kicad/pcbnew/gen_self.h

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/****************************************************/
/* Gestion des composants specifiques aux microndes */
/* Generation d'une self */
/****************************************************/
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/* Fichier GEN_SELF.H */
/* Fonctions locales */
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static void Exit_Self( WinEDA_DrawPanel* Panel, wxDC* DC );
static EDGE_MODULE* gen_arc( EDGE_MODULE* PtSegm, int cX, int cY, int angle );
static void ShowCadreSelf( WinEDA_DrawPanel* panel, wxDC* DC, bool erase );
/* structures locales */
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class SELFPCB // Definition d'une self constituee par une piste
{
public:
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int forme; // Serpentin, spirale ..
int orient; // 0..3600
int valeur; // Valeur de la self
wxPoint m_Start;
wxPoint m_End; // Coord du point de depart et d'arrivee
wxSize m_Size;
D_PAD* pt_pad_start, * pt_pad_end; // Pointeurs sur les pads d'extremite
int lng; // Longueur de la piste constituant la self
int m_Width; // m_Size.xur de la piste
int nbrin; // Parametres de calcul: nombre de brins
int lbrin; // longueur du brin
int rayon; // Rayon des raccords entre brins
int delta; // distance aux pads
};
/* Variables locales */
static SELFPCB Mself;
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static int Self_On;
static int Bl_X0, Bl_Y0, Bl_Xf, Bl_Yf; // Coord du cadre insrcivant la self
/*************************************************************************/
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static void ShowCadreSelf( WinEDA_DrawPanel* panel, wxDC* DC, bool erase )
/*************************************************************************/
/* Routine d'affichage a l'ecran du cadre de la self */
{
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int deltaX, deltaY;
/* Calcul de l'orientation et de la taille de la fenetre:
* - orient = vert ou Horiz ( dimension max)
* - Size.x = Size.y / 2
*/
GRSetDrawMode( DC, GR_XOR );
if( erase )/* effacement du cadre */
{
GRRect( &panel->m_ClipBox, DC, Bl_X0, Bl_Y0, Bl_Xf, Bl_Yf, YELLOW );
}
deltaX = (panel->GetScreen()->m_Curseur.x - Mself.m_Start.x) / 4;
deltaY = (panel->GetScreen()->m_Curseur.y - Mself.m_Start.y) / 4;
Mself.orient = 900;
if( abs( deltaX ) > abs( deltaY ) )
Mself.orient = 0;
if( Mself.orient == 0 )
{
Bl_X0 = Mself.m_Start.x;
Bl_Y0 = Mself.m_Start.y - deltaX;
Bl_Xf = panel->GetScreen()->m_Curseur.x;
Bl_Yf = Mself.m_Start.y + deltaX;
}
else
{
Bl_X0 = Mself.m_Start.x - deltaY;
Bl_Y0 = Mself.m_Start.y;
Bl_Xf = Mself.m_Start.x + deltaY;
Bl_Yf = panel->GetScreen()->m_Curseur.y;
}
GRRect( &panel->m_ClipBox, DC, Bl_X0, Bl_Y0, Bl_Xf, Bl_Yf, YELLOW );
}
/*************************************************/
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void Exit_Self( WinEDA_DrawPanel* Panel, wxDC* DC )
/*************************************************/
/* Routine de fermeture de l'application : ferme les commandes en cours */
{
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if( Self_On )
{
Self_On = 0;
Panel->ManageCurseur( Panel, DC, 0 ); /* efface cadre */
Panel->ManageCurseur = NULL;
Panel->ForceCloseManageCurseur = NULL;
}
}
/*******************************************/
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void WinEDA_PcbFrame::Begin_Self( wxDC* DC )
/*******************************************/
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/*
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* Routine d'initialisation d'un trace de self
*/
{
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if( Self_On )
{
Genere_Self( DC );
return;
}
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Mself.m_Start = GetScreen()->m_Curseur;
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Self_On = 1;
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/* Mise a jour de l'origine des coord relatives */
GetScreen()->m_O_Curseur = GetScreen()->m_Curseur;
Affiche_Status_Box();
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Bl_X0 = Mself.m_Start.x; Bl_Y0 = Mself.m_Start.y;
Bl_Xf = Bl_X0; Bl_Yf = Bl_Y0;
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DrawPanel->ManageCurseur = ShowCadreSelf;
DrawPanel->ForceCloseManageCurseur = Exit_Self;
DrawPanel->ManageCurseur( DrawPanel, DC, 0 ); /* Affiche cadre */
}
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/**********************************************/
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MODULE* WinEDA_PcbFrame::Genere_Self( wxDC* DC )
/**********************************************/
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/* Genere une self en forme de serpentin
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* - longueur Mself.lng
* - Extremites Mself.m_Start et Mself.m_End
* - Contrainte: m_Start.x = m_End.x ( self verticale )
* ou m_Start.y = m_End.y ( self horizontale )
*
* On doit determiner:
* Mself.nbrin = nombre de segments perpendiculaires a la direction
* ( le serpention aura nbrin + 1 demicercles + 2 1/4 de cercle)
* Mself.lbrin = longueur d'un brin
* Mself.rayon = rayon des parties arrondies du serpentin
* Mself.delta = segments raccord entre extremites et le serpention lui meme
*
* Les equations sont
* Mself.m_Size.x = 2*Mself.rayon + Mself.lbrin
* Mself.m_Size.y = 2*Mself.delta + 2*Mself.nbrin*Mself.rayon
* Mself.lng = 2*Mself.delta // Raccords au serpentin
+ (Mself.nbrin-2) * Mself.lbrin //longueur des brins sauf 1er et dernier
+ (Mself.nbrin+1) * ( PI * Mself.rayon) // longueur des arrondis
+ Mself.lbrin/2 - Melf.rayon*2) // longueur du 1er et dernier brin
*
* Les contraintes sont:
* nbrin >= 2
* Mself.rayon < Mself.m_Size.x
* Mself.m_Size.y = Mself.rayon*4 + 2*Mself.raccord
* Mself.lbrin > Mself.rayon *2
*
* Le calcul est conduit de la facon suivante:
* Initialement:
* nbrin = 2
* rayon = 4 * m_Size.x (valeur fixe arbitraire)
* puis:
* on augmente le nombre de brins jusqu'a la longueur desiree
* ( le rayon est diminue si necessaire )
*
*/
{
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EDGE_MODULE* PtSegm, * LastSegm, * FirstSegm, * newedge;
MODULE* Module;
D_PAD* PtPad;
int ii, ll, lextbrin;
float fcoeff;
bool abort = FALSE;
wxString msg;
DrawPanel->ManageCurseur( DrawPanel, DC, FALSE ); /* efface cadre */
DrawPanel->ManageCurseur = NULL;
DrawPanel->ForceCloseManageCurseur = NULL;
if( Self_On == 0 )
{
DisplayError( this, wxT( "Starting point not init.." ) ); return NULL;
}
Self_On = 0;
Mself.m_End = m_CurrentScreen->m_Curseur;
/* Agencement des parametres pour simplifier le calcul : */
/* le point de depart doit avoir la coord depart < celle du point de fin */
if( Mself.orient == 0 ) // Self horizontale
{
Mself.m_End.y = Mself.m_Start.y;
if( Mself.m_Start.x > Mself.m_End.x )
EXCHG( Mself.m_Start.x, Mself.m_End.x );
Mself.m_Size.y = Mself.m_End.x - Mself.m_Start.x;
Mself.lng = Mself.m_Size.y;
}
else // Self verticale
{
Mself.m_End.x = Mself.m_Start.x;
if( Mself.m_Start.y > Mself.m_End.y )
EXCHG( Mself.m_Start.y, Mself.m_End.y );
Mself.m_Size.y = Mself.m_End.y - Mself.m_Start.y;
Mself.lng = Mself.m_Size.y;
}
/* Entree de la vraie longueur desiree */
if( !g_UnitMetric )
{
fcoeff = 10000.0;
msg.Printf( wxT( "%1.4f" ), Mself.lng / fcoeff );
abort = Get_Message( _( "Length(inch):" ), msg, this );
}
else
{
fcoeff = 10000.0 / 25.4;
msg.Printf( wxT( "%2.3f" ), Mself.lng / fcoeff );
abort = Get_Message( _( "Length(mm):" ), msg, this );
}
if( abort )
return NULL;
double fval;
if( !msg.ToDouble( &fval ) )
{
DisplayError( this, _( "Incorrect number, abort" ) );
return NULL;
}
Mself.lng = (int) round( fval * fcoeff );
/* Controle des valeurs ( ii = valeur minimale de la longueur */
if( Mself.lng < Mself.m_Size.y )
{
DisplayError( this, _( "Requested length < minimum length" ) );
return NULL;
}
/* Generation du composant: calcul des elements de la self */
Mself.m_Width = g_DesignSettings.m_CurrentTrackWidth;
Mself.m_Size.x = Mself.m_Size.y / 2;
// Choix d'une Valeur de depart raisonnable pour le rayon des arcs de cercle
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Mself.rayon = MIN( Mself.m_Width * 5, Mself.m_Size.x / 4 );
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/* Calcul des parametres */
for( Mself.nbrin = 2; ; Mself.nbrin++ )
{
Mself.delta = ( Mself.m_Size.y - ( Mself.rayon * 2 * Mself.nbrin ) ) / 2;
if( Mself.delta < Mself.m_Size.y / 10 ) // C.a.d. si m_Size.yeur self > m_Size.yeur specifiee
{ // Reduction du rayon des arrondis
Mself.delta = Mself.m_Size.y / 10;
Mself.rayon = (Mself.m_Size.y - 2 * Mself.delta) / ( 2 * Mself.nbrin);
if( Mself.rayon < Mself.m_Width )
{ // Rayon vraiment trop petit...
Affiche_Message( _( "Unable to create line: Requested length is too big" ) );
return NULL;
}
}
Mself.lbrin = Mself.m_Size.x - (Mself.rayon * 2);
lextbrin = (Mself.lbrin / 2) - Mself.rayon;
ll = 2 * lextbrin; // Longueur du 1er et dernier brin
ll += 2 * Mself.delta; // Longueur des raccord au serpentin
ll += Mself.nbrin * (Mself.lbrin - 2); // longueur des autres brins
ll += ( (Mself.nbrin + 1) * 314 * Mself.rayon ) / 100;
msg.Printf( _( "Segm count = %d, Lenght = " ), Mself.nbrin );
wxString stlen;
valeur_param( ll, stlen ); msg += stlen;
Affiche_Message( msg );
if( ll >= Mself.lng )
break;
}
/* Generation du composant : le calcul est fait self Verticale */
if( Create_1_Module( DC, wxEmptyString ) == NULL )
return NULL;
Module = m_Pcb->m_Modules;
Module->m_LibRef = wxT( "MuSelf" );
Module->m_Attributs = MOD_VIRTUAL | MOD_CMS;
Module->m_Flags = 0;
Module->Draw( DrawPanel, DC, wxPoint( 0, 0 ), GR_XOR );
/* Generation des elements speciaux: drawsegments */
LastSegm = (EDGE_MODULE*) Module->m_Drawings;
if( LastSegm )
while( LastSegm->Pnext )
LastSegm = (EDGE_MODULE*) LastSegm->Pnext;
FirstSegm = PtSegm = new EDGE_MODULE( Module );
if( LastSegm )
{
LastSegm->Pnext = PtSegm;
PtSegm->Pback = LastSegm;
}
else
{
Module->m_Drawings = PtSegm; PtSegm->Pback = Module;
}
PtSegm->m_Start = Mself.m_Start;
PtSegm->m_End.x = Mself.m_Start.x;
PtSegm->m_End.y = PtSegm->m_Start.y + Mself.delta;
PtSegm->m_Width = Mself.m_Width;
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PtSegm->SetLayer( Module->GetLayer() );
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PtSegm->m_Shape = S_SEGMENT;
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm = gen_arc( PtSegm, PtSegm->m_End.x - Mself.rayon, PtSegm->m_End.y, -900 );
if( lextbrin )
{
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm->m_End.x -= lextbrin;
}
/* Trace du serpentin */
for( ii = 1; ii < Mself.nbrin; ii++ )
{
int arc_angle;
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
if( ii & 1 ) /* brin d'ordre impair : cercles de sens > 0 */
arc_angle = 1800;
else
arc_angle = -1800;
PtSegm = gen_arc( PtSegm, PtSegm->m_End.x,
PtSegm->m_End.y + Mself.rayon, arc_angle );
if( ii < Mself.nbrin - 1 )
{
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
if( ii & 1 )
PtSegm->m_End.x += Mself.lbrin;
else
PtSegm->m_End.x -= Mself.lbrin;
}
}
/* Trace du point final */
if( ii & 1 ) /* brin final de sens > 0 */
{
if( lextbrin )
{
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm->m_End.x -= lextbrin;
}
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start.x = PtSegm->m_End.x; PtSegm->m_Start.y = PtSegm->m_End.y;
PtSegm = gen_arc( PtSegm, PtSegm->m_End.x, PtSegm->m_End.y + Mself.rayon, 900 );
}
else
{
if( lextbrin )
{
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm->m_End.x += lextbrin;
}
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm = gen_arc( PtSegm, PtSegm->m_End.x, PtSegm->m_End.y + Mself.rayon, -900 );
}
newedge = new EDGE_MODULE( Module );
newedge->Copy( PtSegm );
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start = PtSegm->m_End;
PtSegm->m_End = Mself.m_End;
PtSegm->Pnext = NULL;
/* Rotation de la self si le trace doit etre horizontal : */
LastSegm = PtSegm;
if( Mself.orient == 0 )
{
for( PtSegm = FirstSegm; PtSegm != NULL; PtSegm = (EDGE_MODULE*) PtSegm->Pnext )
{
RotatePoint( &PtSegm->m_Start.x, &PtSegm->m_Start.y,
FirstSegm->m_Start.x, FirstSegm->m_Start.y, 900 );
if( PtSegm != LastSegm )
RotatePoint( &PtSegm->m_End.x, &PtSegm->m_End.y,
FirstSegm->m_Start.x, FirstSegm->m_Start.y, 900 );
}
}
/* Modif position ancre */
Module->m_Pos.x = LastSegm->m_End.x; Module->m_Pos.y = LastSegm->m_End.y;
/* Placement des 2 pads sur extremite */
PtPad = new D_PAD( Module );
Module->m_Pads = PtPad; PtPad->Pback = Module;
PtPad->SetPadName( wxT( "1" ) );
PtPad->m_Pos.x = LastSegm->m_End.x; PtPad->m_Pos.y = LastSegm->m_End.y;
PtPad->m_Pos0.x = PtPad->m_Pos.x - Module->m_Pos.x;
PtPad->m_Pos0.y = PtPad->m_Pos.y - Module->m_Pos.y;
PtPad->m_Size.x = PtPad->m_Size.y = LastSegm->m_Width;
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PtPad->m_Masque_Layer = g_TabOneLayerMask[LastSegm->GetLayer()];
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PtPad->m_Attribut = SMD;
PtPad->m_PadShape = CIRCLE;
PtPad->m_Rayon = PtPad->m_Size.x / 2;
D_PAD* newpad = new D_PAD( Module );
newpad->Copy( PtPad );
newpad->AddToChain( PtPad );
PtPad = newpad;
PtPad->SetPadName( wxT( "2" ) );
PtPad->m_Pos.x = FirstSegm->m_Start.x; PtPad->m_Pos.y = FirstSegm->m_Start.y;
PtPad->m_Pos0.x = PtPad->m_Pos.x - Module->m_Pos.x;
PtPad->m_Pos0.y = PtPad->m_Pos.y - Module->m_Pos.y;
/* Modif des positions textes */
Module->Display_Infos( this );
Module->m_Value->m_Pos.x = Module->m_Reference->m_Pos.x = ( FirstSegm->m_Start.x +
LastSegm->m_End.x ) / 2;
Module->m_Value->m_Pos.y = Module->m_Reference->m_Pos.y = ( FirstSegm->m_Start.y +
LastSegm->m_End.y ) / 2;
Module->m_Reference->m_Pos.y -= Module->m_Reference->m_Size.y;
Module->m_Value->m_Pos.y += Module->m_Value->m_Size.y;
Module->m_Reference->m_Pos0.x = Module->m_Reference->m_Pos.x - Module->m_Pos.x;
Module->m_Reference->m_Pos0.y = Module->m_Reference->m_Pos.y - Module->m_Pos.y;
Module->m_Value->m_Pos0.x = Module->m_Value->m_Pos.x - Module->m_Pos.x;
Module->m_Value->m_Pos0.y = Module->m_Value->m_Pos.y - Module->m_Pos.y;
/* Init des Coord locales des segments */
for( PtSegm = FirstSegm; PtSegm != NULL; PtSegm = (EDGE_MODULE*) PtSegm->Pnext )
{
PtSegm->m_Start0.x = PtSegm->m_Start.x - Module->m_Pos.x;
PtSegm->m_Start0.y = PtSegm->m_Start.y - Module->m_Pos.y;
PtSegm->m_End0.x = PtSegm->m_End.x - Module->m_Pos.x;
PtSegm->m_End0.y = PtSegm->m_End.y - Module->m_Pos.y;
}
Module->Set_Rectangle_Encadrement();
Module->Draw( DrawPanel, DC, wxPoint( 0, 0 ), GR_OR );
return Module;
}
/**************************************************************************/
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static EDGE_MODULE* gen_arc( EDGE_MODULE* PtSegm, int cX, int cY, int angle )
/**************************************************************************/
/* Genere un arc de EDGE_MODULE :
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* de centre cX,cY
* d'angle "angle"
* de point de depart donne dans la structure pointee par PtSegm, qui doit
* entre a jour (type,net..)
* Retourne un pointeur sur la derniere structure EDGE_MODULE generee
*/
{
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int ii, nb_seg;
float alpha, beta, fsin, fcos;
int x0, xr0, y0, yr0;
EDGE_MODULE* newedge;
angle = -angle;
y0 = PtSegm->m_Start.x - cX; x0 = PtSegm->m_Start.y - cY;
nb_seg = ( abs( angle ) ) / 225; if( nb_seg == 0 )
nb_seg = 1;
alpha = ( (float) angle * 3.14159 / 1800 ) / nb_seg;
for( ii = 1; ii <= nb_seg; ii++ )
{
if( ii > 1 )
{
newedge = new EDGE_MODULE( (MODULE*) NULL );
newedge->Copy( PtSegm );
newedge->m_Parent = PtSegm->m_Parent;
newedge->AddToChain( PtSegm );
PtSegm = newedge;
PtSegm->m_Start.x = PtSegm->m_End.x; PtSegm->m_Start.y = PtSegm->m_End.y;
}
beta = (alpha * ii);
fcos = cos( beta ); fsin = sin( beta );
xr0 = (int) (x0 * fcos + y0 * fsin);
yr0 = (int) (y0 * fcos - x0 * fsin);
PtSegm->m_End.x = cX + yr0; PtSegm->m_End.y = cY + xr0;
}
return PtSegm;
}