int main() {
HRESULT hr = CoInitializeEx(NULL, COINIT_MULTITHREADED);
if (SUCCEEDED(hr)) {
IPingable * ptrPingable;
HRESULT hr = CoCreateInstance(CLSID_CoPingEngine, NULL, CLSCTX_LOCAL_SERVER, IID_IPingable, reinterpret_cast<void**>(&ptrPingable));
if (SUCCEEDED(hr)) {
ptrPingable->Initialize();
StatusResponse status;
ptrPingable->Ping(12345, &status);
printf("Status for ping code 12345: %d %S\n", status.Code, status.Description);
ptrPingable->Ping(777, &status);
printf("Status for ping code 777: %d %S\n", status.Code, status.Description);
ptrPingable->Ping(1800, &status);
printf("Status for ping code 1800: %d %S\n", status.Code, status.Description);
CComVariant history;
hr = ptrPingable->RetrieveHistory(&history);
if (SUCCEEDED(hr)) {
printHistory(history);
}
else {
DisplayStatus(TEXT("RetrieveHistory failed: \n"), hr);
}
// Try creating a larger history
printf("Sending more pings...\n");
for (int i = 0; i < 16; i++) {
ptrPingable->Ping(i, &status);
}
hr = ptrPingable->RetrieveHistory(&history);
if (SUCCEEDED(hr)) {
printHistory(history);
}
else {
DisplayStatus(TEXT("RetrieveHistory failed: \n"), hr);
}
SysFreeString(status.Description);
ptrPingable->Release();
}
else {
DisplayStatus(TEXT("CoCreateInstance(CoPingEngine) failed: "), hr);
}
CoUninitialize();
}
else {
DisplayStatus(TEXT("CoInitializeEx failed: "), hr);
}
return 0;
}
void EDA_3D_CANVAS::OnMouseWheel( wxMouseEvent& event )
{
if( event.ShiftDown() )
{
if( event.GetWheelRotation() < 0 )
SetView3D( WXK_UP ); // move up
else
SetView3D( WXK_DOWN ); // move down
}
else if( event.ControlDown() )
{
if( event.GetWheelRotation() > 0 )
SetView3D( WXK_RIGHT ); // move right
else
SetView3D( WXK_LEFT ); // move left
}
else
{
if( event.GetWheelRotation() > 0 )
{
GetPrm3DVisu().m_Zoom /= 1.4;
if( GetPrm3DVisu().m_Zoom <= 0.01 )
GetPrm3DVisu().m_Zoom = 0.01;
}
else
GetPrm3DVisu().m_Zoom *= 1.4;
DisplayStatus();
Refresh( false );
}
GetPrm3DVisu().m_Beginx = event.GetX();
GetPrm3DVisu().m_Beginy = event.GetY();
}
EDA_3D_CANVAS::EDA_3D_CANVAS( EDA_3D_FRAME* parent, int* attribList ) :
wxGLCanvas( parent, wxID_ANY, attribList, wxDefaultPosition, wxDefaultSize,
wxFULL_REPAINT_ON_RESIZE )
{
m_init = false;
m_reportWarnings = true;
m_shadow_init = false;
// set an invalide value to not yet initialized indexes managing
// textures created to enhance 3D rendering
m_text_pcb = m_text_silk = INVALID_INDEX;
m_text_fake_shadow_front = INVALID_INDEX;
m_text_fake_shadow_back = INVALID_INDEX;
m_text_fake_shadow_board = INVALID_INDEX;
// position of the front and back layers
// (will be initialized to a better value later)
m_ZBottom = 0.0;
m_ZTop = 0.0;
m_lightPos = S3D_VERTEX(0.0f, 0.0f, 30.0f);
// Clear all gl list identifiers:
for( int ii = GL_ID_BEGIN; ii < GL_ID_END; ii++ )
m_glLists[ii] = 0;
// Explicitly create a new rendering context instance for this canvas.
m_glRC = new wxGLContext( this );
DisplayStatus();
}
void CVPCB_MAINFRAME::DelAssociations( wxCommandEvent& event )
{
if( IsOK( this, _( "Delete selections" ) ) )
{
m_skipComponentSelect = true;
// Remove all selections to avoid issues when setting the fpids
m_compListBox->DeselectAll();
for( unsigned i = 0; i < m_netlist.GetCount(); i++ )
{
FPID fpid;
m_netlist.GetComponent( i )->SetFPID( fpid );
SetNewPkg( wxEmptyString );
}
// Remove all selections after setting the fpids
m_compListBox->DeselectAll();
m_skipComponentSelect = false;
m_compListBox->SetSelection( 0 );
m_undefinedComponentCnt = m_netlist.GetCount();
}
DisplayStatus();
}
void Main_OnDisplay( HWND hWnd )
{
TCHAR strAppName[MAX_PATH]={0};
TCHAR strBlock[10]={0};
TCHAR* pEnd=nullptr;
TABLEDLG_DATA tblDlgData={0};
// Get the appname, the selected block ID & the selected
// language. Create the string block. If the block creation is successful,
// bring up the table dialog box.
CWindow wnd(hWnd);
if (!wnd.GetDlgItemText(IDC_EDIT_APPNAME, strAppName, MAX_PATH))
{
DisplayMsg(hWnd, IDS_INVALIDAPPNAME);
return;
}
CComboBox combo(wnd.GetDlgItem(IDC_COMBO_LANGUAGES));
int nSel = combo.GetCurSel();
if( CB_ERR == nSel )
{
DisplayMsg(hWnd, IDS_INVALIDLANGUAGE);
return;
}
if (!wnd.GetDlgItemText(IDC_EDIT_BLOCKID, strBlock, _countof(strBlock)))
{
DisplayMsg(hWnd, IDS_INVALIDBLOCKID);
return;
}
UINT nBlockID = _tcstoul(strBlock, &pEnd, 10);
if( *pEnd != 0 )
{
DisplayMsg(hWnd, IDS_INVALIDBLOCKID);
return;
}
HSTRBLOCK hStrBlock = GetStringBlock(strAppName, nBlockID, s_langInfo[nSel].wLangID);
if( nullptr == hStrBlock )
{
DisplayStatus(hWnd, GetStringBlockError());
return;
}
// Show up the table dialog-box that displays the string block.
tblDlgData.strAppName = strAppName;
tblDlgData.nBlockID = nBlockID;
tblDlgData.wStrID = static_cast<WORD>(s_langInfo[nSel].nStrID);
tblDlgData.hStrBlock = hStrBlock;
DialogBoxParam(GetAppInstance(), MAKEINTRESOURCE(IDD_DIALOG_TABLE), hWnd,
Table_DlgProc, reinterpret_cast<LPARAM>(&tblDlgData));
// Delete the string block.
DeleteStringBlock(hStrBlock);
}
EDA_3D_CANVAS::EDA_3D_CANVAS( EDA_3D_FRAME* parent, int* attribList ) :
wxGLCanvas( parent, wxID_ANY, attribList, wxDefaultPosition, wxDefaultSize,
wxFULL_REPAINT_ON_RESIZE )
{
m_init = false;
m_gllist = 0;
// Explicitly create a new rendering context instance for this canvas.
m_glRC = new wxGLContext( this );
DisplayStatus();
}
void CVPCB_MAINFRAME::refreshAfterComponentSearch( COMPONENT* component )
{
// Tell AuiMgr that objects are changed !
if( m_auimgr.GetManagedWindow() ) // Be sure Aui Manager is initialized
// (could be not the case when starting CvPcb
m_auimgr.Update();
if( component == NULL )
return;
// Preview of the already assigned footprint.
// Find the footprint that was already chosen for this component and select it,
// but only if the selection is made from the component list or the library list.
// If the selection is made from the footprint list, do not change the current
// selected footprint.
if( FindFocus() == m_compListBox || FindFocus() == m_libListBox )
{
wxString module = FROM_UTF8( component->GetFPID().Format().c_str() );
bool found = false;
for( int ii = 0; ii < m_footprintListBox->GetCount(); ii++ )
{
wxString footprintName;
wxString msg = m_footprintListBox->OnGetItemText( ii, 0 );
msg.Trim( true );
msg.Trim( false );
footprintName = msg.AfterFirst( wxChar( ' ' ) );
if( module.Cmp( footprintName ) == 0 )
{
m_footprintListBox->SetSelection( ii, true );
found = true;
break;
}
}
if( !found )
{
int ii = m_footprintListBox->GetSelection();
if ( ii >= 0 )
m_footprintListBox->SetSelection( ii, false );
if( GetFootprintViewerFrame() )
{
CreateScreenCmp();
}
}
}
SendMessageToEESCHEMA();
DisplayStatus();
}
void EDA_3D_CANVAS::OnMagnify( wxMouseEvent& event )
{
double magnification = ( event.GetMagnification() + 1.0f );
GetPrm3DVisu().m_Zoom /= magnification;
if( GetPrm3DVisu().m_Zoom <= 0.01 )
GetPrm3DVisu().m_Zoom = 0.01;
DisplayStatus();
Refresh( false );
}
INT PageHeap_Execute()
{
if (!Set && !Unset)
{
DisplayStatus();
}
else
{
ModifyStatus();
}
return 0;
}
void EDA_3D_CANVAS::OnMouseWheel( wxMouseEvent& event )
{
wxSize size( GetClientSize() );
if( event.ShiftDown() )
{
if( event.GetWheelRotation() < 0 )
{
/* up */
SetView3D( WXK_UP );
}
else
{
/* down */
SetView3D( WXK_DOWN );
}
}
else if( event.ControlDown() )
{
if( event.GetWheelRotation() > 0 )
{
/* right */
SetView3D( WXK_RIGHT );
}
else
{
/* left */
SetView3D( WXK_LEFT );
}
}
else
{
if( event.GetWheelRotation() > 0 )
{
g_Parm_3D_Visu.m_Zoom /= 1.4;
if( g_Parm_3D_Visu.m_Zoom <= 0.01 )
g_Parm_3D_Visu.m_Zoom = 0.01;
}
else
g_Parm_3D_Visu.m_Zoom *= 1.4;
DisplayStatus();
Refresh( false );
}
g_Parm_3D_Visu.m_Beginx = event.GetX();
g_Parm_3D_Visu.m_Beginy = event.GetY();
}
EDA_3D_CANVAS::EDA_3D_CANVAS( EDA_3D_FRAME* parent, int* attribList ) :
wxGLCanvas( parent, wxID_ANY, attribList, wxDefaultPosition, wxDefaultSize,
wxFULL_REPAINT_ON_RESIZE )
{
m_init = false;
m_shadow_init = false;
// Clear all gl list identifiers:
for( int ii = GL_ID_BEGIN; ii < GL_ID_END; ii++ )
m_glLists[ii] = 0;
// Explicitly create a new rendering context instance for this canvas.
m_glRC = new wxGLContext( this );
DisplayStatus();
}
void CVPCB_MAINFRAME::BuildFOOTPRINTS_LISTBOX()
{
wxFont guiFont = wxSystemSettings::GetFont( wxSYS_DEFAULT_GUI_FONT );
if( m_footprintListBox == NULL )
{
m_footprintListBox = new FOOTPRINTS_LISTBOX( this, ID_CVPCB_FOOTPRINT_LIST,
wxDefaultPosition, wxDefaultSize );
m_footprintListBox->SetFont( wxFont( guiFont.GetPointSize(),
wxFONTFAMILY_MODERN,
wxFONTSTYLE_NORMAL,
wxFONTWEIGHT_NORMAL ) );
}
m_footprintListBox->SetFootprints( m_footprints, wxEmptyString, NULL,
FOOTPRINTS_LISTBOX::UNFILTERED );
DisplayStatus();
}
/*!
* \brief Start background thread for display updates.
*
* \param name Display device name.
*
* \return 0 on success or -1 in case of a failure.
*/
int DisplayInit(char *name)
{
if ((lcd = fopen(name, "w")) == 0)
return -1;
if ((sline[0] = malloc(DISPLAY_VCOLUMNS + 1)) == 0 ||
(sline[1] = malloc(DISPLAY_VCOLUMNS + 1)) == 0 ||
(mline[0] = malloc(DISPLAY_VCOLUMNS + 1)) == 0 || (mline[1] = malloc(DISPLAY_VCOLUMNS + 1)) == 0)
return -1;
sline[0][DISPLAY_VCOLUMNS] = 0;
sline[1][DISPLAY_VCOLUMNS] = 0;
if (NutThreadCreate("displ", Displayer, 0, 512) == 0)
return -1;
DisplayStatus(DIST_NONE);
return 0;
}
void CVPCB_MAINFRAME::SetNewPkg( const wxString& aFootprintName )
{
COMPONENT* component;
int componentIndex;
if( m_netlist.IsEmpty() )
return;
// If no component is selected, select the first one
if( m_compListBox->GetFirstSelected() < 0 )
{
componentIndex = 0;
m_compListBox->SetSelection( componentIndex, true );
}
// iterate over the selection
while( m_compListBox->GetFirstSelected() != -1 )
{
// Get the component for the current iteration
componentIndex = m_compListBox->GetFirstSelected();
component = m_netlist.GetComponent( componentIndex );
if( component == NULL )
return;
SetNewPkg( aFootprintName, componentIndex );
m_compListBox->SetSelection( componentIndex, false );
}
// select the next component, if there is one
if( componentIndex < (m_compListBox->GetCount() - 1) )
componentIndex++;
m_compListBox->SetSelection( componentIndex, true );
// update the statusbar
DisplayStatus();
}
void EDA_3D_CANVAS::OnMouseMove( wxMouseEvent& event )
{
wxSize size( GetClientSize() );
double spin_quat[4];
if( event.Dragging() )
{
if( event.LeftIsDown() )
{
/* drag in progress, simulate trackball */
trackball( spin_quat,
(2.0 * g_Parm_3D_Visu.m_Beginx - size.x) / size.x,
(size.y - 2.0 * g_Parm_3D_Visu.m_Beginy) / size.y,
( 2.0 * event.GetX() - size.x) / size.x,
( size.y - 2.0 * event.GetY() ) / size.y );
add_quats( spin_quat, g_Parm_3D_Visu.m_Quat, g_Parm_3D_Visu.m_Quat );
}
else if( event.MiddleIsDown() )
{
/* middle button drag -> pan */
/* Current zoom and an additional factor are taken into account
* for the amount of panning. */
const double PAN_FACTOR = 8.0 * g_Parm_3D_Visu.m_Zoom;
m_draw3dOffset.x -= PAN_FACTOR *
( g_Parm_3D_Visu.m_Beginx - event.GetX() ) / size.x;
m_draw3dOffset.y -= PAN_FACTOR *
(event.GetY() - g_Parm_3D_Visu.m_Beginy) / size.y;
}
/* orientation has changed, redraw mesh */
DisplayStatus();
Refresh( false );
}
g_Parm_3D_Visu.m_Beginx = event.GetX();
g_Parm_3D_Visu.m_Beginy = event.GetY();
}
void CVPCB_MAINFRAME::SetNewPkg( const wxString& aFootprintName, int aIndex )
{
COMPONENT* component;
if( m_netlist.IsEmpty() )
return;
component = m_netlist.GetComponent( aIndex );
if( component == NULL )
return;
LIB_ID fpid;
if( !aFootprintName.IsEmpty() )
{
wxCHECK_RET( fpid.Parse( aFootprintName, LIB_ID::ID_PCB ) < 0,
wxString::Format( _( "\"%s\" is not a valid LIB_ID." ), aFootprintName ) );
}
component->SetFPID( fpid );
// create the new component description
wxString description = wxString::Format( CMP_FORMAT, aIndex + 1,
GetChars( component->GetReference() ),
GetChars( component->GetValue() ),
GetChars( FROM_UTF8( component->GetFPID().Format().c_str() ) ) );
// Set the new description and deselect the processed component
m_compListBox->SetString( aIndex, description );
// Mark this "session" as modified
m_modified = true;
// update the statusbar
DisplayStatus();
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
uint_fast32_t ui32TxCount;
uint_fast32_t ui32RxCount;
tRectangle sRect;
char pcBuffer[16];
//
// Enable lazy stacking for interrupt handlers. This allows floating-point
// instructions to be used within interrupt handlers, but at the expense of
// extra stack usage.
//
ROM_FPULazyStackingEnable();
//
// Set the clocking to run from the PLL at 50MHz
//
ROM_SysCtlClockSet(SYSCTL_SYSDIV_4 | SYSCTL_USE_PLL | SYSCTL_OSC_MAIN |
SYSCTL_XTAL_16MHZ);
#ifdef DEBUG
//
// Configure the UART for debug output.
//
ConfigureUART();
#endif
//
// Not configured initially.
//
g_bUSBConfigured = false;
//
// Initialize the display driver.
//
CFAL96x64x16Init();
//
// Initialize the graphics context.
//
GrContextInit(&g_sContext, &g_sCFAL96x64x16);
//
// Fill the top part of the screen with blue to create the banner.
//
sRect.i16XMin = 0;
sRect.i16YMin = 0;
sRect.i16XMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.i16YMax = 9;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Change foreground for white text.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
//
// Put the application name in the middle of the banner.
//
GrContextFontSet(&g_sContext, g_psFontFixed6x8);
GrStringDrawCentered(&g_sContext, "usb-dev-bulk", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 4, 0);
//
// Show the various static text elements on the color STN display.
//
GrStringDraw(&g_sContext, "Tx bytes:", -1, 0, 32, false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, 0, 42, false);
//
// Enable the GPIO peripheral used for USB, and configure the USB
// pins.
//
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOB);
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOL);
ROM_GPIOPinTypeUSBAnalog(GPIO_PORTB_BASE, GPIO_PIN_0 | GPIO_PIN_1);
ROM_GPIOPinTypeUSBAnalog(GPIO_PORTL_BASE, GPIO_PIN_6 | GPIO_PIN_7);
//
// Enable the system tick.
//
ROM_SysTickPeriodSet(ROM_SysCtlClockGet() / SYSTICKS_PER_SECOND);
ROM_SysTickIntEnable();
ROM_SysTickEnable();
//
// Show the application name on the display and UART output.
//
DEBUG_PRINT("\nTiva C Series USB bulk device example\n");
DEBUG_PRINT("---------------------------------\n\n");
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, "Configuring USB");
//
// Initialize the transmit and receive buffers.
//
USBBufferInit(&g_sTxBuffer);
USBBufferInit(&g_sRxBuffer);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDBulkInit(0, &g_sBulkDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, "Waiting for host");
//
// Clear our local byte counters.
//
ui32RxCount = 0;
ui32TxCount = 0;
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(g_ui32Flags & COMMAND_STATUS_UPDATE)
{
//
// Clear the command flag
//
g_ui32Flags &= ~COMMAND_STATUS_UPDATE;
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ui32TxCount != g_ui32TxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ui32TxCount = g_ui32TxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, " %d ", ui32TxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 48, 32, true);
}
//
// Has there been any receive traffic since we last checked?
//
if(ui32RxCount != g_ui32RxCount)
{
//
// Take a snapshot of the latest receive count.
//
ui32RxCount = g_ui32RxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, " %d ", ui32RxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 48, 42, true);
}
}
}
void PlayLoop (void)
{
id0_char_t shot_color[3] = {4,9,14};
id0_int_t allgems[5]={GEM_DELAY_TIME, // used for Q & D comparison
GEM_DELAY_TIME, // for having all gems...
GEM_DELAY_TIME, // the "allgems" declaration MUST
GEM_DELAY_TIME, // match the "gems" declaration in
GEM_DELAY_TIME // the gametype structure!
};
// id0_int_t originx=0;
// id0_int_t i=100;
id0_signed_long_t dx,dy/*,radius*/,psin,pcos,newx,newy;
//id0_int_t give;
id0_short_t objnum;
id0_signed_long_t ox,oy,xl,xh,yl,yh,px,py,norm_dx,norm_dy;
id0_short_t o_radius;
void (*think)(struct objstruct *); // REFKEEN: C++ patch
ingame = true;
SD_SetTimeCount(0);
playstate = (exittype)0;
//playstate = TimeCount = 0;
gamestate.shotpower = handheight = 0;
pointcount = pointsleft = 0;
status_flag = S_NONE;
#if 0
// setup sky/ground colors and effects (based on level)
//
switch (gamestate.mapon)
{
case 255:
if (!(BGFLAGS & BGF_NIGHT))
{
InitBgChange(3*60,sky_daytonight,-1,NULL,BGF_NIGHT);
groundcolor = &gnd_colors[0];
}
else
{
skycolor = &sky_colors[0];
groundcolor = &gnd_colors[0];
}
break;
default:
skycolor = &sky_colors[gamestate.mapon];
groundcolor = &gnd_colors[gamestate.mapon];
skytimer = groundtimer = -1;
break;
}
#endif
BGFLAGS |= BGF_NOT_LIGHTNING;
skytimer = groundtimer = -1;
debug_gnd = *groundcolor;
debug_sky = *skycolor;
RedrawStatusWindow();
ThreeDRefresh();
if (screenfaded)
VW_FadeIn();
#ifndef PROFILE
fizzlein = true; // fizzle fade in the first refresh
#endif
/*TimeCount = */lasttimecount = lastnuke = 0;
SD_SetTimeCount(0);
PollControls (); // center mouse
// StartMusic ();
do
{
#ifndef PROFILE
PollControls();
#else
control.xaxis = 1;
//if (++TimeCount == 300)
// return;
SD_AddToTimeCount(1);
if (SD_GetTimeCount() == 300)
return;
#endif
DisplayStatus(&status_flag);
objnum=0;
for (obj = player;obj;obj = obj->next)
{
if ((obj->active >= yes) && (!(FreezeTime && (obj!=player))))
{
if (obj->ticcount)
{
obj->ticcount-=realtics;
while ( obj->ticcount <= 0)
{
think = obj->state->thinkptr;
if (think)
{
statetype *oldstate=obj->state;
think (obj);
if (!obj->state)
{
RemoveObj (obj);
goto nextactor;
}
if (obj->state != oldstate)
break;
}
obj->state = obj->state->next;
if (!obj->state)
{
RemoveObj (obj);
goto nextactor;
}
if (!obj->state->tictime)
{
obj->ticcount = 0;
goto nextactor;
}
if (obj->state->tictime>0)
obj->ticcount += obj->state->tictime;
}
}
think = obj->state->thinkptr;
if (think)
{
think (obj);
if (!obj->state)
RemoveObj (obj);
}
nextactor:;
}
// keep a list of objects around the player for radar updates
//
if (obj == player)
{
px = player->x;
py = player->y;
psin = sintable[player->angle];
pcos = costable[player->angle];
xl = px-((id0_long_t)RADAR_WIDTH<<TILESHIFT)/2;
xh = px+((id0_long_t)RADAR_WIDTH<<TILESHIFT)/2-1;
yl = py-((id0_long_t)RADAR_HEIGHT<<TILESHIFT)/2;
yh = py+((id0_long_t)RADAR_HEIGHT<<TILESHIFT)/2;
}
if (objnum > MAX_RADAR_BLIPS-2)
objnum = MAX_RADAR_BLIPS-2;
ox = obj->x;
oy = obj->y;
if ((ox >= xl) && (ox <= xh) && (oy >= yl) && (oy <= yh))
{
norm_dx = (dx = px-ox)>>TILESHIFT;
norm_dy = (dy = oy-py)>>TILESHIFT;
id0_int_t IntSqrt(id0_long_t va);
o_radius = IntSqrt((norm_dx * norm_dx) + (norm_dy * norm_dy));
if (o_radius < RADAR_RADIUS)
{
newx = FixedByFrac(dy,pcos)-FixedByFrac(dx,psin);
newy = FixedByFrac(dy,psin)+FixedByFrac(dx,pcos);
RadarXY[objnum][0]=newx>>TILESHIFT;
RadarXY[objnum][1]=newy>>TILESHIFT;
// Define color to use for this object...
//
switch (obj->obclass)
{
// NO GEM NEEDED
//
// THE WIZARD! (YOU)
//
case playerobj:
RadarXY[objnum++][2]=15;
break;
// WIZARD'S SHOTS
//
case pshotobj:
case bigpshotobj:
RadarXY[objnum++][2]=shot_color[screenpage];
break;
// BATS (DK GRAY)
//
case batobj:
if (obj->active == always)
RadarXY[objnum++][2]=8;
break;
// RABBITS (LT GRAY)
//
case bunnyobj:
if (obj->active == always)
RadarXY[objnum++][2]=7;
break;
// RED GEM
//
// EYE, RED DEMON (DK RED)
//
case eyeobj:
case reddemonobj:
if (gamestate.gems[B_RGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=4;
break;
// RED MAGE (LT RED)
//
case mageobj:
if (gamestate.gems[B_RGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=12;
break;
// BLUE GEM
//
// SUCCUBUS (LT BLUE)
//
case succubusobj:
if (gamestate.gems[B_BGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=9;
break;
// WATER DRAGON (DK BLUE)
//
case wetobj:
if (gamestate.gems[B_GGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=1;
break;
// GREEN GEM
//
// GREEN TROLL (LT GREEN)
//
case fatdemonobj:
if (gamestate.gems[B_GGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=10;
break;
// GODESS (DK GREEN)
//
case godessobj:
if (gamestate.gems[B_GGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=2;
break;
// YELLOW GEM
//
// ANT (BROWN)
//
case antobj:
case treeobj:
if (gamestate.gems[B_YGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=6;
break;
// SKELETON (YELLOW)
//
case skeletonobj:
if (gamestate.gems[B_YGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=14;
break;
// PURPLE GEM
//
// ZOMBIE
//
case zombieobj:
if (gamestate.gems[B_PGEM-B_RGEM])
if (obj->active == always)
RadarXY[objnum++][2]=13;
break;
// ALL GEMS NEEDED
//
// NEMESIS
//
case grelmobj:
if (!memcmp(gamestate.gems,allgems,sizeof(gamestate.gems)))
if (obj->active == always)
RadarXY[objnum++][2]=15;
break;
}
}
}
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
uint32_t ui32TxCount;
uint32_t ui32RxCount;
tRectangle sRect;
char pcBuffer[16];
uint32_t ui32Fullness;
//
// Enable lazy stacking for interrupt handlers. This allows floating-point
// instructions to be used within interrupt handlers, but at the expense of
// extra stack usage.
//
ROM_FPULazyStackingEnable();
//
// Set the clocking to run from the PLL at 50MHz
//
ROM_SysCtlClockSet(SYSCTL_SYSDIV_4 | SYSCTL_USE_PLL | SYSCTL_OSC_MAIN |
SYSCTL_XTAL_16MHZ);
//
// Configure the required pins for USB operation.
//
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOB);
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOG);
ROM_GPIOPinConfigure(GPIO_PG4_USB0EPEN);
ROM_GPIOPinTypeUSBDigital(GPIO_PORTG_BASE, GPIO_PIN_4);
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOL);
ROM_GPIOPinTypeUSBAnalog(GPIO_PORTL_BASE, GPIO_PIN_6 | GPIO_PIN_7);
ROM_GPIOPinTypeUSBAnalog(GPIO_PORTB_BASE, GPIO_PIN_0 | GPIO_PIN_1);
//
// Erratum workaround for silicon revision A1. VBUS must have pull-down.
//
if(CLASS_IS_BLIZZARD && REVISION_IS_A1)
{
HWREG(GPIO_PORTB_BASE + GPIO_O_PDR) |= GPIO_PIN_1;
}
//
// Not configured initially.
//
g_bUSBConfigured = false;
//
// Initialize the display driver.
//
CFAL96x64x16Init();
//
// Initialize the graphics context.
//
GrContextInit(&g_sContext, &g_sCFAL96x64x16);
//
// Fill the top 15 rows of the screen with blue to create the banner.
//
sRect.i16XMin = 0;
sRect.i16YMin = 0;
sRect.i16XMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.i16YMax = 9;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Put a white box around the banner.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
//
// Put the application name in the middle of the banner.
//
GrContextFontSet(&g_sContext, g_psFontFixed6x8);
GrStringDrawCentered(&g_sContext, "usb-dev-serial", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 4, 0);
//
// Show the various static text elements on the color STN display.
//
GrStringDraw(&g_sContext, "Tx #",-1, 0, 12, false);
GrStringDraw(&g_sContext, "Tx buf", -1, 0, 22, false);
GrStringDraw(&g_sContext, "Rx #", -1, 0, 32, false);
GrStringDraw(&g_sContext, "Rx buf", -1, 0, 42, false);
DrawBufferMeter(&g_sContext, 40, 22);
DrawBufferMeter(&g_sContext, 40, 42);
//
// Enable the UART that we will be redirecting.
//
ROM_SysCtlPeripheralEnable(USB_UART_PERIPH);
//
// Enable and configure the UART RX and TX pins
//
ROM_SysCtlPeripheralEnable(TX_GPIO_PERIPH);
ROM_SysCtlPeripheralEnable(RX_GPIO_PERIPH);
ROM_GPIOPinTypeUART(TX_GPIO_BASE, TX_GPIO_PIN);
ROM_GPIOPinTypeUART(RX_GPIO_BASE, RX_GPIO_PIN);
//
// TODO: Add code to configure handshake GPIOs if required.
//
//
// Set the default UART configuration.
//
ROM_UARTConfigSetExpClk(USB_UART_BASE, ROM_SysCtlClockGet(),
DEFAULT_BIT_RATE, DEFAULT_UART_CONFIG);
ROM_UARTFIFOLevelSet(USB_UART_BASE, UART_FIFO_TX4_8, UART_FIFO_RX4_8);
//
// Configure and enable UART interrupts.
//
ROM_UARTIntClear(USB_UART_BASE, ROM_UARTIntStatus(USB_UART_BASE, false));
ROM_UARTIntEnable(USB_UART_BASE, (UART_INT_OE | UART_INT_BE | UART_INT_PE |
UART_INT_FE | UART_INT_RT | UART_INT_TX | UART_INT_RX));
//
// Enable the system tick.
//
ROM_SysTickPeriodSet(ROM_SysCtlClockGet() / SYSTICKS_PER_SECOND);
ROM_SysTickIntEnable();
ROM_SysTickEnable();
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, " Configuring... ");
//
// Initialize the transmit and receive buffers.
//
USBBufferInit(&g_sTxBuffer);
USBBufferInit(&g_sRxBuffer);
//
// Set the USB stack mode to Device mode with VBUS monitoring.
//
USBStackModeSet(0, eUSBModeDevice, 0);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDCDCInit(0, &g_sCDCDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, "Waiting for host");
//
// Clear our local byte counters.
//
ui32RxCount = 0;
ui32TxCount = 0;
//
// Enable interrupts now that the application is ready to start.
//
ROM_IntEnable(USB_UART_INT);
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(g_ui32Flags & COMMAND_STATUS_UPDATE)
{
//
// Clear the command flag
//
ROM_IntMasterDisable();
g_ui32Flags &= ~COMMAND_STATUS_UPDATE;
ROM_IntMasterEnable();
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ui32TxCount != g_ui32UARTTxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ui32TxCount = g_ui32UARTTxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ui32TxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 40, 12, true);
//
// Update the RX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's receive buffer is the UART's
// transmit buffer.
//
ui32Fullness = ((USBBufferDataAvailable(&g_sRxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ui32Fullness, 40, 22);
}
//
// Has there been any receive traffic since we last checked?
//
if(ui32RxCount != g_ui32UARTRxCount)
{
//
// Take a snapshot of the latest receive count.
//
ui32RxCount = g_ui32UARTRxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ui32RxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 40, 32, true);
//
// Update the TX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's transmit buffer is the UART's
// receive buffer.
//
ui32Fullness = ((USBBufferDataAvailable(&g_sTxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ui32Fullness, 40, 42);
}
}
}
// === Public functions
HRESULT TDXVADecoderVC1::DecodeFrame(BYTE* pDataIn, UINT nSize, REFERENCE_TIME rtStart, REFERENCE_TIME rtStop)
{
HRESULT hr;
int nSurfaceIndex;
CComPtr<IMediaSample> pSampleToDeliver;
int nFieldType, nSliceType;
UINT nFrameSize, nSize_Result;
m_pCodec->libavcodec->FFVC1UpdatePictureParam(&m_PictureParams, m_pCodec->avctx, &nFieldType, &nSliceType, pDataIn, nSize, &nFrameSize, FALSE, &m_bFrame_repeat_pict);
if (m_pCodec->libavcodec->FFIsSkipped(m_pCodec->avctx)) {
return S_OK;
}
// Wait I frame after a flush
if (m_bFlushed && ! m_PictureParams.bPicIntra) {
return S_FALSE;
}
hr = GetFreeSurfaceIndex(nSurfaceIndex, &pSampleToDeliver, rtStart, rtStop);
if (FAILED(hr)) {
ASSERT(hr == VFW_E_NOT_COMMITTED); // Normal when stop playing
return hr;
}
CHECK_HR(BeginFrame(nSurfaceIndex, pSampleToDeliver));
DPRINTF(_l("TDXVADecoderVC1::DecodeFrame - PictureType = %s, rtStart = %I64d Surf=%d\n"), m_pCodec->libavcodec->GetFFMpegPictureType(nSliceType), rtStart, nSurfaceIndex);
m_PictureParams.wDecodedPictureIndex = nSurfaceIndex;
m_PictureParams.wDeblockedPictureIndex = m_PictureParams.wDecodedPictureIndex;
// Manage reference picture list
if (!m_PictureParams.bPicBackwardPrediction) {
if (m_wRefPictureIndex[0] != NO_REF_FRAME) {
RemoveRefFrame(m_wRefPictureIndex[0]);
}
m_wRefPictureIndex[0] = m_wRefPictureIndex[1];
m_wRefPictureIndex[1] = nSurfaceIndex;
}
m_PictureParams.wForwardRefPictureIndex = (m_PictureParams.bPicIntra == 0) ? m_wRefPictureIndex[0] : NO_REF_FRAME;
m_PictureParams.wBackwardRefPictureIndex = (m_PictureParams.bPicBackwardPrediction == 1) ? m_wRefPictureIndex[1] : NO_REF_FRAME;
m_PictureParams.bPic4MVallowed = (m_PictureParams.wBackwardRefPictureIndex == NO_REF_FRAME && m_PictureParams.bPicStructure == 3) ? 1 : 0;
m_PictureParams.bPicDeblockConfined |= (m_PictureParams.wBackwardRefPictureIndex == NO_REF_FRAME) ? 0x04 : 0;
m_PictureParams.bPicScanMethod++; // Use for status reporting sections 3.8.1 and 3.8.2
DPRINTF(_l("TDXVADecoderVC1::DecodeFrame - Decode frame %i\n"), m_PictureParams.bPicScanMethod);
// Send picture params to accelerator
CHECK_HR(AddExecuteBuffer(DXVA2_PictureParametersBufferType, sizeof(m_PictureParams), &m_PictureParams));
// Send bitstream to accelerator
CHECK_HR(AddExecuteBuffer(DXVA2_BitStreamDateBufferType, nFrameSize ? nFrameSize : nSize, pDataIn, &nSize_Result));
m_SliceInfo.wQuantizerScaleCode = 1; // TODO : 1->31 ???
m_SliceInfo.dwSliceBitsInBuffer = nSize_Result * 8;
CHECK_HR(AddExecuteBuffer(DXVA2_SliceControlBufferType, sizeof(m_SliceInfo), &m_SliceInfo));
// Decode frame
CHECK_HR(Execute());
CHECK_HR(EndFrame(nSurfaceIndex));
// ***************
if (nFrameSize) { // Decoding Second Field
m_pCodec->libavcodec->FFVC1UpdatePictureParam(&m_PictureParams, m_pCodec->avctx, NULL, NULL, pDataIn, nSize, NULL, TRUE, &m_bFrame_repeat_pict);
CHECK_HR(BeginFrame(nSurfaceIndex, pSampleToDeliver));
DPRINTF(_l("TDXVADecoderVC1::DecodeFrame - PictureType = %s\n"), m_pCodec->libavcodec->GetFFMpegPictureType(nSliceType));
CHECK_HR(AddExecuteBuffer(DXVA2_PictureParametersBufferType, sizeof(m_PictureParams), &m_PictureParams));
// Send bitstream to accelerator
CHECK_HR(AddExecuteBuffer(DXVA2_BitStreamDateBufferType, nSize - nFrameSize, pDataIn + nFrameSize, &nSize_Result));
m_SliceInfo.wQuantizerScaleCode = 1; // TODO : 1->31 ???
m_SliceInfo.dwSliceBitsInBuffer = nSize_Result * 8;
CHECK_HR(AddExecuteBuffer(DXVA2_SliceControlBufferType, sizeof(m_SliceInfo), &m_SliceInfo));
// Decode frame
CHECK_HR(Execute());
CHECK_HR(EndFrame(nSurfaceIndex));
}
// ***************
#ifdef _DEBUG
DisplayStatus();
#endif
// Re-order B frames
if (m_pCodec->isReorderBFrame()) {
if (m_PictureParams.bPicBackwardPrediction == 1) {
SwapRT(rtStart, m_rtStartDelayed);
SwapRT(rtStop, m_rtStopDelayed);
} else {
// Save I or P reference time (swap later)
if (!m_bFlushed) {
if (m_nDelayedSurfaceIndex != -1) {
UpdateStore(m_nDelayedSurfaceIndex, m_rtStartDelayed, m_rtStopDelayed);
}
m_rtStartDelayed = m_rtStopDelayed = _I64_MAX;
SwapRT(rtStart, m_rtStartDelayed);
SwapRT(rtStop, m_rtStopDelayed);
m_nDelayedSurfaceIndex = nSurfaceIndex;
}
}
}
AddToStore(nSurfaceIndex, pSampleToDeliver, (m_PictureParams.bPicBackwardPrediction != 1), rtStart, rtStop,
false, (FF_FIELD_TYPE)nFieldType, (FF_SLICE_TYPE)nSliceType, 0);
m_bFlushed = false;
return DisplayNextFrame();
}
void CVPCB_MAINFRAME::OnSelectComponent( wxListEvent& event )
{
if( m_skipComponentSelect )
return;
wxString libraryName;
COMPONENT* component = NULL;
int filter = FOOTPRINTS_LISTBOX::UNFILTERED;
if( m_mainToolBar->GetToolToggled( ID_CVPCB_FOOTPRINT_DISPLAY_FILTERED_LIST ) )
filter |= FOOTPRINTS_LISTBOX::BY_COMPONENT;
if( m_mainToolBar->GetToolToggled( ID_CVPCB_FOOTPRINT_DISPLAY_PIN_FILTERED_LIST ) )
filter |= FOOTPRINTS_LISTBOX::BY_PIN_COUNT;
if( m_mainToolBar->GetToolToggled( ID_CVPCB_FOOTPRINT_DISPLAY_BY_LIBRARY_LIST ) )
filter |= FOOTPRINTS_LISTBOX::BY_LIBRARY;
component = GetSelectedComponent();
libraryName = m_libListBox->GetSelectedLibrary();
m_footprintListBox->SetFootprints( m_footprints, libraryName, component, filter );
// Tell AuiMgr that objects are changed !
if( m_auimgr.GetManagedWindow() ) // Be sure Aui Manager is initialized
// (could be not the case when starting CvPcb
m_auimgr.Update();
if( component == NULL )
return;
// Preview of the already assigned footprint.
// Find the footprint that was already chosen for this component and select it,
// but only if the selection is made from the component list or the library list.
// If the selection is made from the footprint list, do not change the current
// selected footprint.
if( FindFocus() == m_compListBox || FindFocus() == m_libListBox )
{
wxString module = FROM_UTF8( component->GetFPID().Format().c_str() );
bool found = false;
for( int ii = 0; ii < m_footprintListBox->GetCount(); ii++ )
{
wxString footprintName;
wxString msg = m_footprintListBox->OnGetItemText( ii, 0 );
msg.Trim( true );
msg.Trim( false );
footprintName = msg.AfterFirst( wxChar( ' ' ) );
if( module.Cmp( footprintName ) == 0 )
{
m_footprintListBox->SetSelection( ii, true );
found = true;
break;
}
}
if( !found )
{
int ii = m_footprintListBox->GetSelection();
if ( ii >= 0 )
m_footprintListBox->SetSelection( ii, false );
if( GetFpViewerFrame() )
{
CreateScreenCmp();
}
}
}
SendMessageToEESCHEMA();
DisplayStatus();
}
HRESULT CDXVADecoderH264::DecodeFrame(BYTE* pDataIn, UINT nSize, REFERENCE_TIME rtStart, REFERENCE_TIME rtStop)
{
HRESULT hr = S_FALSE;
UINT nSlices = 0;
int nSurfaceIndex = -1;
int nFieldType = -1;
int nSliceType = -1;
int nFramePOC = INT_MIN;
int nOutPOC = INT_MIN;
REFERENCE_TIME rtOutStart = _I64_MIN;
CH264Nalu Nalu;
UINT nNalOffset = 0;
CComPtr<IMediaSample> pSampleToDeliver;
CComQIPtr<IMPCDXVA2Sample> pDXVA2Sample;
int slice_step = 1;
if (FFH264DecodeBuffer(m_pFilter->GetAVCtx(), pDataIn, nSize, &nFramePOC, &nOutPOC, &rtOutStart) == -1) {
return S_FALSE;
}
while (!nSlices && slice_step <= 2) {
Nalu.SetBuffer(pDataIn, nSize, slice_step == 1 ? m_nNALLength : 0);
while (Nalu.ReadNext()) {
switch (Nalu.GetType()) {
case NALU_TYPE_SLICE:
case NALU_TYPE_IDR:
if (m_bUseLongSlice) {
m_pSliceLong[nSlices].BSNALunitDataLocation = nNalOffset;
m_pSliceLong[nSlices].SliceBytesInBuffer = (UINT)Nalu.GetDataLength() + 3; //.GetRoundedDataLength();
m_pSliceLong[nSlices].slice_id = nSlices;
FF264UpdateRefFrameSliceLong(&m_DXVAPicParams, &m_pSliceLong[nSlices], m_pFilter->GetAVCtx());
if (nSlices > 0) {
m_pSliceLong[nSlices - 1].NumMbsForSlice = m_pSliceLong[nSlices].NumMbsForSlice = m_pSliceLong[nSlices].first_mb_in_slice - m_pSliceLong[nSlices - 1].first_mb_in_slice;
}
}
nSlices++;
nNalOffset += (UINT)(Nalu.GetDataLength() + 3);
if (nSlices > MAX_SLICES) {
break;
}
break;
}
}
slice_step++;
}
if (!nSlices) {
return S_FALSE;
}
m_nMaxWaiting = min(max(m_DXVAPicParams.num_ref_frames, 3), 8);
// If parsing fail (probably no PPS/SPS), continue anyway it may arrived later (happen on truncated streams)
if (FAILED(FFH264BuildPicParams(&m_DXVAPicParams, &m_DXVAScalingMatrix, &nFieldType, &nSliceType, m_pFilter->GetAVCtx(), m_pFilter->GetPCIVendor()))) {
return S_FALSE;
}
TRACE_H264("CDXVADecoderH264::DecodeFrame() : nFramePOC = %11d, nOutPOC = %11d[%11d], [%d - %d], rtOutStart = [%20I64d]\n", nFramePOC, nOutPOC, m_nOutPOC, m_DXVAPicParams.field_pic_flag, m_DXVAPicParams.RefPicFlag, rtOutStart);
// Wait I frame after a flush
if (m_bFlushed && !m_DXVAPicParams.IntraPicFlag) {
TRACE_H264("CDXVADecoderH264::DecodeFrame() : Flush - wait I frame\n");
m_nBrokenFramesFlag = 0;
m_nBrokenFramesFlag_POC = 0;
m_nfield_pic_flag = m_DXVAPicParams.field_pic_flag;
m_nRefPicFlag = m_DXVAPicParams.RefPicFlag;
m_nPrevOutPOC = INT_MIN;
return S_FALSE;
}
/* Disabled, because that causes serious problems.
// Some magic code for detecting the incorrect decoding of interlaced frames ...
// TODO : necessary to make it better, and preferably on the side of ffmpeg ...
if (m_nfield_pic_flag && m_nfield_pic_flag == m_DXVAPicParams.field_pic_flag && m_nRefPicFlag == m_DXVAPicParams.RefPicFlag) {
if (m_nPrevOutPOC == m_nOutPOC && m_nOutPOC == INT_MIN) {
m_nBrokenFramesFlag_POC++;
}
m_nBrokenFramesFlag++;
} else {
m_nBrokenFramesFlag = 0;
m_nBrokenFramesFlag_POC = 0;
}
m_nfield_pic_flag = m_DXVAPicParams.field_pic_flag;
m_nRefPicFlag = m_DXVAPicParams.RefPicFlag;
m_nPrevOutPOC = m_nOutPOC;
if (m_nBrokenFramesFlag > 4) {
m_nBrokenFramesFlag = 0;
if (m_nBrokenFramesFlag_POC > 1) {
TRACE_H264("CDXVADecoderH264::DecodeFrame() : Detected broken frames ... flush data\n");
m_nBrokenFramesFlag_POC = 0;
Flush();
return S_FALSE;
}
}
//
*/
CHECK_HR_TRACE(GetFreeSurfaceIndex(nSurfaceIndex, &pSampleToDeliver, rtStart, rtStop));
FFH264SetCurrentPicture(nSurfaceIndex, &m_DXVAPicParams, m_pFilter->GetAVCtx());
CHECK_HR_TRACE(BeginFrame(nSurfaceIndex, pSampleToDeliver));
m_DXVAPicParams.StatusReportFeedbackNumber++;
// Send picture parameters
CHECK_HR_TRACE(AddExecuteBuffer(DXVA2_PictureParametersBufferType, sizeof(m_DXVAPicParams), &m_DXVAPicParams));
CHECK_HR_TRACE(Execute());
// Add bitstream, slice control and quantization matrix
CHECK_HR_TRACE(AddExecuteBuffer(DXVA2_BitStreamDateBufferType, nSize, pDataIn, &nSize));
if (m_bUseLongSlice) {
CHECK_HR_TRACE(AddExecuteBuffer(DXVA2_SliceControlBufferType, sizeof(DXVA_Slice_H264_Long)*nSlices, m_pSliceLong));
} else {
CHECK_HR_TRACE(AddExecuteBuffer(DXVA2_SliceControlBufferType, sizeof(DXVA_Slice_H264_Short)*nSlices, m_pSliceShort));
}
CHECK_HR_TRACE(AddExecuteBuffer(DXVA2_InverseQuantizationMatrixBufferType, sizeof(DXVA_Qmatrix_H264), (void*)&m_DXVAScalingMatrix));
// Decode bitstream
CHECK_HR_TRACE(Execute());
CHECK_HR_TRACE(EndFrame(nSurfaceIndex));
#if defined(_DEBUG) && 0
DisplayStatus();
#endif
bool bAdded = AddToStore(nSurfaceIndex, pSampleToDeliver, m_DXVAPicParams.RefPicFlag, rtStart, rtStop,
m_DXVAPicParams.field_pic_flag, (FF_FIELD_TYPE)nFieldType,
(FF_SLICE_TYPE)nSliceType, nFramePOC);
FFH264UpdateRefFramesList(&m_DXVAPicParams, m_pFilter->GetAVCtx());
ClearUnusedRefFrames();
if (bAdded) {
hr = DisplayNextFrame();
}
if (nOutPOC != INT_MIN) {
m_nOutPOC = nOutPOC;
m_rtOutStart = rtOutStart;
}
m_bFlushed = false;
return hr;
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
uint32_t ui32TxCount, ui32RxCount, ui32Fullness, ui32SysClock, ui32PLLRate;
tRectangle sRect;
char pcBuffer[16];
#ifdef USE_ULPI
uint32_t ui32Setting;
#endif
//
// Set the system clock to run at 120MHz from the PLL.
//
ui32SysClock = MAP_SysCtlClockFreqSet((SYSCTL_XTAL_25MHZ |
SYSCTL_OSC_MAIN | SYSCTL_USE_PLL |
SYSCTL_CFG_VCO_480), 120000000);
//
// Configure the device pins.
//
PinoutSet();
#ifdef USE_ULPI
//
// Switch the USB ULPI Pins over.
//
USBULPIPinoutSet();
//
// Enable USB ULPI with high speed support.
//
ui32Setting = USBLIB_FEATURE_ULPI_HS;
USBOTGFeatureSet(0, USBLIB_FEATURE_USBULPI, &ui32Setting);
//
// Setting the PLL frequency to zero tells the USB library to use the
// external USB clock.
//
ui32PLLRate = 0;
#else
//
// Save the PLL rate used by this application.
//
ui32PLLRate = 480000000;
#endif
//
// Enable the system tick.
//
ROM_SysTickPeriodSet(ui32SysClock / TICKS_PER_SECOND);
ROM_SysTickIntEnable();
ROM_SysTickEnable();
//
// Not configured initially.
//
g_ui32Flags = 0;
//
// Initialize the display driver.
//
Kentec320x240x16_SSD2119Init(ui32SysClock);
//
// Initialize the graphics context.
//
GrContextInit(&g_sContext, &g_sKentec320x240x16_SSD2119);
//
// Draw the application frame.
//
FrameDraw(&g_sContext, "usb-dev-serial");
//
// Fill the top 15 rows of the screen with blue to create the banner.
//
sRect.i16XMin = 0;
sRect.i16YMin = 0;
sRect.i16XMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.i16YMax = 23;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Put a white box around the banner.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
//
// Show the various static text elements on the color STN display.
//
GrContextFontSet(&g_sContext, TEXT_FONT);
GrStringDraw(&g_sContext, "Tx bytes:", -1, 8, 80, false);
GrStringDraw(&g_sContext, "Tx buffer:", -1, 8, 105, false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, 8, 160, false);
GrStringDraw(&g_sContext, "Rx buffer:", -1, 8, 185, false);
DrawBufferMeter(&g_sContext, 150, 105);
DrawBufferMeter(&g_sContext, 150, 185);
//
// Enable the UART that we will be redirecting.
//
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_UART0);
//
// Change the UART clock to the 16 MHz PIOSC.
//
UARTClockSourceSet(UART0_BASE, UART_CLOCK_PIOSC);
//
// Set the default UART configuration.
//
ROM_UARTConfigSetExpClk(UART0_BASE, UART_CLOCK,
DEFAULT_BIT_RATE, DEFAULT_UART_CONFIG);
ROM_UARTFIFOLevelSet(UART0_BASE, UART_FIFO_TX4_8, UART_FIFO_RX4_8);
//
// Configure and enable UART interrupts.
//
ROM_UARTIntClear(UART0_BASE, ROM_UARTIntStatus(UART0_BASE, false));
ROM_UARTIntEnable(UART0_BASE, (UART_INT_OE | UART_INT_BE | UART_INT_PE |
UART_INT_FE | UART_INT_RT | UART_INT_TX | UART_INT_RX));
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, " Configuring USB... ");
//
// Initialize the transmit and receive buffers.
//
USBBufferInit(&g_sTxBuffer);
USBBufferInit(&g_sRxBuffer);
//
// Set the USB stack mode to Device mode with VBUS monitoring.
//
USBStackModeSet(0, eUSBModeDevice, 0);
//
// Tell the USB library the CPU clock and the PLL frequency. This is a
// new requirement for TM4C129 devices.
//
USBDCDFeatureSet(0, USBLIB_FEATURE_CPUCLK, &ui32SysClock);
USBDCDFeatureSet(0, USBLIB_FEATURE_USBPLL, &ui32PLLRate);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDCDCInit(0, (tUSBDCDCDevice *)&g_sCDCDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, " Waiting for host... ");
//
// Clear our local byte counters.
//
ui32RxCount = 0;
ui32TxCount = 0;
g_ui32UARTTxCount = 0;
g_ui32UARTRxCount = 0;
#ifdef DEBUG
g_ui32UARTRxErrors = 0;
#endif
//
// Enable interrupts now that the application is ready to start.
//
ROM_IntEnable(INT_UART0);
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(HWREGBITW(&g_ui32Flags, FLAG_STATUS_UPDATE))
{
//
// Clear the command flag
//
HWREGBITW(&g_ui32Flags, FLAG_STATUS_UPDATE) = 0;
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ui32TxCount != g_ui32UARTTxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ui32TxCount = g_ui32UARTTxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ui32TxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 150, 80, true);
//
// Update the RX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's receive buffer is the UART's
// transmit buffer.
//
ui32Fullness = ((USBBufferDataAvailable(&g_sRxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ui32Fullness, 150, 105);
}
//
// Has there been any receive traffic since we last checked?
//
if(ui32RxCount != g_ui32UARTRxCount)
{
//
// Take a snapshot of the latest receive count.
//
ui32RxCount = g_ui32UARTRxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ui32RxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 150, 160, true);
//
// Update the TX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's transmit buffer is the UART's
// receive buffer.
//
ui32Fullness = ((USBBufferDataAvailable(&g_sTxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ui32Fullness, 150, 185);
}
}
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
unsigned int ulTxCount;
unsigned int ulRxCount;
tRectangle sRect;
char pcBuffer[16];
unsigned int ulFullness;
unsigned int intFlags = 0;
unsigned char Intstatus;
unsigned int i;
unsigned char *src, *dest;
MMUConfigAndEnable();
//
// Not configured initially.
//
g_bUSBConfigured = false;
//
//configures arm interrupt controller to generate raster interrupt
//
USBInterruptEnable();
//
//LCD Back light setup
//
LCDBackLightEnable();
//
//UPD Pin setup
//
UPDNPinControl();
//
//Delay timer setup
//
DelayTimerSetup();
//
//Configures raster to display image
//
SetUpLCD();
RasterDMAFBConfig(SOC_LCDC_0_REGS,
(unsigned int)(g_pucBuffer+PALETTE_OFFSET),
(unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 -
PALETTE_OFFSET, FRAME_BUFFER_0);
RasterDMAFBConfig(SOC_LCDC_0_REGS,
(unsigned int)(g_pucBuffer+PALETTE_OFFSET),
(unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 -
PALETTE_OFFSET, FRAME_BUFFER_1);
src = (unsigned char *) palette_32b;
dest = (unsigned char *) (g_pucBuffer+PALETTE_OFFSET);
// Copy palette info into buffer
for( i = PALETTE_OFFSET; i < (PALETTE_SIZE+PALETTE_OFFSET); i++)
{
*dest++ = *src++;
}
GrOffScreen24BPPInit(&g_s35_480x272x24Display, g_pucBuffer, LCD_WIDTH, LCD_HEIGHT);
// Initialize a drawing context.
GrContextInit(&g_sContext, &g_s35_480x272x24Display);
/* enable End of frame interrupt */
RasterEndOfFrameIntEnable(SOC_LCDC_0_REGS);
/* enable raster */
RasterEnable(SOC_LCDC_0_REGS);
//
// Fill the top 24 rows of the screen with blue to create the banner.
//
sRect.sXMin = 0;
sRect.sYMin = 0;
sRect.sXMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.sYMax = 23;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Put a white box around the banner.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
//
// Put the application name in the middle of the banner.
//
GrContextFontSet(&g_sContext, &g_sFontCm20);
GrStringDrawCentered(&g_sContext, "usb-dev-serial", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 10, 0);
//
// Show the various static text elements on the color STN display.
//
GrContextFontSet(&g_sContext, TEXT_FONT);
GrStringDraw(&g_sContext, "Tx bytes:", -1, 8, 80, false);
GrStringDraw(&g_sContext, "Tx buffer:", -1, 8, 105, false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, 8, 160, false);
GrStringDraw(&g_sContext, "Rx buffer:", -1, 8, 185, false);
DrawBufferMeter(&g_sContext, 150, 105);
DrawBufferMeter(&g_sContext, 150, 185);
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, " Configuring USB... ");
//
//Initialize the Rx and TX Buffers
//
USBBufferInit((tUSBBuffer *)&g_sTxBuffer);
USBBufferInit((tUSBBuffer *)&g_sRxBuffer);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDCDCInit(0, (tUSBDCDCDevice *)&g_sCDCDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, " Waiting for host... ");
//
// Clear our local byte counters.
//
ulRxCount = 0;
ulTxCount = 0;
/* Configuring the system clocks for UART0 instance. */
UART0ModuleClkConfig();
/* Performing the Pin Multiplexing for UART0 instance. */
UARTPinMuxSetup(0);
/* Performing a module reset. */
UARTModuleReset(SOC_UART_0_REGS);
/* Performing Baud Rate settings. */
UartBaudRateSet();
/* Switching to Configuration Mode B. */
UARTRegConfigModeEnable(SOC_UART_0_REGS, UART_REG_CONFIG_MODE_B);
/* Programming the Line Characteristics. */
UARTLineCharacConfig(SOC_UART_0_REGS,
(UART_FRAME_WORD_LENGTH_8 | UART_FRAME_NUM_STB_1),
UART_PARITY_NONE);
/* Disabling write access to Divisor Latches. */
UARTDivisorLatchDisable(SOC_UART_0_REGS);
/* Disabling Break Control. */
UARTBreakCtl(SOC_UART_0_REGS, UART_BREAK_COND_DISABLE);
/* Switching to UART16x operating mode. */
UARTOperatingModeSelect(SOC_UART_0_REGS, UART16x_OPER_MODE);
/* Performing FIFO configurations. */
UartFIFOConfigure();
/* Preparing the 'intFlags' variable to be passed as an argument.*/
intFlags |= (UART_INT_LINE_STAT | UART_INT_RHR_CTI);
/* Enable the Interrupts in UART.*/
UARTIntEnable(SOC_UART_0_REGS, intFlags);
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(g_ulFlags & COMMAND_STATUS_UPDATE)
{
//
// Clear the command flag
//
Intstatus = IntDisable();
g_ulFlags &= ~COMMAND_STATUS_UPDATE;
IntEnable(Intstatus);
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ulTxCount != g_ulUARTTxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ulTxCount = g_ulUARTTxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ulTxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 150, 80, true);
//
// Update the RX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's receive buffer is the UART's
// transmit buffer.
//
ulFullness = ((USBBufferDataAvailable(&g_sRxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ulFullness, 150, 105);
}
//
// Has there been any receive traffic since we last checked?
//
if(ulRxCount != g_ulUARTRxCount)
{
//
// Take a snapshot of the latest receive count.
//
ulRxCount = g_ulUARTRxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, "%d ", ulRxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 150, 160, true);
//
// Update the TX buffer fullness. Remember that the buffers are
// named relative to the USB whereas the status display is from
// the UART's perspective. The USB's transmit buffer is the UART's
// receive buffer.
//
ulFullness = ((USBBufferDataAvailable(&g_sTxBuffer) * 100) /
UART_BUFFER_SIZE);
UpdateBufferMeter(&g_sContext, ulFullness, 150, 185);
}
}
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
unsigned long ulTxCount;
unsigned long ulRxCount;
tRectangle sRect;
char pcBuffer[16];
//
// Set the clocking to run from the PLL at 50MHz
//
ROM_SysCtlClockSet(SYSCTL_SYSDIV_4 | SYSCTL_USE_PLL | SYSCTL_OSC_MAIN |
SYSCTL_XTAL_8MHZ);
#ifdef DEBUG
//
// Configure the relevant pins such that UART0 owns them.
//
ROM_SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOA);
ROM_GPIOPinTypeUART(GPIO_PORTA_BASE, GPIO_PIN_0 | GPIO_PIN_1);
//
// Open UART0 for debug output.
//
UARTStdioInit(0);
#endif
//
// Not configured initially.
//
g_bUSBConfigured = false;
//
// Initialize the display driver.
//
Formike128x128x16Init();
//
// Turn on the backlight.
//
Formike128x128x16BacklightOn();
//
// Initialize the graphics context.
//
GrContextInit(&g_sContext, &g_sFormike128x128x16);
//
// Fill the top 15 rows of the screen with blue to create the banner.
//
sRect.sXMin = 0;
sRect.sYMin = 0;
sRect.sXMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.sYMax = 14;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Put a white box around the banner.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
//
// Put the application name in the middle of the banner.
//
GrContextFontSet(&g_sContext, g_pFontFixed6x8);
GrStringDrawCentered(&g_sContext, "usb_dev_bulk", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 7, 0);
//
// Show the various static text elements on the color STN display.
//
GrContextFontSet(&g_sContext, TEXT_FONT);
GrStringDraw(&g_sContext, "Tx bytes:", -1, 8, 70, false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, 8, 90, false);
//
// Configure the USB mux on the board to put us in device mode. We pull
// the relevant pin high to do this.
//
ROM_SysCtlPeripheralEnable(USB_MUX_GPIO_PERIPH);
ROM_GPIOPinTypeGPIOOutput(USB_MUX_GPIO_BASE, USB_MUX_GPIO_PIN);
ROM_GPIOPinWrite(USB_MUX_GPIO_BASE, USB_MUX_GPIO_PIN, USB_MUX_SEL_DEVICE);
//
// Enable the system tick.
//
ROM_SysTickPeriodSet(SysCtlClockGet() / SYSTICKS_PER_SECOND);
ROM_SysTickIntEnable();
ROM_SysTickEnable();
//
// Show the application name on the display and UART output.
//
DEBUG_PRINT("\nStellaris USB bulk device example\n");
DEBUG_PRINT("---------------------------------\n\n");
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, "Configuring USB...");
//
// Initialize the transmit and receive buffers.
//
USBBufferInit((tUSBBuffer *)&g_sTxBuffer);
USBBufferInit((tUSBBuffer *)&g_sRxBuffer);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDBulkInit(0, (tUSBDBulkDevice *)&g_sBulkDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, "Waiting for host...");
//
// Clear our local byte counters.
//
ulRxCount = 0;
ulTxCount = 0;
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(g_ulFlags & COMMAND_STATUS_UPDATE)
{
//
// Clear the command flag
//
g_ulFlags &= ~COMMAND_STATUS_UPDATE;
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ulTxCount != g_ulTxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ulTxCount = g_ulTxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, "%d", ulTxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 70, 70, true);
}
//
// Has there been any receive traffic since we last checked?
//
if(ulRxCount != g_ulRxCount)
{
//
// Take a snapshot of the latest receive count.
//
ulRxCount = g_ulRxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, "%d", ulRxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 70, 90, true);
}
}
}
/*****************************************************************************
*
* This is the main loop that runs the application.
*
*****************************************************************************/
int main(void)
{
tRectangle sRect;
MMUConfigAndEnable();
/* Enable USB module clock */
USB0ModuleClkConfig();
/* configures arm interrupt controller to generate raster interrupt */
USBInterruptEnable();
/* LCD Back light setup */
LCDBackLightEnable();
/* UPD Pin setup */
UPDNPinControl();
/* Delay timer setup */
DelayTimerSetup();
/* Configures raster to display image */
SetUpLCD();
/* Configures raster to display image and Copy palette info into buffer */
LCDInit();
GrOffScreen24BPPInit(&g_s35_800x480x24Display, g_pucBuffer, LCD_WIDTH, LCD_HEIGHT);
/* Initialize a drawing context. */
GrContextInit(&g_sContext, &g_s35_800x480x24Display);
/* enable End of frame interrupt */
RasterEndOfFrameIntEnable(SOC_LCDC_0_REGS);
/* enable raster */
RasterEnable(SOC_LCDC_0_REGS);
/* Fill the top 24 rows of the screen with blue to create the banner. */
sRect.sXMin = 0;
sRect.sYMin = 0;
sRect.sXMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.sYMax = (MAX_ROW_NUM - 1);
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
/* Put a white box around the banner. */
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
/* Put the application name in the middle of the banner. */
GrContextFontSet(&g_sContext, &g_sFontCm20);
GrStringDrawCentered(&g_sContext, "usb-dev-composite", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 10, 0);
/* Show the various static text elements on the color STN display. */
GrContextFontSet(&g_sContext, TEXT_FONT);
GrContextForegroundSet(&g_sContext, ClrViolet);
GrStringDraw(&g_sContext, "CDC Serial 1 :-", -1, CDC1_STR_X_POSITION,
CDC1_STR_Y_POSITION, false);
GrStringDraw(&g_sContext, "CDC Serial 2 :-", -1, CDC2_STR_X_POSITION,
CDC1_STR_Y_POSITION, false);
GrContextForegroundSet(&g_sContext, ClrWhite);
GrStringDraw(&g_sContext, "Tx bytes:", -1, CDC1_STR_X_POSITION,
(CDC1_STR_Y_POSITION + CDC_STR_Y_DIFF), false);
GrStringDraw(&g_sContext, "Tx buffer:", -1, CDC1_STR_X_POSITION,
(CDC1_STR_Y_POSITION + (CDC_STR_Y_DIFF * 2)), false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, CDC1_STR_X_POSITION,
(CDC1_STR_Y_POSITION + (CDC_STR_Y_DIFF * 4)), false);
GrStringDraw(&g_sContext, "Rx buffer:", -1, CDC1_STR_X_POSITION,
(CDC1_STR_Y_POSITION + (CDC_STR_Y_DIFF * 5)), false);
DrawBufferMeter(&g_sContext, CDC1_BUF_METER_X_POS, CDC1_BUF_METER_Y_POS);
DrawBufferMeter(&g_sContext, CDC1_BUF_METER_X_POS,
(CDC1_BUF_METER_Y_POS + CDC_BUF_METER_Y_DIFF));
GrStringDraw(&g_sContext, "Tx bytes:", -1, CDC2_STR_X_POSITION,
(CDC2_STR_Y_POSITION + CDC_STR_Y_DIFF), false);
GrStringDraw(&g_sContext, "Tx buffer:", -1, CDC2_STR_X_POSITION,
(CDC2_STR_Y_POSITION + (CDC_STR_Y_DIFF * 2)), false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, CDC2_STR_X_POSITION,
(CDC2_STR_Y_POSITION + (CDC_STR_Y_DIFF * 4)), false);
GrStringDraw(&g_sContext, "Rx buffer:", -1, CDC2_STR_X_POSITION,
(CDC2_STR_Y_POSITION + (CDC_STR_Y_DIFF * 5)), false);
DrawBufferMeter(&g_sContext, CDC2_BUF_METER_X_POS, CDC2_BUF_METER_Y_POS);
DrawBufferMeter(&g_sContext, CDC2_BUF_METER_X_POS,
(CDC2_BUF_METER_Y_POS + CDC_BUF_METER_Y_DIFF));
DisplayStatus(&g_sContext, " Waiting for host... ");
/* Pass the USB library our device information, initialize the USB
controller and connect the device to the bus.
*/
g_psCompDevices[0].pvInstance =
USBDCDCCompositeInit(0, (tUSBDCDCDevice *)&g_sCDCDevice1);
g_psCompDevices[1].pvInstance =
USBDCDCCompositeInit(0, (tUSBDCDCDevice *)&g_sCDCDevice2);
/*
Pass the device information to the USB library and place the device
on the bus.
*/
USBDCompositeInit(0, &g_sCompDevice, DESCRIPTOR_DATA_SIZE,
g_pucDescriptorData);
/* Initialize the serial devices. */
SerialInit();
/* Drop into the main loop. */
while(1)
{
/* Allow the main serial routine to run. */
SerialMain();
}
}
//*****************************************************************************
//
// This is the main application entry function.
//
//*****************************************************************************
int
main(void)
{
unsigned int ulTxCount;
unsigned int ulRxCount;
tRectangle sRect;
char pcBuffer[16];
unsigned int i;
unsigned char *src, *dest;
MMUConfigAndEnable();
//
// USB module clock enable
//
USB0ModuleClkConfig();
//
//USB interrupt enable
//
USBInterruptEnable();
//
//LCD back light enable
//
LCDBackLightEnable();
// UPD Pin setup
//
//
UPDNPinControl();
//
//Delay timer setup
//
DelayTimerSetup();
//
//Configures raster to display image
//
SetUpLCD();
RasterDMAFBConfig(SOC_LCDC_0_REGS,
(unsigned int)(g_pucBuffer+PALETTE_OFFSET),
(unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 -
PALETTE_OFFSET, FRAME_BUFFER_0);
RasterDMAFBConfig(SOC_LCDC_0_REGS,
(unsigned int)(g_pucBuffer+PALETTE_OFFSET),
(unsigned int)(g_pucBuffer+PALETTE_OFFSET) + sizeof(g_pucBuffer) - 2 -
PALETTE_OFFSET, FRAME_BUFFER_1);
src = (unsigned char *) palette_32b;
dest = (unsigned char *) (g_pucBuffer+PALETTE_OFFSET);
// Copy palette info into buffer
for( i = PALETTE_OFFSET; i < (PALETTE_SIZE+PALETTE_OFFSET); i++)
{
*dest++ = *src++;
}
GrOffScreen24BPPInit(&g_s35_800x480x24Display, g_pucBuffer, LCD_WIDTH, LCD_HEIGHT);
// Initialize a drawing context.
GrContextInit(&g_sContext, &g_s35_800x480x24Display);
/* enable End of frame interrupt */
RasterEndOfFrameIntEnable(SOC_LCDC_0_REGS);
/* enable raster */
RasterEnable(SOC_LCDC_0_REGS);
//
// Fill the top 15 rows of the screen with blue to create the banner.
//
sRect.sXMin = 0;
sRect.sYMin = 0;
sRect.sXMax = GrContextDpyWidthGet(&g_sContext) - 1;
sRect.sYMax = 23;
GrContextForegroundSet(&g_sContext, ClrDarkBlue);
GrRectFill(&g_sContext, &sRect);
//
// Put a white box around the banner.
//
GrContextForegroundSet(&g_sContext, ClrWhite);
GrRectDraw(&g_sContext, &sRect);
//
// Put the application name in the middle of the banner.
//
GrContextFontSet(&g_sContext, &g_sFontCm20);
GrStringDrawCentered(&g_sContext, "usb-dev-bulk", -1,
GrContextDpyWidthGet(&g_sContext) / 2, 10, 0);
//
// Show the various static text elements on the color STN display.
//
GrContextFontSet(&g_sContext, TEXT_FONT);
GrStringDraw(&g_sContext, "Tx bytes:", -1, 8, 100, false);
GrStringDraw(&g_sContext, "Rx bytes:", -1, 8, 130, false);
//
// Tell the user what we are up to.
//
DisplayStatus(&g_sContext, " Configuring USB... ");
//
// Initialize the transmit and receive buffers.
//
USBBufferInit((tUSBBuffer *)&g_sTxBuffer);
USBBufferInit((tUSBBuffer *)&g_sRxBuffer);
//
// Pass our device information to the USB library and place the device
// on the bus.
//
USBDBulkInit(0, (tUSBDBulkDevice *)&g_sBulkDevice);
//
// Wait for initial configuration to complete.
//
DisplayStatus(&g_sContext, "Waiting for host...");
//
// Clear our local byte counters.
//
ulRxCount = 0;
ulTxCount = 0;
//
// Main application loop.
//
while(1)
{
//
// Have we been asked to update the status display?
//
if(g_ulFlags & COMMAND_STATUS_UPDATE)
{
//
// Clear the command flag
//
g_ulFlags &= ~COMMAND_STATUS_UPDATE;
DisplayStatus(&g_sContext, g_pcStatus);
}
//
// Has there been any transmit traffic since we last checked?
//
if(ulTxCount != g_ulTxCount)
{
//
// Take a snapshot of the latest transmit count.
//
ulTxCount = g_ulTxCount;
//
// Update the display of bytes transmitted by the UART.
//
usnprintf(pcBuffer, 16, " %d ", ulTxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 120, 100, true);
}
//
// Has there been any receive traffic since we last checked?
//
if(ulRxCount != g_ulRxCount)
{
//
// Take a snapshot of the latest receive count.
//
ulRxCount = g_ulRxCount;
//
// Update the display of bytes received by the UART.
//
usnprintf(pcBuffer, 16, " %d ", ulRxCount);
GrStringDraw(&g_sContext, pcBuffer, -1, 120, 130, true);
}
}
}
void EDA_3D_CANVAS::SetView3D( int keycode )
{
int ii;
double delta_move = 0.7 * g_Parm_3D_Visu.m_Zoom;
switch( keycode )
{
case WXK_LEFT:
m_draw3dOffset.x -= delta_move;
break;
case WXK_RIGHT:
m_draw3dOffset.x += delta_move;
break;
case WXK_UP:
m_draw3dOffset.y += delta_move;
break;
case WXK_DOWN:
m_draw3dOffset.y -= delta_move;
break;
case WXK_HOME:
g_Parm_3D_Visu.m_Zoom = 1.0;
m_draw3dOffset.x = m_draw3dOffset.y = 0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
break;
case WXK_END:
break;
case WXK_F1:
g_Parm_3D_Visu.m_Zoom /= 1.4;
if( g_Parm_3D_Visu.m_Zoom <= 0.01 )
g_Parm_3D_Visu.m_Zoom = 0.01;
break;
case WXK_F2:
g_Parm_3D_Visu.m_Zoom *= 1.4;
break;
case '+':
break;
case '-':
break;
case 'r':
case 'R':
m_draw3dOffset.x = m_draw3dOffset.y = 0;
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
break;
case 'x':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
g_Parm_3D_Visu.m_ROTZ = -90;
g_Parm_3D_Visu.m_ROTX = -90;
break;
case 'X':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
g_Parm_3D_Visu.m_ROTZ = 90;
g_Parm_3D_Visu.m_ROTX = -90;
break;
case 'y':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
g_Parm_3D_Visu.m_ROTX = -90;
break;
case 'Y':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
g_Parm_3D_Visu.m_ROTX = -90;
g_Parm_3D_Visu.m_ROTZ = -180;
break;
case 'z':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
break;
case 'Z':
for( ii = 0; ii < 4; ii++ )
g_Parm_3D_Visu.m_Rot[ii] = 0.0;
trackball( g_Parm_3D_Visu.m_Quat, 0.0, 0.0, 0.0, 0.0 );
g_Parm_3D_Visu.m_ROTX = -180;
break;
default:
return;
}
DisplayStatus();
Refresh( false );
}
//*****************************************************************************
//
// This is the main loop that runs the application.
//
//*****************************************************************************
int
main(void)
{
uint8_t ui8ButtonsChanged, ui8Buttons;
uint32_t ui32SysClock;
//
// Set the clocking to run from the PLL at 120MHz
//
ui32SysClock = MAP_SysCtlClockFreqSet((SYSCTL_USE_PLL | SYSCTL_OSC_MAIN |
SYSCTL_XTAL_25MHZ |
SYSCTL_CFG_VCO_480), 120000000);
//
// Configure the device pins.
//
PinoutSet();
//
// Configure the buttons driver.
//
ButtonsInit(ALL_BUTTONS);
//
// Initialize the display driver.
//
Kentec320x240x16_SSD2119Init(ui32SysClock);
//
// Initialize the graphics context.
//
GrContextInit(&g_sContext, &g_sKentec320x240x16_SSD2119);
//
// Draw the application frame.
//
FrameDraw(&g_sContext, "usb-dev-gamepad");
//
// Default status is disconnected.
//
DisplayStatus(&g_sContext, "Disconnected");
//
// Not configured initially.
//
g_iGamepadState = eStateNotConfigured;
//
// Initialize the USB stack for device mode.
//
USBStackModeSet(0, eUSBModeDevice, 0);
//
// Pass the device information to the USB library and place the device
// on the bus.
//
USBDHIDGamepadInit(0, &g_sGamepadDevice);
//
// Zero out the initial report.
//
g_sReport.ui8Buttons = 0;
g_sReport.i8XPos = 0;
g_sReport.i8YPos = 0;
//
// Initialize the touch screen driver.
//
TouchScreenInit(ui32SysClock);
//
// Set the touch screen event handler.
//
TouchScreenCallbackSet(TSHandler);
//
// The main loop starts here. We begin by waiting for a host connection
// then drop into the main gamepad handling section. If the host
// disconnects, we return to the top and wait for a new connection.
//
while(1)
{
//
// Wait here until USB device is connected to a host.
//
if(g_iGamepadState == eStateIdle)
{
//
// See if the buttons updated.
//
ButtonsPoll(&ui8ButtonsChanged, &ui8Buttons);
g_sReport.ui8Buttons = 0;
//
// Set button 1 if up button pressed.
//
if(ui8Buttons & UP_BUTTON)
{
g_sReport.ui8Buttons |= 0x01;
}
//
// Set button 2 if down button pressed.
//
if(ui8Buttons & DOWN_BUTTON)
{
g_sReport.ui8Buttons |= 0x02;
}
//
// Set button 3 if select button pressed.
//
if(ui8Buttons & SELECT_BUTTON)
{
g_sReport.ui8Buttons |= 0x04;
}
if(ui8ButtonsChanged)
{
g_bUpdate = true;
}
//
// Send the report if there was an update.
//
if(g_bUpdate)
{
g_bUpdate = false;
USBDHIDGamepadSendReport(&g_sGamepadDevice, &g_sReport,
sizeof(g_sReport));
//
// Now sending data but protect this from an interrupt since
// it can change in interrupt context as well.
//
IntMasterDisable();
g_iGamepadState = eStateSending;
IntMasterEnable();
}
}
}
}
//*****************************************************************************
//
// Handles asynchronous events from the HID gamepad driver.
//
// \param pvCBData is the event callback pointer provided during
// USBDHIDGamepadInit(). This is a pointer to our gamepad device structure
// (&g_sGamepadDevice).
// \param ui32Event identifies the event we are being called back for.
// \param ui32MsgData is an event-specific value.
// \param pvMsgData is an event-specific pointer.
//
// This function is called by the HID gamepad driver to inform the application
// of particular asynchronous events related to operation of the gamepad HID
// device.
//
// \return Returns 0 in all cases.
//
//*****************************************************************************
uint32_t
GamepadHandler(void *pvCBData, uint32_t ui32Event, uint32_t ui32MsgData,
void *pvMsgData)
{
switch (ui32Event)
{
//
// The host has connected to us and configured the device.
//
case USB_EVENT_CONNECTED:
{
g_iGamepadState = eStateIdle;
DisplayStatus(&g_sContext, "Connected");
break;
}
//
// The host has disconnected from us.
//
case USB_EVENT_DISCONNECTED:
{
g_iGamepadState = eStateNotConfigured;
DisplayStatus(&g_sContext, "Disconnected");
break;
}
//
// This event occurs every time the host acknowledges transmission
// of a report. It is to return to the idle state so that a new report
// can be sent to the host.
//
case USB_EVENT_TX_COMPLETE:
{
//
// Enter the idle state since we finished sending something.
//
g_iGamepadState = eStateIdle;
break;
}
//
// This event indicates that the host has suspended the USB bus.
//
case USB_EVENT_SUSPEND:
{
//
// Go to the suspended state.
//
g_iGamepadState = eStateSuspend;
DisplayStatus(&g_sContext, "Suspended");
break;
}
//
// This event signals that the host has resumed signaling on the bus.
//
case USB_EVENT_RESUME:
{
//
// Go back to the idle state.
//
g_iGamepadState = eStateIdle;
DisplayStatus(&g_sContext, "Connected");
break;
}
//
// Return the pointer to the current report. This call is
// rarely if ever made, but is required by the USB HID
// specification.
//
case USBD_HID_EVENT_GET_REPORT:
{
*(void **)pvMsgData = (void *)&g_sReport;
break;
}
//
// We ignore all other events.
//
default:
{
break;
}
}
return(0);
}