXpct","0");
tempstr.ToDouble(&offsetXpct);
tempstr=ModelNode->GetAttribute("offsetYpct","0");
tempstr.ToDouble(&offsetYpct);
tempstr=ModelNode->GetAttribute("PreviewScale","0.333");
tempstr.ToDouble(&PreviewScale);
tempstr=ModelNode->GetAttribute("PreviewRotation","0");
tempstr.ToLong(°rees);
PreviewRotation=degrees;
// calculate starting channel numbers for each string
size_t NumberOfStrings= HasOneString(DisplayAs) ? 1 : parm1;
int ChannelsPerString=parm2*3;
if (SingleChannel)
ChannelsPerString=1;
else if (SingleNode)
ChannelsPerString=3;
if (ModelNode->HasAttribute("CustomModel"))
{
customModel = ModelNode->GetAttribute("CustomModel");
int maxval=GetCustomMaxChannel(customModel);
// fix NumberOfStrings
if (SingleNode)
{
NumberOfStrings=maxval;
}
else
{
ChannelsPerString=maxval*3;
}
}
tempstr=ModelNode->GetAttribute("Advanced","0");
bool HasIndividualStartChans=tempstr == "1";
stringStartChan.clear();
stringStartChan.resize(NumberOfStrings);
for (i=0; i<NumberOfStrings; i++)
{
tempstr=StartChanAttrName(i);
if (!zeroBased && HasIndividualStartChans && ModelNode->HasAttribute(tempstr))
{
ModelNode->GetAttribute(tempstr, &channelstr);
channelstr.ToLong(&channel);
stringStartChan[i] = channel-1;
}
else
{
stringStartChan[i] = (zeroBased? 0 : StartChannel-1) + i*ChannelsPerString;
}
}
// initialize model based on the DisplayAs value
wxStringTokenizer tkz(DisplayAs, " ");
wxString token = tkz.GetNextToken();
if (token == "Tree")
{
InitVMatrix();
token = tkz.GetNextToken();
token.ToLong(°rees);
SetTreeCoord(degrees);
}
else if (DisplayAs == "Custom")
{
InitCustomMatrix(customModel);
CopyBufCoord2ScreenCoord();
}
else if (DisplayAs == "Vert Matrix")
{
InitVMatrix();
CopyBufCoord2ScreenCoord();
}
else if (DisplayAs == "Horiz Matrix")
{
InitHMatrix();
CopyBufCoord2ScreenCoord();
}
else if (DisplayAs == "Single Line")
{
InitLine();
SetLineCoord();
}
else if (DisplayAs == "Arches")
{
InitHMatrix(); // Old call was InitLine();
SetArchCoord();
}
else if (DisplayAs == "Window Frame")
{
InitFrame();
CopyBufCoord2ScreenCoord();
}
else if (DisplayAs == "Star")
{
InitStar();
CopyBufCoord2ScreenCoord();
}
else if (DisplayAs == "Wreath")
{
InitWreath();
CopyBufCoord2ScreenCoord();
}
size_t NodeCount=GetNodeCount();
for(size_t i=0; i<NodeCount; i++)
{
Nodes[i]->sparkle = rand() % 10000;
}
}
void CAdActor::GetNextStep()
{
if(m_WalkSprite)
{
m_CurrentSprite = m_WalkSprite->GetSprite(m_Dir);
}
else
{
CAdSpriteSet* Anim = GetAnimByName(m_WalkAnimName);
if(Anim) m_CurrentSprite = Anim->GetSprite(m_Dir);
}
if(!m_CurrentSprite) return;
m_CurrentSprite->GetCurrentFrame(m_Zoomable?((CAdGame*)Game)->m_Scene->GetZoomAt(m_PosX, m_PosY):100, m_Zoomable?((CAdGame*)Game)->m_Scene->GetZoomAt(m_PosX, m_PosY):100);
if(!m_CurrentSprite->m_Changed) return;
int MaxStepX, MaxStepY;
MaxStepX = abs(m_CurrentSprite->m_MoveX);
MaxStepY = abs(m_CurrentSprite->m_MoveY);
MaxStepX = max(MaxStepX, MaxStepY);
MaxStepX = max(MaxStepX, 1);
while(m_PFCount > 0 && MaxStepX >= 0)
{
m_PFX += m_PFStepX;
m_PFY += m_PFStepY;
m_PFCount--;
MaxStepX--;
}
if(((CAdGame*)Game)->m_Scene->IsBlockedAt(m_PFX, m_PFY, true, this))
{
if(m_PFCount==0)
{
m_State = m_NextState;
m_NextState = STATE_READY;
return;
}
GoTo(m_TargetPoint->x, m_TargetPoint->y);
return;
}
m_PosX = (int)m_PFX;
m_PosY = (int)m_PFY;
AfterMove();
if(m_PFCount == 0)
{
if(m_Path->GetNext()==NULL)
{
m_PosX = m_TargetPoint->x;
m_PosY = m_TargetPoint->y;
m_Path->Reset();
if(m_AfterWalkDir!=DI_NONE) TurnTo(m_AfterWalkDir);
else
{
m_State = m_NextState;
m_NextState = STATE_READY;
}
}
else InitLine(CBPoint(m_PosX, m_PosY), *m_Path->GetCurrent());
}
}
int NextLine (void)
/* Get a line from the current input. Returns 0 on end of file. */
{
AFile* Input;
/* Clear the current line */
ClearLine ();
/* If there is no file open, bail out, otherwise get the current input file */
if (CollCount (&AFiles) == 0) {
return 0;
}
Input = CollLast (&AFiles);
/* Read characters until we have one complete line */
while (1) {
/* Read the next character */
int C = fgetc (Input->F);
/* Check for EOF */
if (C == EOF) {
/* Accept files without a newline at the end */
if (SB_NotEmpty (Line)) {
++Input->Line;
break;
}
/* Leave the current file */
CloseIncludeFile ();
/* If there is no file open, bail out, otherwise get the
* previous input file and start over.
*/
if (CollCount (&AFiles) == 0) {
return 0;
}
Input = CollLast (&AFiles);
continue;
}
/* Check for end of line */
if (C == '\n') {
/* We got a new line */
++Input->Line;
/* If the \n is preceeded by a \r, remove the \r, so we can read
* DOS/Windows files under *nix.
*/
if (SB_LookAtLast (Line) == '\r') {
SB_Drop (Line, 1);
}
/* If we don't have a line continuation character at the end,
* we're done with this line. Otherwise replace the character
* by a newline and continue reading.
*/
if (SB_LookAtLast (Line) == '\\') {
Line->Buf[Line->Len-1] = '\n';
} else {
break;
}
} else if (C != '\0') { /* Ignore embedded NULs */
/* Just some character, add it to the line */
SB_AppendChar (Line, C);
}
}
/* Add a termination character to the string buffer */
SB_Terminate (Line);
/* Initialize the current and next characters. */
InitLine (Line);
/* Create line information for this line */
UpdateLineInfo (Input->Input, Input->Line, Line);
/* Done */
return 1;
}
