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Elphel
kicad-source-mirror
Commits
c1e3416a
Commit
c1e3416a
authored
Aug 08, 2007
by
dickelbeck
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searching and beautifying
parent
66080848
Changes
20
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20 changed files
with
3168 additions
and
2703 deletions
+3168
-2703
change_log.txt
change_log.txt
+14
-0
trigo.cpp
common/trigo.cpp
+159
-0
pcbstruct.h
include/pcbstruct.h
+22
-2
trigo.h
include/trigo.h
+2
-1
class_board.cpp
pcbnew/class_board.cpp
+29
-40
class_cotation.cpp
pcbnew/class_cotation.cpp
+414
-286
class_cotation.h
pcbnew/class_cotation.h
+48
-28
class_edge_mod.cpp
pcbnew/class_edge_mod.cpp
+67
-0
class_edge_mod.h
pcbnew/class_edge_mod.h
+9
-1
class_mire.cpp
pcbnew/class_mire.cpp
+158
-133
class_mire.h
pcbnew/class_mire.h
+32
-25
class_module.h
pcbnew/class_module.h
+0
-1
class_track.cpp
pcbnew/class_track.cpp
+548
-434
class_track.h
pcbnew/class_track.h
+112
-61
classpcb.cpp
pcbnew/classpcb.cpp
+56
-0
drc.cpp
pcbnew/drc.cpp
+1445
-1248
edit.cpp
pcbnew/edit.cpp
+1
-2
locate.cpp
pcbnew/locate.cpp
+50
-421
protos.h
pcbnew/protos.h
+0
-18
zones.h
pcbnew/zones.h
+2
-2
No files found.
change_log.txt
View file @
c1e3416a
...
...
@@ -5,6 +5,20 @@ Please add newer entries at the top, list the date and your name with
email address.
2007-Aug-08 UPDATE Dick Hollenbeck <dick@softplc.com>
================================================================================
+ pcbnew & common
* Renamed locate.cpp's distance() to DistanceTest() and moved it to trigo.cpp.
Pass more parameters to DistanceTest and removed globals that were used by
distance() in locate.cpp.
Moved and renamed DistanceTest function proto from protos.h to trigo.h.
* Implemented HitTest() for class_cotation, class_mire, and a few other classes
by factoring out existing code from locate.cpp. locate.cpp should operate
exactly the same as before.
* Detected that the suspected class_module hit-testing bug was not real,
i.e. no bug found.
2007-aug-08 UPDATE Jean-Pierre Charras <jean-pierre.charras@inpg.fr>
================================================================================
+ eeschema
...
...
common/trigo.cpp
View file @
c1e3416a
...
...
@@ -9,6 +9,163 @@
#include "trigo.h"
/*****************************/
bool
DistanceTest
(
int
seuil
,
int
dx
,
int
dy
,
int
spot_cX
,
int
spot_cY
)
/*****************************/
/*
* Calcul de la distance du curseur souris a un segment de droite :
* ( piste, edge, contour module ..
* retourne:
* false si distance > seuil
* true si distance <= seuil
* Variables utilisees ( doivent etre initialisees avant appel , et
* sont ramenees au repere centre sur l'origine du segment)
* dx, dy = coord de l'extremite segment.
* spot_cX,spot_cY = coord du curseur souris
* la recherche se fait selon 4 cas:
* segment horizontal
* segment vertical
* segment 45
* segment quelconque
*/
{
int
cXrot
,
cYrot
,
/* coord du point (souris) dans le repere tourne */
segX
,
segY
;
/* coord extremite segment tj >= 0 */
int
pointX
,
pointY
;
/* coord point a tester dans repere modifie dans lequel
* segX et segY sont >=0 */
segX
=
dx
;
segY
=
dy
;
pointX
=
spot_cX
;
pointY
=
spot_cY
;
/*Recalcul coord pour que le segment soit dans 1er quadrant (coord >= 0)*/
if
(
segX
<
0
)
/* mise en >0 par symetrie par rapport a l'axe Y */
{
segX
=
-
segX
;
pointX
=
-
pointX
;
}
if
(
segY
<
0
)
/* mise en > 0 par symetrie par rapport a l'axe X */
{
segY
=
-
segY
;
pointY
=
-
pointY
;
}
if
(
segY
==
0
)
/* piste Horizontale */
{
if
(
abs
(
pointY
)
<=
seuil
)
{
if
(
(
pointX
>=
0
)
&&
(
pointX
<=
segX
)
)
return
1
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
pointX
<
0
)
&&
(
pointX
>=
-
seuil
)
)
{
if
(
(
(
pointX
*
pointX
)
+
(
pointY
*
pointY
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
if
(
(
pointX
>
segX
)
&&
(
pointX
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
pointX
-
segX
)
*
(
pointX
-
segX
)
)
+
(
pointY
*
pointY
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
}
}
else
if
(
segX
==
0
)
/* piste verticale */
{
if
(
abs
(
pointX
)
<=
seuil
)
{
if
(
(
pointY
>=
0
)
&&
(
pointY
<=
segY
)
)
return
true
;
if
(
(
pointY
<
0
)
&&
(
pointY
>=
-
seuil
)
)
{
if
(
(
(
pointY
*
pointY
)
+
(
pointX
*
pointX
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
if
(
(
pointY
>
segY
)
&&
(
pointY
<=
(
segY
+
seuil
)
)
)
{
if
(
(
(
(
pointY
-
segY
)
*
(
pointY
-
segY
)
)
+
(
pointX
*
pointX
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
}
}
else
if
(
segX
==
segY
)
/* piste a 45 degre */
{
/* on fait tourner les axes de 45 degre. la souris a alors les
* coord : x1 = x*cos45 + y*sin45
* y1 = y*cos45 - x*sin45
* et le segment de piste est alors horizontal.
* recalcul des coord de la souris ( sin45 = cos45 = .707 = 7/10
* remarque : sin ou cos45 = .707, et lors du recalcul des coord
* dx45 et dy45, lec coeff .707 est neglige, dx et dy sont en fait .707 fois
* trop grands. (c.a.d trop petits)
* spot_cX,Y doit etre * par .707 * .707 = 0.5 */
cXrot
=
(
pointX
+
pointY
)
>>
1
;
cYrot
=
(
pointY
-
pointX
)
>>
1
;
/* recalcul des coord de l'extremite du segment , qui sera vertical
* suite a l'orientation des axes sur l'ecran : dx45 = pointX (ou pointY)
* et est en fait 1,414 plus grand , et dy45 = 0 */
// seuil doit etre * .707 pour tenir compte du coeff de reduction sur dx,dy
seuil
*=
7
;
seuil
/=
10
;
if
(
abs
(
cYrot
)
<=
seuil
)
/* ok sur axe vertical) */
{
if
(
(
cXrot
>=
0
)
&&
(
cXrot
<=
segX
)
)
return
true
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
cXrot
<
0
)
&&
(
cXrot
>=
-
seuil
)
)
{
if
(
(
(
cXrot
*
cXrot
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
if
(
(
cXrot
>
segX
)
&&
(
cXrot
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
cXrot
-
segX
)
*
(
cXrot
-
segX
)
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
}
}
else
/* orientation quelconque */
{
/* On fait un changement d'axe (rotation) de facon a ce que le segment
* de piste soit horizontal dans le nouveau repere */
int
angle
;
angle
=
(
int
)
(
atan2
(
(
float
)
segY
,
(
float
)
segX
)
*
1800
/
M_PI
);
cXrot
=
pointX
;
cYrot
=
pointY
;
RotatePoint
(
&
cXrot
,
&
cYrot
,
angle
);
/* Rotation du point a tester */
RotatePoint
(
&
segX
,
&
segY
,
angle
);
/* Rotation du segment */
/* la piste est Horizontale , par suite des modifs de coordonnes
* et d'axe, donc segX = longueur du segment */
if
(
abs
(
cYrot
)
<=
seuil
)
/* ok sur axe vertical) */
{
if
(
(
cXrot
>=
0
)
&&
(
cXrot
<=
segX
)
)
return
true
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
cXrot
<
0
)
&&
(
cXrot
>=
-
seuil
)
)
{
if
(
(
(
cXrot
*
cXrot
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
if
(
(
cXrot
>
segX
)
&&
(
cXrot
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
cXrot
-
segX
)
*
(
cXrot
-
segX
)
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
true
;
}
}
}
return
false
;
}
/***********************************/
int
ArcTangente
(
int
dy
,
int
dx
)
/***********************************/
...
...
@@ -217,3 +374,5 @@ void RotatePoint( double* pX, double* pY, int angle )
*
pY
=
fpy
;
}
}
include/pcbstruct.h
View file @
c1e3416a
...
...
@@ -235,7 +235,6 @@ public:
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
...
...
@@ -264,7 +263,7 @@ public:
* @param typeloc
* @return EDA_BaseStruct* - if a direct hit, else NULL.
*/
EDA_BaseStruct
*
FindPadOrModule
(
const
wxPoint
&
refPos
,
int
layer
,
int
typeloc
);
EDA_BaseStruct
*
FindPadOrModule
(
const
wxPoint
&
refPos
,
int
layer
);
#endif
};
...
...
@@ -322,6 +321,27 @@ public:
void
UnLink
(
void
);
void
Copy
(
DRAWSEGMENT
*
source
);
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param ref_pos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
HitTest
(
const
wxPoint
&
ref_pos
);
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
* @return wxString
*/
wxString
GetClass
()
const
{
return
wxT
(
"pgraphic"
);
}
#endif
};
...
...
include/trigo.h
View file @
c1e3416a
...
...
@@ -7,7 +7,7 @@
#define TRIGO_H
/* Prototype des fonctions de
TRIGO.CC
*/
/* Prototype des fonctions de
trigo.cpp
*/
void
RotatePoint
(
int
*
pX
,
int
*
pY
,
int
angle
);
void
RotatePoint
(
int
*
pX
,
int
*
pY
,
int
cx
,
int
cy
,
int
angle
);
void
RotatePoint
(
wxPoint
*
point
,
const
wxPoint
&
centre
,
int
angle
);
...
...
@@ -19,6 +19,7 @@ int ArcTangente(int dy, int dx);
Analogue a atan2 ( mais plus rapide pour les caculs si
l'angle est souvent 0, -1800, ou +- 900 */
bool
DistanceTest
(
int
seuil
,
int
dx
,
int
dy
,
int
spot_cX
,
int
spot_cY
);
...
...
pcbnew/class_board.cpp
View file @
c1e3416a
...
...
@@ -290,75 +290,64 @@ void BOARD::Show( int nestLevel, std::ostream& os )
// see pcbstruct.h
EDA_BaseStruct
*
BOARD
::
FindPadOrModule
(
const
wxPoint
&
refPos
,
int
layer
,
int
typeloc
)
EDA_BaseStruct
*
BOARD
::
FindPadOrModule
(
const
wxPoint
&
refPos
,
int
layer
)
{
class
PadOrModule
:
public
INSPECTOR
{
public
:
EDA_BaseStruct
*
found
;
int
layer
;
int
typeloc
;
PadOrModule
(
int
alayer
,
int
atypeloc
)
:
found
(
0
),
layer
(
alayer
),
typeloc
(
atypeloc
)
{}
PadOrModule
(
int
alayer
)
:
found
(
0
),
// found is NULL
layer
(
alayer
)
{
}
SEARCH_RESULT
Inspect
(
EDA_BaseStruct
*
testItem
,
const
void
*
testData
)
{
const
wxPoint
*
refPos
=
(
const
wxPoint
*
)
testData
;
const
wxPoint
&
refPos
=
*
(
const
wxPoint
*
)
testData
;
if
(
testItem
->
m_StructType
==
TYPE
MODULE
)
if
(
testItem
->
m_StructType
==
TYPE
PAD
)
{
int
mlayer
=
((
MODULE
*
)
testItem
)
->
m_Layer
;
if
(
typeloc
&
MATCH_LAYER
)
{
if
(
layer
!=
mlayer
)
return
SEARCH_CONTINUE
;
}
if
(
typeloc
&
VISIBLE_ONLY
)
{
if
(
!
IsModuleLayerVisible
(
mlayer
)
)
return
SEARCH_CONTINUE
;
}
if
(
testItem
->
HitTest
(
*
refPos
)
)
if
(
testItem
->
HitTest
(
refPos
)
)
{
found
=
testItem
;
return
SEARCH_QUIT
;
}
}
else
if
(
testItem
->
m_StructType
==
TYPEPAD
)
else
if
(
testItem
->
m_StructType
==
TYPEMODULE
)
{
if
(
testItem
->
HitTest
(
*
refPos
)
)
int
mlayer
=
((
MODULE
*
)
testItem
)
->
m_Layer
;
// consider only visible modules
if
(
IsModuleLayerVisible
(
mlayer
)
)
{
found
=
testItem
;
return
SEARCH_QUIT
;
if
(
testItem
->
HitTest
(
refPos
)
)
{
// save regardless of layer test, but only quit if
// layer matches, otherwise use this item if no future
// layer match.
found
=
testItem
;
if
(
layer
==
mlayer
)
return
SEARCH_QUIT
;
}
}
}
else
{
int
debug
=
1
;
/* this should not happen, because of scanTypes */
}
return
SEARCH_CONTINUE
;
}
};
PadOrModule
inspector1
(
layer
,
MATCH_LAYER
);
PadOrModule
inspector2
(
layer
,
VISIBLE_ONLY
);
PadOrModule
inspector
(
layer
);
// search only for PADs first, then MODULES, and preferably a layer match
static
const
KICAD_T
scanTypes
[]
=
{
TYPEPAD
,
TYPEMODULE
,
EOT
};
// search the current layer first
if
(
SEARCH_QUIT
==
IterateForward
(
m_Modules
,
&
inspector1
,
&
refPos
,
scanTypes
)
)
return
inspector1
.
found
;
// if not found, set layer to don't care and search again
if
(
SEARCH_QUIT
==
IterateForward
(
m_Modules
,
&
inspector2
,
&
refPos
,
scanTypes
)
)
return
inspector2
.
found
;
IterateForward
(
m_Modules
,
&
inspector
,
&
refPos
,
scanTypes
);
return
NULL
;
return
inspector
.
found
;
}
#endif
pcbnew/class_cotation.cpp
View file @
c1e3416a
...
...
@@ -7,348 +7,476 @@
#include "common.h"
#include "pcbnew.h"
#include "trigo.h"
COTATION
::
COTATION
(
EDA_BaseStruct
*
StructFather
)
:
EDA_BaseStruct
(
StructFather
,
TYPECOTATION
)
COTATION
::
COTATION
(
EDA_BaseStruct
*
StructFather
)
:
EDA_BaseStruct
(
StructFather
,
TYPECOTATION
)
{
m_Layer
=
DRAW_LAYER
;
m_Width
=
50
;
m_Value
=
0
;
m_Shape
=
0
;
m_Unit
=
INCHES
;
m_Text
=
new
TEXTE_PCB
(
this
);
m_Layer
=
DRAW_LAYER
;
m_Width
=
50
;
m_Value
=
0
;
m_Shape
=
0
;
m_Unit
=
INCHES
;
m_Text
=
new
TEXTE_PCB
(
this
);
}
/* Effacement memoire de la structure */
COTATION
::~
COTATION
(
void
)
COTATION
::~
COTATION
(
void
)
{
delete
m_Text
;
delete
m_Text
;
}
/* supprime du chainage la structure Struct
les structures arrieres et avant sont chainees directement
*
les structures arrieres et avant sont chainees directement
*/
void
COTATION
::
UnLink
(
void
)
{
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
((
BOARD
*
)
Pback
)
->
m_Drawings
=
Pnext
;
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
(
(
BOARD
*
)
Pback
)
->
m_Drawings
=
Pnext
;
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
}
/* Changement du texte de la cotation */
void
COTATION
::
SetText
(
const
wxString
&
NewText
)
void
COTATION
::
SetText
(
const
wxString
&
NewText
)
{
m_Text
->
m_Text
=
NewText
;
m_Text
->
m_Text
=
NewText
;
}
/*************************************/
void
COTATION
::
Copy
(
COTATION
*
source
)
void
COTATION
::
Copy
(
COTATION
*
source
)
/*************************************/
{
m_Value
=
source
->
m_Value
;
m_Layer
=
source
->
m_Layer
;
m_Width
=
source
->
m_Width
;
m_Pos
=
source
->
m_Pos
;
m_Shape
=
source
->
m_Shape
;
m_Unit
=
source
->
m_Unit
;
m_TimeStamp
=
GetTimeStamp
();
m_Text
->
Copy
(
source
->
m_Text
);
Barre_ox
=
source
->
Barre_ox
;
Barre_oy
=
source
->
Barre_oy
;
Barre_fx
=
source
->
Barre_fx
;
Barre_fy
=
source
->
Barre_fy
;
TraitG_ox
=
source
->
TraitG_ox
;
TraitG_oy
=
source
->
TraitG_oy
;
TraitG_fx
=
source
->
TraitG_fx
;
TraitG_fy
=
source
->
TraitG_fy
;
TraitD_ox
=
source
->
TraitD_ox
;
TraitD_oy
=
source
->
TraitD_oy
;
TraitD_fx
=
source
->
TraitD_fx
;
TraitD_fy
=
source
->
TraitD_fy
;
FlecheD1_ox
=
source
->
FlecheD1_ox
;
FlecheD1_oy
=
source
->
FlecheD1_oy
;
FlecheD1_fx
=
source
->
FlecheD1_fx
;
FlecheD1_fy
=
source
->
FlecheD1_fy
;
FlecheD2_ox
=
source
->
FlecheD2_ox
;
FlecheD2_oy
=
source
->
FlecheD2_oy
;
FlecheD2_fx
=
source
->
FlecheD2_fx
;
FlecheD2_fy
=
source
->
FlecheD2_fy
;
FlecheG1_ox
=
source
->
FlecheG1_ox
;
FlecheG1_oy
=
source
->
FlecheG1_oy
;
FlecheG1_fx
=
source
->
FlecheG1_fx
;
FlecheG1_fy
=
source
->
FlecheG1_fy
;
FlecheG2_ox
=
source
->
FlecheG2_ox
;
FlecheG2_oy
=
source
->
FlecheG2_oy
;
FlecheG2_fx
=
source
->
FlecheG2_fx
;
FlecheG2_fy
=
source
->
FlecheG2_fy
;
m_Value
=
source
->
m_Value
;
m_Layer
=
source
->
m_Layer
;
m_Width
=
source
->
m_Width
;
m_Pos
=
source
->
m_Pos
;
m_Shape
=
source
->
m_Shape
;
m_Unit
=
source
->
m_Unit
;
m_TimeStamp
=
GetTimeStamp
();
m_Text
->
Copy
(
source
->
m_Text
);
Barre_ox
=
source
->
Barre_ox
;
Barre_oy
=
source
->
Barre_oy
;
Barre_fx
=
source
->
Barre_fx
;
Barre_fy
=
source
->
Barre_fy
;
TraitG_ox
=
source
->
TraitG_ox
;
TraitG_oy
=
source
->
TraitG_oy
;
TraitG_fx
=
source
->
TraitG_fx
;
TraitG_fy
=
source
->
TraitG_fy
;
TraitD_ox
=
source
->
TraitD_ox
;
TraitD_oy
=
source
->
TraitD_oy
;
TraitD_fx
=
source
->
TraitD_fx
;
TraitD_fy
=
source
->
TraitD_fy
;
FlecheD1_ox
=
source
->
FlecheD1_ox
;
FlecheD1_oy
=
source
->
FlecheD1_oy
;
FlecheD1_fx
=
source
->
FlecheD1_fx
;
FlecheD1_fy
=
source
->
FlecheD1_fy
;
FlecheD2_ox
=
source
->
FlecheD2_ox
;
FlecheD2_oy
=
source
->
FlecheD2_oy
;
FlecheD2_fx
=
source
->
FlecheD2_fx
;
FlecheD2_fy
=
source
->
FlecheD2_fy
;
FlecheG1_ox
=
source
->
FlecheG1_ox
;
FlecheG1_oy
=
source
->
FlecheG1_oy
;
FlecheG1_fx
=
source
->
FlecheG1_fx
;
FlecheG1_fy
=
source
->
FlecheG1_fy
;
FlecheG2_ox
=
source
->
FlecheG2_ox
;
FlecheG2_oy
=
source
->
FlecheG2_oy
;
FlecheG2_fx
=
source
->
FlecheG2_fx
;
FlecheG2_fy
=
source
->
FlecheG2_fy
;
}
/***************************************************************/
bool
COTATION
::
ReadCotationDescr
(
FILE
*
File
,
int
*
LineNum
)
bool
COTATION
::
ReadCotationDescr
(
FILE
*
File
,
int
*
LineNum
)
/***************************************************************/
{
char
Line
[
2048
],
Text
[
2048
];
while
(
GetLine
(
File
,
Line
,
LineNum
)
!=
NULL
)
{
if
(
strnicmp
(
Line
,
"$EndCOTATION"
,
4
)
==
0
)
return
TRUE
;
if
(
Line
[
0
]
==
'V'
)
{
sscanf
(
Line
+
2
,
" %d"
,
&
m_Value
);
continue
;
}
if
(
Line
[
0
]
==
'G'
)
{
sscanf
(
Line
+
2
,
" %d %d %lX"
,
&
m_Shape
,
&
m_Layer
,
&
m_TimeStamp
);
/* Mise a jour des param .layer des sous structures */
if
(
m_Layer
<
FIRST_NO_COPPER_LAYER
)
m_Layer
=
FIRST_NO_COPPER_LAYER
;
if
(
m_Layer
>
LAST_NO_COPPER_LAYER
)
m_Layer
=
LAST_NO_COPPER_LAYER
;
m_Text
->
m_Layer
=
m_Layer
;
continue
;
}
if
(
Line
[
0
]
==
'T'
)
{
ReadDelimitedText
(
Text
,
Line
+
2
,
sizeof
(
Text
)
);
m_Text
->
m_Text
=
CONV_FROM_UTF8
(
Text
);
continue
;
}
if
(
Line
[
0
]
==
'P'
)
{
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d %d"
,
&
m_Text
->
m_Pos
.
x
,
&
m_Text
->
m_Pos
.
y
,
&
m_Text
->
m_Size
.
x
,
&
m_Text
->
m_Size
.
y
,
&
m_Text
->
m_Width
,
&
m_Text
->
m_Orient
,
&
m_Text
->
m_Miroir
);
m_Pos
=
m_Text
->
m_Pos
;
continue
;
}
if
(
Line
[
0
]
==
'S'
)
{
switch
(
Line
[
1
]
)
{
int
Dummy
;
case
'b'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
Barre_ox
,
&
Barre_oy
,
&
Barre_fx
,
&
Barre_fy
,
&
m_Width
);
break
;
case
'd'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
TraitD_ox
,
&
TraitD_oy
,
&
TraitD_fx
,
&
TraitD_fy
,
&
Dummy
);
break
;
case
'g'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
TraitG_ox
,
&
TraitG_oy
,
&
TraitG_fx
,
&
TraitG_fy
,
&
Dummy
);
break
;
case
'1'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheD1_ox
,
&
FlecheD1_oy
,
&
FlecheD1_fx
,
&
FlecheD1_fy
,
&
Dummy
);
break
;
case
'2'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheD2_ox
,
&
FlecheD2_oy
,
&
FlecheD2_fx
,
&
FlecheD2_fy
,
&
Dummy
);
break
;
case
'3'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d
\n
"
,
&
Dummy
,
&
FlecheG1_ox
,
&
FlecheG1_oy
,
&
FlecheG1_fx
,
&
FlecheG1_fy
,
&
Dummy
);
break
;
case
'4'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheG2_ox
,
&
FlecheG2_oy
,
&
FlecheG2_fx
,
&
FlecheG2_fy
,
&
Dummy
);
break
;
}
continue
;
}
}
return
FALSE
;
char
Line
[
2048
],
Text
[
2048
];
while
(
GetLine
(
File
,
Line
,
LineNum
)
!=
NULL
)
{
if
(
strnicmp
(
Line
,
"$EndCOTATION"
,
4
)
==
0
)
return
TRUE
;
if
(
Line
[
0
]
==
'V'
)
{
sscanf
(
Line
+
2
,
" %d"
,
&
m_Value
);
continue
;
}
if
(
Line
[
0
]
==
'G'
)
{
sscanf
(
Line
+
2
,
" %d %d %lX"
,
&
m_Shape
,
&
m_Layer
,
&
m_TimeStamp
);
/* Mise a jour des param .layer des sous structures */
if
(
m_Layer
<
FIRST_NO_COPPER_LAYER
)
m_Layer
=
FIRST_NO_COPPER_LAYER
;
if
(
m_Layer
>
LAST_NO_COPPER_LAYER
)
m_Layer
=
LAST_NO_COPPER_LAYER
;
m_Text
->
m_Layer
=
m_Layer
;
continue
;
}
if
(
Line
[
0
]
==
'T'
)
{
ReadDelimitedText
(
Text
,
Line
+
2
,
sizeof
(
Text
)
);
m_Text
->
m_Text
=
CONV_FROM_UTF8
(
Text
);
continue
;
}
if
(
Line
[
0
]
==
'P'
)
{
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d %d"
,
&
m_Text
->
m_Pos
.
x
,
&
m_Text
->
m_Pos
.
y
,
&
m_Text
->
m_Size
.
x
,
&
m_Text
->
m_Size
.
y
,
&
m_Text
->
m_Width
,
&
m_Text
->
m_Orient
,
&
m_Text
->
m_Miroir
);
m_Pos
=
m_Text
->
m_Pos
;
continue
;
}
if
(
Line
[
0
]
==
'S'
)
{
switch
(
Line
[
1
]
)
{
int
Dummy
;
case
'b'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
Barre_ox
,
&
Barre_oy
,
&
Barre_fx
,
&
Barre_fy
,
&
m_Width
);
break
;
case
'd'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
TraitD_ox
,
&
TraitD_oy
,
&
TraitD_fx
,
&
TraitD_fy
,
&
Dummy
);
break
;
case
'g'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
TraitG_ox
,
&
TraitG_oy
,
&
TraitG_fx
,
&
TraitG_fy
,
&
Dummy
);
break
;
case
'1'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheD1_ox
,
&
FlecheD1_oy
,
&
FlecheD1_fx
,
&
FlecheD1_fy
,
&
Dummy
);
break
;
case
'2'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheD2_ox
,
&
FlecheD2_oy
,
&
FlecheD2_fx
,
&
FlecheD2_fy
,
&
Dummy
);
break
;
case
'3'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d
\n
"
,
&
Dummy
,
&
FlecheG1_ox
,
&
FlecheG1_oy
,
&
FlecheG1_fx
,
&
FlecheG1_fy
,
&
Dummy
);
break
;
case
'4'
:
sscanf
(
Line
+
2
,
" %d %d %d %d %d %d"
,
&
Dummy
,
&
FlecheG2_ox
,
&
FlecheG2_oy
,
&
FlecheG2_fx
,
&
FlecheG2_fy
,
&
Dummy
);
break
;
}
continue
;
}
}
return
FALSE
;
}
/**************************************************/
bool
COTATION
::
WriteCotationDescr
(
FILE
*
File
)
bool
COTATION
::
WriteCotationDescr
(
FILE
*
File
)
/**************************************************/
{
if
(
GetState
(
DELETED
)
)
return
FALSE
;
if
(
GetState
(
DELETED
)
)
return
FALSE
;
fprintf
(
File
,
"$COTATION
\n
"
);
fprintf
(
File
,
"$COTATION
\n
"
);
fprintf
(
File
,
"Ge %d %d %lX
\n
"
,
m_Shape
,
m_Layer
,
m_TimeStamp
);
fprintf
(
File
,
"Ge %d %d %lX
\n
"
,
m_Shape
,
m_Layer
,
m_TimeStamp
);
fprintf
(
File
,
"Va %d
\n
"
,
m_Value
);
fprintf
(
File
,
"Va %d
\n
"
,
m_Value
);
if
(
!
m_Text
->
m_Text
.
IsEmpty
()
)
fprintf
(
File
,
"Te
\"
%s
\"\n
"
,
CONV_TO_UTF8
(
m_Text
->
m_Text
));
else
fprintf
(
File
,
"Te
\"
?
\"\n
"
);
if
(
!
m_Text
->
m_Text
.
IsEmpty
()
)
fprintf
(
File
,
"Te
\"
%s
\"\n
"
,
CONV_TO_UTF8
(
m_Text
->
m_Text
)
);
else
fprintf
(
File
,
"Te
\"
?
\"\n
"
);
fprintf
(
File
,
"Po %d %d %d %d %d %d %d
\n
"
,
m_Text
->
m_Pos
.
x
,
m_Text
->
m_Pos
.
y
,
m_Text
->
m_Size
.
x
,
m_Text
->
m_Size
.
y
,
m_Text
->
m_Width
,
m_Text
->
m_Orient
,
m_Text
->
m_Miroir
);
fprintf
(
File
,
"Po %d %d %d %d %d %d %d
\n
"
,
m_Text
->
m_Pos
.
x
,
m_Text
->
m_Pos
.
y
,
m_Text
->
m_Size
.
x
,
m_Text
->
m_Size
.
y
,
m_Text
->
m_Width
,
m_Text
->
m_Orient
,
m_Text
->
m_Miroir
);
fprintf
(
File
,
"Sb %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
Barre_ox
,
Barre_oy
,
Barre_fx
,
Barre_fy
,
m_Width
);
fprintf
(
File
,
"Sb %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
Barre_ox
,
Barre_oy
,
Barre_fx
,
Barre_fy
,
m_Width
);
fprintf
(
File
,
"Sd %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
TraitD_ox
,
TraitD_oy
,
TraitD_fx
,
TraitD_fy
,
m_Width
);
fprintf
(
File
,
"Sd %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
TraitD_ox
,
TraitD_oy
,
TraitD_fx
,
TraitD_fy
,
m_Width
);
fprintf
(
File
,
"Sg %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
TraitG_ox
,
TraitG_oy
,
TraitG_fx
,
TraitG_fy
,
m_Width
);
fprintf
(
File
,
"Sg %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
TraitG_ox
,
TraitG_oy
,
TraitG_fx
,
TraitG_fy
,
m_Width
);
fprintf
(
File
,
"S1 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheD1_ox
,
FlecheD1_oy
,
FlecheD1_fx
,
FlecheD1_fy
,
m_Width
);
fprintf
(
File
,
"S1 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheD1_ox
,
FlecheD1_oy
,
FlecheD1_fx
,
FlecheD1_fy
,
m_Width
);
fprintf
(
File
,
"S2 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheD2_ox
,
FlecheD2_oy
,
FlecheD2_fx
,
FlecheD2_fy
,
m_Width
);
fprintf
(
File
,
"S2 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheD2_ox
,
FlecheD2_oy
,
FlecheD2_fx
,
FlecheD2_fy
,
m_Width
);
fprintf
(
File
,
"S3 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheG1_ox
,
FlecheG1_oy
,
FlecheG1_fx
,
FlecheG1_fy
,
m_Width
);
fprintf
(
File
,
"S3 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheG1_ox
,
FlecheG1_oy
,
FlecheG1_fx
,
FlecheG1_fy
,
m_Width
);
fprintf
(
File
,
"S4 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheG2_ox
,
FlecheG2_oy
,
FlecheG2_fx
,
FlecheG2_fy
,
m_Width
);
fprintf
(
File
,
"S4 %d %d %d %d %d %d
\n
"
,
S_SEGMENT
,
FlecheG2_ox
,
FlecheG2_oy
,
FlecheG2_fx
,
FlecheG2_fy
,
m_Width
);
fprintf
(
File
,
"$EndCOTATION
\n
"
);
fprintf
(
File
,
"$EndCOTATION
\n
"
);
return
(
1
)
;
return
1
;
}
/************************************************************************/
void
COTATION
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
)
void
COTATION
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
)
/************************************************************************/
/* impression de 1 cotation : serie de n segments + 1 texte
*/
*/
{
int
ox
,
oy
,
typeaff
,
width
,
gcolor
;
int
zoom
=
panel
->
GetScreen
()
->
GetZoom
();
ox
=
offset
.
x
;
oy
=
offset
.
y
;
m_Text
->
Draw
(
panel
,
DC
,
offset
,
mode_color
);
gcolor
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
gcolor
&
ITEM_NOT_SHOW
)
!=
0
)
return
;
GRSetDrawMode
(
DC
,
mode_color
);
typeaff
=
DisplayOpt
.
DisplayDrawItems
;
width
=
m_Width
;
if
(
width
/
zoom
<
2
)
typeaff
=
FILAIRE
;
switch
(
typeaff
)
{
case
FILAIRE
:
width
=
0
;
case
FILLED
:
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
Barre_ox
-
ox
,
Barre_oy
-
oy
,
Barre_fx
-
ox
,
Barre_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
TraitG_ox
-
ox
,
TraitG_oy
-
oy
,
TraitG_fx
-
ox
,
TraitG_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
TraitD_ox
-
ox
,
TraitD_oy
-
oy
,
TraitD_fx
-
ox
,
TraitD_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD1_ox
-
ox
,
FlecheD1_oy
-
oy
,
FlecheD1_fx
-
ox
,
FlecheD1_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD2_ox
-
ox
,
FlecheD2_oy
-
oy
,
FlecheD2_fx
-
ox
,
FlecheD2_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG1_ox
-
ox
,
FlecheG1_oy
-
oy
,
FlecheG1_fx
-
ox
,
FlecheG1_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG2_ox
-
ox
,
FlecheG2_oy
-
oy
,
FlecheG2_fx
-
ox
,
FlecheG2_fy
-
oy
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
Barre_ox
-
ox
,
Barre_oy
-
oy
,
Barre_fx
-
ox
,
Barre_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
TraitG_ox
-
ox
,
TraitG_oy
-
oy
,
TraitG_fx
-
ox
,
TraitG_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
TraitD_ox
-
ox
,
TraitD_oy
-
oy
,
TraitD_fx
-
ox
,
TraitD_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD1_ox
-
ox
,
FlecheD1_oy
-
oy
,
FlecheD1_fx
-
ox
,
FlecheD1_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD2_ox
-
ox
,
FlecheD2_oy
-
oy
,
FlecheD2_fx
-
ox
,
FlecheD2_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG1_ox
-
ox
,
FlecheG1_oy
-
oy
,
FlecheG1_fx
-
ox
,
FlecheG1_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG2_ox
-
ox
,
FlecheG2_oy
-
oy
,
FlecheG2_fx
-
ox
,
FlecheG2_fy
-
oy
,
width
,
gcolor
);
break
;
}
int
ox
,
oy
,
typeaff
,
width
,
gcolor
;
int
zoom
=
panel
->
GetScreen
()
->
GetZoom
();
ox
=
offset
.
x
;
oy
=
offset
.
y
;
m_Text
->
Draw
(
panel
,
DC
,
offset
,
mode_color
);
gcolor
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
gcolor
&
ITEM_NOT_SHOW
)
!=
0
)
return
;
GRSetDrawMode
(
DC
,
mode_color
);
typeaff
=
DisplayOpt
.
DisplayDrawItems
;
width
=
m_Width
;
if
(
width
/
zoom
<
2
)
typeaff
=
FILAIRE
;
switch
(
typeaff
)
{
case
FILAIRE
:
width
=
0
;
case
FILLED
:
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
Barre_ox
-
ox
,
Barre_oy
-
oy
,
Barre_fx
-
ox
,
Barre_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
TraitG_ox
-
ox
,
TraitG_oy
-
oy
,
TraitG_fx
-
ox
,
TraitG_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
TraitD_ox
-
ox
,
TraitD_oy
-
oy
,
TraitD_fx
-
ox
,
TraitD_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD1_ox
-
ox
,
FlecheD1_oy
-
oy
,
FlecheD1_fx
-
ox
,
FlecheD1_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD2_ox
-
ox
,
FlecheD2_oy
-
oy
,
FlecheD2_fx
-
ox
,
FlecheD2_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG1_ox
-
ox
,
FlecheG1_oy
-
oy
,
FlecheG1_fx
-
ox
,
FlecheG1_fy
-
oy
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG2_ox
-
ox
,
FlecheG2_oy
-
oy
,
FlecheG2_fx
-
ox
,
FlecheG2_fy
-
oy
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
Barre_ox
-
ox
,
Barre_oy
-
oy
,
Barre_fx
-
ox
,
Barre_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
TraitG_ox
-
ox
,
TraitG_oy
-
oy
,
TraitG_fx
-
ox
,
TraitG_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
TraitD_ox
-
ox
,
TraitD_oy
-
oy
,
TraitD_fx
-
ox
,
TraitD_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD1_ox
-
ox
,
FlecheD1_oy
-
oy
,
FlecheD1_fx
-
ox
,
FlecheD1_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheD2_ox
-
ox
,
FlecheD2_oy
-
oy
,
FlecheD2_fx
-
ox
,
FlecheD2_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG1_ox
-
ox
,
FlecheG1_oy
-
oy
,
FlecheG1_fx
-
ox
,
FlecheG1_fy
-
oy
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
FlecheG2_ox
-
ox
,
FlecheG2_oy
-
oy
,
FlecheG2_fx
-
ox
,
FlecheG2_fy
-
oy
,
width
,
gcolor
);
break
;
}
}
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param ref_pos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
COTATION
::
HitTest
(
const
wxPoint
&
ref_pos
)
{
int
ux0
,
uy0
;
int
dx
,
dy
,
spot_cX
,
spot_cY
;
if
(
m_Text
)
{
// because HitTest() is present in both base classes of TEXTE_PCB
// use a clarifying cast to tell compiler which HitTest()
// to call.
if
(
static_cast
<
EDA_TextStruct
*>
(
m_Text
)
->
HitTest
(
ref_pos
)
)
return
true
;
}
/* Localisation des SEGMENTS ?) */
ux0
=
Barre_ox
;
uy0
=
Barre_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Barre_fx
-
ux0
;
dy
=
Barre_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
TraitG_ox
;
uy0
=
TraitG_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
TraitG_fx
-
ux0
;
dy
=
TraitG_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
TraitD_ox
;
uy0
=
TraitD_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
TraitD_fx
-
ux0
;
dy
=
TraitD_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
FlecheD1_ox
;
uy0
=
FlecheD1_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
FlecheD1_fx
-
ux0
;
dy
=
FlecheD1_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
FlecheD2_ox
;
uy0
=
FlecheD2_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
FlecheD2_fx
-
ux0
;
dy
=
FlecheD2_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
FlecheG1_ox
;
uy0
=
FlecheG1_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
FlecheG1_fx
-
ux0
;
dy
=
FlecheG1_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
ux0
=
FlecheG2_ox
;
uy0
=
FlecheG2_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
FlecheG2_fx
-
ux0
;
dy
=
FlecheG2_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
return
false
;
}
pcbnew/class_cotation.h
View file @
c1e3416a
...
...
@@ -6,42 +6,62 @@
#include "base_struct.h"
class
COTATION
:
public
EDA_BaseStruct
class
COTATION
:
public
EDA_BaseStruct
{
public
:
int
m_Layer
;
// 0.. 32 ( NON bit a bit)
int
m_Width
;
wxPoint
m_Pos
;
int
m_Shape
;
int
m_Unit
;
/* 0 = inches, 1 = mm */
int
m_Value
;
/* valeur en unites PCB de la cote */
public
:
int
m_Layer
;
// 0.. 32 ( NON bit a bit)
int
m_Width
;
wxPoint
m_Pos
;
int
m_Shape
;
int
m_Unit
;
/* 0 = inches, 1 = mm */
int
m_Value
;
/* valeur en unites PCB de la cote */
TEXTE_PCB
*
m_Text
;
/* pour affichage du texte */
int
Barre_ox
,
Barre_oy
,
Barre_fx
,
Barre_fy
;
int
TraitG_ox
,
TraitG_oy
,
TraitG_fx
,
TraitG_fy
;
int
TraitD_ox
,
TraitD_oy
,
TraitD_fx
,
TraitD_fy
;
int
FlecheD1_ox
,
FlecheD1_oy
,
FlecheD1_fx
,
FlecheD1_fy
;
int
FlecheD2_ox
,
FlecheD2_oy
,
FlecheD2_fx
,
FlecheD2_fy
;
int
FlecheG1_ox
,
FlecheG1_oy
,
FlecheG1_fx
,
FlecheG1_fy
;
int
FlecheG2_ox
,
FlecheG2_oy
,
FlecheG2_fx
,
FlecheG2_fy
;
TEXTE_PCB
*
m_Text
;
/* pour affichage du texte */
int
Barre_ox
,
Barre_oy
,
Barre_fx
,
Barre_fy
;
int
TraitG_ox
,
TraitG_oy
,
TraitG_fx
,
TraitG_fy
;
int
TraitD_ox
,
TraitD_oy
,
TraitD_fx
,
TraitD_fy
;
int
FlecheD1_ox
,
FlecheD1_oy
,
FlecheD1_fx
,
FlecheD1_fy
;
int
FlecheD2_ox
,
FlecheD2_oy
,
FlecheD2_fx
,
FlecheD2_fy
;
int
FlecheG1_ox
,
FlecheG1_oy
,
FlecheG1_fx
,
FlecheG1_fy
;
int
FlecheG2_ox
,
FlecheG2_oy
,
FlecheG2_fx
,
FlecheG2_fy
;
public
:
COTATION
(
EDA_BaseStruct
*
StructFather
);
~
COTATION
(
void
);
public
:
COTATION
(
EDA_BaseStruct
*
StructFather
);
~
COTATION
(
void
);
bool
ReadCotationDescr
(
FILE
*
File
,
int
*
LineNum
);
bool
WriteCotationDescr
(
FILE
*
File
);
bool
ReadCotationDescr
(
FILE
*
File
,
int
*
LineNum
);
bool
WriteCotationDescr
(
FILE
*
File
);
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
/* Modification du texte de la cotation */
void
SetText
(
const
wxString
&
NewText
);
/* Modification du texte de la cotation */
void
SetText
(
const
wxString
&
NewText
);
void
Copy
(
COTATION
*
source
);
void
Copy
(
COTATION
*
source
);
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
);
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
);
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param ref_pos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
HitTest
(
const
wxPoint
&
ref_pos
);
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
* @return wxString
*/
wxString
GetClass
()
const
{
return
wxT
(
"DIMENSION"
);
}
#endif
};
#endif
// #define COTATION_H
#endif
// #define COTATION_H
pcbnew/class_edge_mod.cpp
View file @
c1e3416a
...
...
@@ -438,6 +438,73 @@ int EDGE_MODULE::ReadDescr( char* Line, FILE* File,
}
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param refPos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
EDGE_MODULE
::
HitTest
(
const
wxPoint
&
ref_pos
)
{
int
uxf
,
uyf
;
int
rayon
,
dist
;
int
dx
,
dy
,
spot_cX
,
spot_cY
;
int
ux0
,
uy0
;
ux0
=
m_Start
.
x
;
uy0
=
m_Start
.
y
;
uxf
=
m_End
.
x
;
uyf
=
m_End
.
y
;
switch
(
m_Shape
)
{
case
S_SEGMENT
:
/* recalcul des coordonnees avec ux0,uy0 = origine des coord. */
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
dx
=
uxf
-
ux0
;
dy
=
uyf
-
uy0
;
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
break
;
case
S_CIRCLE
:
rayon
=
(
int
)
hypot
(
(
double
)
(
uxf
-
ux0
),
(
double
)
(
uyf
-
uy0
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
ref_pos
.
x
-
ux0
),
(
double
)
(
ref_pos
.
y
-
uy0
)
);
if
(
abs
(
rayon
-
dist
)
<=
m_Width
)
return
true
;
break
;
case
S_ARC
:
rayon
=
(
int
)
hypot
(
(
double
)
(
uxf
-
ux0
),
(
double
)
(
uyf
-
uy0
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
ref_pos
.
x
-
ux0
),
(
double
)
(
ref_pos
.
y
-
uy0
)
);
if
(
abs
(
rayon
-
dist
)
>
m_Width
)
break
;
/* pour un arc, controle complementaire */
int
mouseAngle
=
(
int
)
ArcTangente
(
ref_pos
.
y
-
uy0
,
ref_pos
.
x
-
ux0
);
int
stAngle
=
(
int
)
ArcTangente
(
uyf
-
uy0
,
uxf
-
ux0
);
int
endAngle
=
stAngle
+
m_Angle
;
if
(
endAngle
>
3600
)
{
stAngle
-=
3600
;
endAngle
-=
3600
;
}
if
(
(
mouseAngle
>=
stAngle
)
&&
(
mouseAngle
<=
endAngle
)
)
return
true
;
break
;
}
return
false
;
// an unknown m_Shape also returns false
}
#if defined(DEBUG)
/**
* Function Show
...
...
pcbnew/class_edge_mod.h
View file @
c1e3416a
...
...
@@ -41,6 +41,14 @@ public:
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
draw_mode
);
void
Draw3D
(
Pcb3D_GLCanvas
*
glcanvas
);
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param refPos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
HitTest
(
const
wxPoint
&
refPos
);
#if defined(DEBUG)
/**
...
...
@@ -50,7 +58,7 @@ public:
*/
virtual
wxString
GetClass
()
const
{
return
wxT
(
"GRAPHIC"
);
return
wxT
(
"
M
GRAPHIC"
);
// return wxT( "EDGE" ); ?
}
...
...
pcbnew/class_mire.cpp
View file @
c1e3416a
...
...
@@ -9,15 +9,15 @@
#include "pcbnew.h"
MIREPCB
::
MIREPCB
(
EDA_BaseStruct
*
StructFather
)
:
EDA_BaseStruct
(
StructFather
,
TYPEMIRE
)
MIREPCB
::
MIREPCB
(
EDA_BaseStruct
*
StructFather
)
:
EDA_BaseStruct
(
StructFather
,
TYPEMIRE
)
{
m_Shape
=
0
;
m_Size
=
5000
;
m_Shape
=
0
;
m_Size
=
5000
;
}
MIREPCB
::~
MIREPCB
(
void
)
MIREPCB
::~
MIREPCB
(
void
)
{
}
...
...
@@ -25,161 +25,186 @@ MIREPCB::~MIREPCB(void)
/***************************/
void
MIREPCB
::
UnLink
(
void
)
/***************************/
/* supprime du chainage la structure Struct
les structures arrieres et avant sont chainees directement
*
les structures arrieres et avant sont chainees directement
*/
{
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
((
BOARD
*
)
Pback
)
->
m_Drawings
=
Pnext
;
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
(
(
BOARD
*
)
Pback
)
->
m_Drawings
=
Pnext
;
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
}
/**********************************/
void
MIREPCB
::
Copy
(
MIREPCB
*
source
)
void
MIREPCB
::
Copy
(
MIREPCB
*
source
)
/**********************************/
{
m_Layer
=
source
->
m_Layer
;
m_Width
=
source
->
m_Width
;
m_Pos
=
source
->
m_Pos
;
m_Shape
=
source
->
m_Shape
;
m_Size
=
source
->
m_Size
;
m_TimeStamp
=
GetTimeStamp
();
m_Layer
=
source
->
m_Layer
;
m_Width
=
source
->
m_Width
;
m_Pos
=
source
->
m_Pos
;
m_Shape
=
source
->
m_Shape
;
m_Size
=
source
->
m_Size
;
m_TimeStamp
=
GetTimeStamp
();
}
/**************************************************************/
bool
MIREPCB
::
ReadMirePcbDescr
(
FILE
*
File
,
int
*
LineNum
)
bool
MIREPCB
::
ReadMirePcbDescr
(
FILE
*
File
,
int
*
LineNum
)
/**************************************************************/
/* Lecture de la description de 1 segment type Drawing PCB
*/
*/
{
char
Line
[
256
];
while
(
GetLine
(
File
,
Line
,
LineNum
)
!=
NULL
)
{
if
(
strnicmp
(
Line
,
"$End"
,
4
)
==
0
)
return
TRUE
;
/* fin de liste */
if
(
Line
[
0
]
==
'P'
)
{
sscanf
(
Line
+
2
,
" %X %d %d %d %d %d %lX"
,
&
m_Shape
,
&
m_Layer
,
&
m_Pos
.
x
,
&
m_Pos
.
y
,
&
m_Size
,
&
m_Width
,
&
m_TimeStamp
);
if
(
m_Layer
<
FIRST_NO_COPPER_LAYER
)
m_Layer
=
FIRST_NO_COPPER_LAYER
;
if
(
m_Layer
>
LAST_NO_COPPER_LAYER
)
m_Layer
=
LAST_NO_COPPER_LAYER
;
}
}
return
FALSE
;
char
Line
[
256
];
while
(
GetLine
(
File
,
Line
,
LineNum
)
!=
NULL
)
{
if
(
strnicmp
(
Line
,
"$End"
,
4
)
==
0
)
return
TRUE
;
/* fin de liste */
if
(
Line
[
0
]
==
'P'
)
{
sscanf
(
Line
+
2
,
" %X %d %d %d %d %d %lX"
,
&
m_Shape
,
&
m_Layer
,
&
m_Pos
.
x
,
&
m_Pos
.
y
,
&
m_Size
,
&
m_Width
,
&
m_TimeStamp
);
if
(
m_Layer
<
FIRST_NO_COPPER_LAYER
)
m_Layer
=
FIRST_NO_COPPER_LAYER
;
if
(
m_Layer
>
LAST_NO_COPPER_LAYER
)
m_Layer
=
LAST_NO_COPPER_LAYER
;
}
}
return
FALSE
;
}
/************************************************/
bool
MIREPCB
::
WriteMirePcbDescr
(
FILE
*
File
)
bool
MIREPCB
::
WriteMirePcbDescr
(
FILE
*
File
)
/************************************************/
{
if
(
GetState
(
DELETED
)
)
return
FALSE
;
fprintf
(
File
,
"$MIREPCB
\n
"
);
fprintf
(
File
,
"Po %X %d %d %d %d %d %8.8lX
\n
"
,
m_Shape
,
m_Layer
,
m_Pos
.
x
,
m_Pos
.
y
,
m_Size
,
m_Width
,
m_TimeStamp
);
fprintf
(
File
,
"$EndMIREPCB
\n
"
);
return
TRUE
;
if
(
GetState
(
DELETED
)
)
return
FALSE
;
fprintf
(
File
,
"$MIREPCB
\n
"
);
fprintf
(
File
,
"Po %X %d %d %d %d %d %8.8lX
\n
"
,
m_Shape
,
m_Layer
,
m_Pos
.
x
,
m_Pos
.
y
,
m_Size
,
m_Width
,
m_TimeStamp
);
fprintf
(
File
,
"$EndMIREPCB
\n
"
);
return
TRUE
;
}
/**********************************************************/
void
MIREPCB
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
)
void
MIREPCB
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
)
/**********************************************************/
/* Affichage de 1 mire : 2 segments + 1 cercle
le cercle a pour rayon le demi rayon de la mire
les 2 traits ont pour longueur le diametre de la mire
*/
*
le cercle a pour rayon le demi rayon de la mire
*
les 2 traits ont pour longueur le diametre de la mire
*/
{
int
rayon
,
ox
,
oy
,
gcolor
,
width
;
int
dx1
,
dx2
,
dy1
,
dy2
;
int
typeaff
;
int
zoom
;
ox
=
m_Pos
.
x
+
offset
.
x
;
oy
=
m_Pos
.
y
+
offset
.
y
;
gcolor
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
gcolor
&
ITEM_NOT_SHOW
)
!=
0
)
return
;
zoom
=
panel
->
GetZoom
();
GRSetDrawMode
(
DC
,
mode_color
);
typeaff
=
DisplayOpt
.
DisplayDrawItems
;
width
=
m_Width
;
if
(
width
/
zoom
<
2
)
typeaff
=
FILAIRE
;
/* Trace du cercle: */
rayon
=
m_Size
/
4
;
switch
(
typeaff
)
{
case
FILAIRE
:
width
=
0
;
case
FILLED
:
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
+
(
width
/
2
),
gcolor
)
;
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
-
(
width
/
2
),
gcolor
)
;
break
;
}
/* Trace des 2 traits */
rayon
=
m_Size
/
2
;
dx1
=
rayon
,
dy1
=
0
;
dx2
=
0
,
dy2
=
rayon
;
if
(
m_Shape
)
/* Forme X */
{
dx1
=
dy1
=
(
rayon
*
7
)
/
5
;
dx2
=
dx1
;
dy2
=
-
dy1
;
}
switch
(
typeaff
)
{
case
FILAIRE
:
case
FILLED
:
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx1
,
oy
-
dy1
,
ox
+
dx1
,
oy
+
dy1
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx2
,
oy
-
dy2
,
ox
+
dx2
,
oy
+
dy2
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx1
,
oy
-
dy1
,
ox
+
dx1
,
oy
+
dy1
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx2
,
oy
-
dy2
,
ox
+
dx2
,
oy
+
dy2
,
width
,
gcolor
);
break
;
}
int
rayon
,
ox
,
oy
,
gcolor
,
width
;
int
dx1
,
dx2
,
dy1
,
dy2
;
int
typeaff
;
int
zoom
;
ox
=
m_Pos
.
x
+
offset
.
x
;
oy
=
m_Pos
.
y
+
offset
.
y
;
gcolor
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
gcolor
&
ITEM_NOT_SHOW
)
!=
0
)
return
;
zoom
=
panel
->
GetZoom
();
GRSetDrawMode
(
DC
,
mode_color
);
typeaff
=
DisplayOpt
.
DisplayDrawItems
;
width
=
m_Width
;
if
(
width
/
zoom
<
2
)
typeaff
=
FILAIRE
;
/* Trace du cercle: */
rayon
=
m_Size
/
4
;
switch
(
typeaff
)
{
case
FILAIRE
:
width
=
0
;
case
FILLED
:
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
+
(
width
/
2
),
gcolor
);
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
ox
,
oy
,
rayon
-
(
width
/
2
),
gcolor
);
break
;
}
/* Trace des 2 traits */
rayon
=
m_Size
/
2
;
dx1
=
rayon
,
dy1
=
0
;
dx2
=
0
,
dy2
=
rayon
;
if
(
m_Shape
)
/* Forme X */
{
dx1
=
dy1
=
(
rayon
*
7
)
/
5
;
dx2
=
dx1
;
dy2
=
-
dy1
;
}
switch
(
typeaff
)
{
case
FILAIRE
:
case
FILLED
:
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx1
,
oy
-
dy1
,
ox
+
dx1
,
oy
+
dy1
,
width
,
gcolor
);
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx2
,
oy
-
dy2
,
ox
+
dx2
,
oy
+
dy2
,
width
,
gcolor
);
break
;
case
SKETCH
:
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx1
,
oy
-
dy1
,
ox
+
dx1
,
oy
+
dy1
,
width
,
gcolor
);
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
ox
-
dx2
,
oy
-
dy2
,
ox
+
dx2
,
oy
+
dy2
,
width
,
gcolor
);
break
;
}
}
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param refPos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
MIREPCB
::
HitTest
(
const
wxPoint
&
refPos
)
{
int
dX
=
refPos
.
x
-
m_Pos
.
x
;
int
dY
=
refPos
.
y
-
m_Pos
.
y
;
int
rayon
=
m_Size
/
2
;
return
abs
(
dX
)
<=
rayon
&&
abs
(
dY
)
<=
rayon
;
}
pcbnew/class_mire.h
View file @
c1e3416a
...
...
@@ -7,31 +7,38 @@
#include "base_struct.h"
class
MIREPCB
:
public
EDA_BaseStruct
{
public
:
int
m_Layer
;
// 0.. 32 ( NON bit a bit)
int
m_Width
;
wxPoint
m_Pos
;
int
m_Shape
;
// bit 0 : 0 = forme +, 1 = forme X
int
m_Size
;
public
:
MIREPCB
(
EDA_BaseStruct
*
StructFather
);
~
MIREPCB
(
void
);
bool
WriteMirePcbDescr
(
FILE
*
File
);
bool
ReadMirePcbDescr
(
FILE
*
File
,
int
*
LineNum
);
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
void
Copy
(
MIREPCB
*
source
);
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
);
class
MIREPCB
:
public
EDA_BaseStruct
{
public
:
int
m_Layer
;
// 0.. 32 ( NON bit a bit)
int
m_Width
;
wxPoint
m_Pos
;
int
m_Shape
;
// bit 0 : 0 = forme +, 1 = forme X
int
m_Size
;
public
:
MIREPCB
(
EDA_BaseStruct
*
StructFather
);
~
MIREPCB
(
void
);
bool
WriteMirePcbDescr
(
FILE
*
File
);
bool
ReadMirePcbDescr
(
FILE
*
File
,
int
*
LineNum
);
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
void
Copy
(
MIREPCB
*
source
);
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
const
wxPoint
&
offset
,
int
mode_color
);
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param refPos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
HitTest
(
const
wxPoint
&
refPos
);
};
#endif // #define MIRE_H
#endif // #define MIRE_H
pcbnew/class_module.h
View file @
c1e3416a
...
...
@@ -144,7 +144,6 @@ public:
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
...
...
pcbnew/class_track.cpp
View file @
c1e3416a
...
...
@@ -12,551 +12,665 @@
#include "cvpcb.h"
#endif
#include "trigo.h"
/**************************************/
/* Classes pour Pistes, Vias et Zones */
/**************************************/
/**************************************/
/* Classes pour Pistes, Vias et Zones */
/**************************************/
/* Constructeur des classes type pistes, vias et zones */
TRACK
::
TRACK
(
EDA_BaseStruct
*
StructFather
,
DrawStructureType
idtype
)
:
EDA_BaseLineStruct
(
StructFather
,
idtype
)
TRACK
::
TRACK
(
EDA_BaseStruct
*
StructFather
,
DrawStructureType
idtype
)
:
EDA_BaseLineStruct
(
StructFather
,
idtype
)
{
m_Shape
=
S_SEGMENT
;
start
=
end
=
NULL
;
m_NetCode
=
0
;
m_Sous_Netcode
=
0
;
m_Drill
=
-
1
;
m_Param
=
0
;
m_Shape
=
S_SEGMENT
;
start
=
end
=
NULL
;
m_NetCode
=
0
;
m_Sous_Netcode
=
0
;
m_Drill
=
-
1
;
m_Param
=
0
;
}
SEGZONE
::
SEGZONE
(
EDA_BaseStruct
*
StructFather
)
:
TRACK
(
StructFather
,
TYPEZONE
)
SEGZONE
::
SEGZONE
(
EDA_BaseStruct
*
StructFather
)
:
TRACK
(
StructFather
,
TYPEZONE
)
{
}
SEGVIA
::
SEGVIA
(
EDA_BaseStruct
*
StructFather
)
:
TRACK
(
StructFather
,
TYPEVIA
)
SEGVIA
::
SEGVIA
(
EDA_BaseStruct
*
StructFather
)
:
TRACK
(
StructFather
,
TYPEVIA
)
{
}
/* Copy constructor */
TRACK
::
TRACK
(
const
TRACK
&
Source
)
:
EDA_BaseLineStruct
(
Source
.
m_Parent
,
(
DrawStructureType
)
Source
.
m_StructType
)
TRACK
::
TRACK
(
const
TRACK
&
Source
)
:
EDA_BaseLineStruct
(
Source
.
m_Parent
,
(
DrawStructureType
)
Source
.
m_StructType
)
{
m_StructType
=
Source
.
m_StructType
;
m_Shape
=
Source
.
m_Shape
;
m_NetCode
=
Source
.
m_NetCode
;
m_Flags
=
Source
.
m_Flags
;
m_TimeStamp
=
Source
.
m_TimeStamp
;
SetStatus
(
Source
.
ReturnStatus
()
);
m_Layer
=
Source
.
m_Layer
;
m_Start
=
Source
.
m_Start
;
m_End
=
Source
.
m_End
;
m_Width
=
Source
.
m_Width
;
m_Drill
=
Source
.
m_Drill
;
m_Sous_Netcode
=
Source
.
m_Sous_Netcode
;
m_Param
=
Source
.
m_Param
;
m_StructType
=
Source
.
m_StructType
;
m_Shape
=
Source
.
m_Shape
;
m_NetCode
=
Source
.
m_NetCode
;
m_Flags
=
Source
.
m_Flags
;
m_TimeStamp
=
Source
.
m_TimeStamp
;
SetStatus
(
Source
.
ReturnStatus
()
);
m_Layer
=
Source
.
m_Layer
;
m_Start
=
Source
.
m_Start
;
m_End
=
Source
.
m_End
;
m_Width
=
Source
.
m_Width
;
m_Drill
=
Source
.
m_Drill
;
m_Sous_Netcode
=
Source
.
m_Sous_Netcode
;
m_Param
=
Source
.
m_Param
;
}
/***********************/
bool
TRACK
::
IsNull
(
void
)
bool
TRACK
::
IsNull
(
void
)
/***********************/
// return TRUE if segment lenght = 0
// return TRUE if segment length = 0
{
if
(
(
m_StructType
!=
TYPEVIA
)
&&
(
m_Start
==
m_End
)
)
return
TRUE
;
else
return
FALSE
;
if
(
(
m_StructType
!=
TYPEVIA
)
&&
(
m_Start
==
m_End
)
)
return
TRUE
;
else
return
FALSE
;
}
/*************************************************************/
int
TRACK
::
IsPointOnEnds
(
const
wxPoint
&
point
,
int
min_dist
)
int
TRACK
::
IsPointOnEnds
(
const
wxPoint
&
point
,
int
min_dist
)
/*************************************************************/
/* Return:
STARTPOINT if point if near (dist = min_dist) star point
ENDPOINT if point if near (dist = min_dist) end point
STARTPOINT|ENDPOINT if point if near (dist = min_dist) both ends
0 if no
if min_dist < 0: min_dist = track_width/2
*/
*
STARTPOINT if point if near (dist = min_dist) star point
*
ENDPOINT if point if near (dist = min_dist) end point
*
STARTPOINT|ENDPOINT if point if near (dist = min_dist) both ends
*
0 if no
*
if min_dist < 0: min_dist = track_width/2
*/
{
int
dx
,
dy
;
int
result
=
0
;
if
(
min_dist
<
0
)
min_dist
=
m_Width
/
2
;
dx
=
m_Start
.
x
-
point
.
x
;
dy
=
m_Start
.
y
-
point
.
y
;
if
(
min_dist
==
0
)
{
if
(
(
dx
==
0
)
&&
(
dy
==
0
)
)
result
|=
STARTPOINT
;
}
else
{
double
dist
=
((
double
)
dx
*
dx
)
+
((
double
)
dy
*
dy
);
dist
=
sqrt
(
dist
);
if
(
min_dist
>=
(
int
)
dist
)
result
|=
STARTPOINT
;
}
dx
=
m_End
.
x
-
point
.
x
;
dy
=
m_End
.
y
-
point
.
y
;
if
(
min_dist
==
0
)
{
if
(
(
dx
==
0
)
&&
(
dy
==
0
)
)
result
|=
ENDPOINT
;
}
else
{
double
dist
=
((
double
)
dx
*
dx
)
+
((
double
)
dy
*
dy
);
dist
=
sqrt
(
dist
);
if
(
min_dist
>=
(
int
)
dist
)
result
|=
ENDPOINT
;
}
return
result
;
int
dx
,
dy
;
int
result
=
0
;
if
(
min_dist
<
0
)
min_dist
=
m_Width
/
2
;
dx
=
m_Start
.
x
-
point
.
x
;
dy
=
m_Start
.
y
-
point
.
y
;
if
(
min_dist
==
0
)
{
if
(
(
dx
==
0
)
&&
(
dy
==
0
)
)
result
|=
STARTPOINT
;
}
else
{
double
dist
=
(
(
double
)
dx
*
dx
)
+
(
(
double
)
dy
*
dy
);
dist
=
sqrt
(
dist
);
if
(
min_dist
>=
(
int
)
dist
)
result
|=
STARTPOINT
;
}
dx
=
m_End
.
x
-
point
.
x
;
dy
=
m_End
.
y
-
point
.
y
;
if
(
min_dist
==
0
)
{
if
(
(
dx
==
0
)
&&
(
dy
==
0
)
)
result
|=
ENDPOINT
;
}
else
{
double
dist
=
(
(
double
)
dx
*
dx
)
+
(
(
double
)
dy
*
dy
);
dist
=
sqrt
(
dist
);
if
(
min_dist
>=
(
int
)
dist
)
result
|=
ENDPOINT
;
}
return
result
;
}
/******************************************/
bool
SEGVIA
::
IsViaOnLayer
(
int
layer_number
)
bool
SEGVIA
::
IsViaOnLayer
(
int
layer_number
)
/******************************************/
/* Retoune TRUE si Via sur layer layer_number
*/
*/
{
int
via_type
=
Shape
();
if
(
via_type
==
VIA_NORMALE
)
{
if
(
layer_number
<=
LAYER_CMP_N
)
return
TRUE
;
else
return
FALSE
;
}
// VIA_BORGNE ou VIA_ENTERREE:
int
bottom_layer
,
top_layer
;
ReturnLayerPair
(
&
top_layer
,
&
bottom_layer
);
if
(
(
bottom_layer
<=
layer_number
)
&&
(
top_layer
>=
layer_number
)
)
return
TRUE
;
else
return
FALSE
;
int
via_type
=
Shape
();
if
(
via_type
==
VIA_NORMALE
)
{
if
(
layer_number
<=
LAYER_CMP_N
)
return
TRUE
;
else
return
FALSE
;
}
// VIA_BORGNE ou VIA_ENTERREE:
int
bottom_layer
,
top_layer
;
ReturnLayerPair
(
&
top_layer
,
&
bottom_layer
);
if
(
(
bottom_layer
<=
layer_number
)
&&
(
top_layer
>=
layer_number
)
)
return
TRUE
;
else
return
FALSE
;
}
/***********************************/
int
TRACK
::
ReturnMaskLayer
(
void
)
int
TRACK
::
ReturnMaskLayer
(
void
)
/***********************************/
/* Retourne le masque (liste bit a bit ) des couches occupees par le segment
de piste pointe par PtSegm.
Si PtSegm pointe une via, il y a plusieurs couches occupees
*/
*
de piste pointe par PtSegm.
*
Si PtSegm pointe une via, il y a plusieurs couches occupees
*/
{
if
(
m_StructType
==
TYPEVIA
)
{
int
via_type
=
m_Shape
&
15
;
if
(
via_type
==
VIA_NORMALE
)
return
(
ALL_CU_LAYERS
);
// VIA_BORGNE ou VIA_ENTERREE:
int
bottom_layer
=
(
m_Layer
>>
4
)
&
15
;
int
top_layer
=
m_Layer
&
15
;
if
(
bottom_layer
>
top_layer
)
EXCHG
(
bottom_layer
,
top_layer
);
int
layermask
=
0
;
while
(
bottom_layer
<=
top_layer
)
{
layermask
|=
g_TabOneLayerMask
[
bottom_layer
++
];
}
return
(
layermask
);
}
else
return
(
g_TabOneLayerMask
[
m_Layer
]);
if
(
m_StructType
==
TYPEVIA
)
{
int
via_type
=
m_Shape
&
15
;
if
(
via_type
==
VIA_NORMALE
)
return
ALL_CU_LAYERS
;
// VIA_BORGNE ou VIA_ENTERREE:
int
bottom_layer
=
(
m_Layer
>>
4
)
&
15
;
int
top_layer
=
m_Layer
&
15
;
if
(
bottom_layer
>
top_layer
)
EXCHG
(
bottom_layer
,
top_layer
);
int
layermask
=
0
;
while
(
bottom_layer
<=
top_layer
)
{
layermask
|=
g_TabOneLayerMask
[
bottom_layer
++
];
}
return
layermask
;
}
else
return
g_TabOneLayerMask
[
m_Layer
];
}
/*********************************************************/
void
SEGVIA
::
SetLayerPair
(
int
top_layer
,
int
bottom_layer
)
void
SEGVIA
::
SetLayerPair
(
int
top_layer
,
int
bottom_layer
)
/*********************************************************/
/* Met a jour .m_Layer pour une via:
m_Layer code les 2 couches limitant la via
*/
*
m_Layer code les 2 couches limitant la via
*/
{
int
via_type
=
m_Shape
&
255
;
int
via_type
=
m_Shape
&
255
;
if
(
via_type
==
VIA_NORMALE
)
{
top_layer
=
LAYER_CMP_N
;
bottom_layer
=
LAYER_CUIVRE_N
;
}
if
(
via_type
==
VIA_NORMALE
)
{
top_layer
=
LAYER_CMP_N
;
bottom_layer
=
LAYER_CUIVRE_N
;
}
if
(
bottom_layer
>
top_layer
)
EXCHG
(
bottom_layer
,
top_layer
);
m_Layer
=
(
top_layer
&
15
)
+
(
(
bottom_layer
&
15
)
<<
4
);
if
(
bottom_layer
>
top_layer
)
EXCHG
(
bottom_layer
,
top_layer
);
m_Layer
=
(
top_layer
&
15
)
+
(
(
bottom_layer
&
15
)
<<
4
);
}
/***************************************************************/
void
SEGVIA
::
ReturnLayerPair
(
int
*
top_layer
,
int
*
bottom_layer
)
void
SEGVIA
::
ReturnLayerPair
(
int
*
top_layer
,
int
*
bottom_layer
)
/***************************************************************/
/* Retourne les 2 couches limitant la via
les pointeurs top_layer et bottom_layer peuvent etre NULLs
*/
*
les pointeurs top_layer et bottom_layer peuvent etre NULLs
*/
{
int
b_layer
=
(
m_Layer
>>
4
)
&
15
;
int
t_layer
=
m_Layer
&
15
;
if
(
b_layer
>
t_layer
)
EXCHG
(
b_layer
,
t_layer
);
if
(
top_layer
)
*
top_layer
=
t_layer
;
if
(
bottom_layer
)
*
bottom_layer
=
b_layer
;
int
b_layer
=
(
m_Layer
>>
4
)
&
15
;
int
t_layer
=
m_Layer
&
15
;
if
(
b_layer
>
t_layer
)
EXCHG
(
b_layer
,
t_layer
);
if
(
top_layer
)
*
top_layer
=
t_layer
;
if
(
bottom_layer
)
*
bottom_layer
=
b_layer
;
}
/************************/
TRACK
*
TRACK
::
Next
(
void
)
TRACK
*
TRACK
::
Next
(
void
)
/************************/
{
return
(
TRACK
*
)
Pnext
;
return
(
TRACK
*
)
Pnext
;
}
/* supprime du chainage la structure Struct
les structures arrieres et avant sont chainees directement
*
les structures arrieres et avant sont chainees directement
*/
void
TRACK
::
UnLink
(
void
)
{
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
if
(
GetState
(
DELETED
)
)
// A REVOIR car Pback = NULL si place en undelete
{
if
(
g_UnDeleteStack
)
g_UnDeleteStack
[
g_UnDeleteStackPtr
-
1
]
=
Pnext
;
}
else
{
if
(
m_StructType
==
TYPEZONE
)
{
((
BOARD
*
)
Pback
)
->
m_Zone
=
(
TRACK
*
)
Pnext
;
}
else
{
((
BOARD
*
)
Pback
)
->
m_Track
=
(
TRACK
*
)
Pnext
;
}
}
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
/* Modification du chainage arriere */
if
(
Pback
)
{
if
(
Pback
->
m_StructType
!=
TYPEPCB
)
{
Pback
->
Pnext
=
Pnext
;
}
else
/* Le chainage arriere pointe sur la structure "Pere" */
{
if
(
GetState
(
DELETED
)
)
// A REVOIR car Pback = NULL si place en undelete
{
if
(
g_UnDeleteStack
)
g_UnDeleteStack
[
g_UnDeleteStackPtr
-
1
]
=
Pnext
;
}
else
{
if
(
m_StructType
==
TYPEZONE
)
{
(
(
BOARD
*
)
Pback
)
->
m_Zone
=
(
TRACK
*
)
Pnext
;
}
else
{
(
(
BOARD
*
)
Pback
)
->
m_Track
=
(
TRACK
*
)
Pnext
;
}
}
}
}
/* Modification du chainage avant */
if
(
Pnext
)
Pnext
->
Pback
=
Pback
;
Pnext
=
Pback
=
NULL
;
}
/************************************************************/
void
TRACK
::
Insert
(
BOARD
*
Pcb
,
EDA_BaseStruct
*
InsertPoint
)
void
TRACK
::
Insert
(
BOARD
*
Pcb
,
EDA_BaseStruct
*
InsertPoint
)
/************************************************************/
/* Ajoute un element ou une liste a une liste de base
Si Insertpoint == NULL: insertion en debut de
liste Pcb->Track ou Pcb->Zone
Insertion a la suite de InsertPoint
Si InsertPoint == NULL, insertion en tete de liste
*/
*
Si Insertpoint == NULL: insertion en debut de
*
liste Pcb->Track ou Pcb->Zone
*
Insertion a la suite de InsertPoint
*
Si InsertPoint == NULL, insertion en tete de liste
*/
{
TRACK
*
track
,
*
NextS
;
/* Insertion du debut de la chaine a greffer */
if
(
InsertPoint
==
NULL
)
{
Pback
=
Pcb
;
if
(
m_StructType
==
TYPEZONE
)
{
NextS
=
Pcb
->
m_Zone
;
Pcb
->
m_Zone
=
this
;
}
else
{
NextS
=
Pcb
->
m_Track
;
Pcb
->
m_Track
=
this
;
}
}
else
{
NextS
=
(
TRACK
*
)
InsertPoint
->
Pnext
;
Pback
=
InsertPoint
;
InsertPoint
->
Pnext
=
this
;
}
/* Chainage de la fin de la liste a greffer */
track
=
this
;
while
(
track
->
Pnext
)
track
=
(
TRACK
*
)
track
->
Pnext
;
/* Track pointe la fin de la chaine a greffer */
track
->
Pnext
=
NextS
;
if
(
NextS
)
NextS
->
Pback
=
track
;
TRACK
*
track
,
*
NextS
;
/* Insertion du debut de la chaine a greffer */
if
(
InsertPoint
==
NULL
)
{
Pback
=
Pcb
;
if
(
m_StructType
==
TYPEZONE
)
{
NextS
=
Pcb
->
m_Zone
;
Pcb
->
m_Zone
=
this
;
}
else
{
NextS
=
Pcb
->
m_Track
;
Pcb
->
m_Track
=
this
;
}
}
else
{
NextS
=
(
TRACK
*
)
InsertPoint
->
Pnext
;
Pback
=
InsertPoint
;
InsertPoint
->
Pnext
=
this
;
}
/* Chainage de la fin de la liste a greffer */
track
=
this
;
while
(
track
->
Pnext
)
track
=
(
TRACK
*
)
track
->
Pnext
;
/* Track pointe la fin de la chaine a greffer */
track
->
Pnext
=
NextS
;
if
(
NextS
)
NextS
->
Pback
=
track
;
}
/***********************************************/
TRACK
*
TRACK
::
GetBestInsertPoint
(
BOARD
*
Pcb
)
TRACK
*
TRACK
::
GetBestInsertPoint
(
BOARD
*
Pcb
)
/***********************************************/
/* Recherche du meilleur point d'insertion pour le nouveau segment de piste
Retourne
un pointeur sur le segment de piste APRES lequel l'insertion
doit se faire ( dernier segment du net d'apartenance )
NULL si pas de piste ( liste vide );
*/
*
Retourne
*
un pointeur sur le segment de piste APRES lequel l'insertion
*
doit se faire ( dernier segment du net d'apartenance )
*
NULL si pas de piste ( liste vide );
*/
{
TRACK
*
track
,
*
NextTrack
;
if
(
m_StructType
==
TYPEZONE
)
track
=
Pcb
->
m_Zone
;
else
track
=
Pcb
->
m_Track
;
/* Traitement du debut de liste */
if
(
track
==
NULL
)
return
(
NULL
);
/* pas de piste ! */
if
(
m_NetCode
<
track
->
m_NetCode
)
/* insertion en tete de liste */
return
(
NULL
);
while
(
(
NextTrack
=
(
TRACK
*
)
track
->
Pnext
)
!=
NULL
)
{
if
(
NextTrack
->
m_NetCode
>
this
->
m_NetCode
)
break
;
track
=
NextTrack
;
}
return
(
track
);
TRACK
*
track
,
*
NextTrack
;
if
(
m_StructType
==
TYPEZONE
)
track
=
Pcb
->
m_Zone
;
else
track
=
Pcb
->
m_Track
;
/* Traitement du debut de liste */
if
(
track
==
NULL
)
return
NULL
;
/* pas de piste ! */
if
(
m_NetCode
<
track
->
m_NetCode
)
/* insertion en tete de liste */
return
NULL
;
while
(
(
NextTrack
=
(
TRACK
*
)
track
->
Pnext
)
!=
NULL
)
{
if
(
NextTrack
->
m_NetCode
>
this
->
m_NetCode
)
break
;
track
=
NextTrack
;
}
return
track
;
}
/* Recherche du debut du net
( les elements sont classes par net_code croissant )
la recherche se fait a partir de this
si net_code == -1 le netcode de this sera utilise
Retourne un pointeur sur le debut du net, ou NULL si net non trouve
*/
TRACK
*
TRACK
::
GetStartNetCode
(
int
NetCode
)
*
( les elements sont classes par net_code croissant )
*
la recherche se fait a partir de this
*
si net_code == -1 le netcode de this sera utilise
*
Retourne un pointeur sur le debut du net, ou NULL si net non trouve
*/
TRACK
*
TRACK
::
GetStartNetCode
(
int
NetCode
)
{
TRACK
*
Track
=
this
;
int
ii
=
0
;
if
(
NetCode
==
-
1
)
NetCode
=
m_NetCode
;
while
(
Track
!=
NULL
)
{
if
(
Track
->
m_NetCode
>
NetCode
)
break
;
if
(
Track
->
m_NetCode
==
NetCode
)
{
ii
++
;
break
;
}
Track
=
(
TRACK
*
)
Track
->
Pnext
;
}
if
(
ii
)
return
(
Track
);
else
return
(
NULL
);
TRACK
*
Track
=
this
;
int
ii
=
0
;
if
(
NetCode
==
-
1
)
NetCode
=
m_NetCode
;
while
(
Track
!=
NULL
)
{
if
(
Track
->
m_NetCode
>
NetCode
)
break
;
if
(
Track
->
m_NetCode
==
NetCode
)
{
ii
++
;
break
;
}
Track
=
(
TRACK
*
)
Track
->
Pnext
;
}
if
(
ii
)
return
Track
;
else
return
NULL
;
}
/* Recherche de la fin du net
Retourne un pointeur sur la fin du net, ou NULL si net non trouve
*/
TRACK
*
TRACK
::
GetEndNetCode
(
int
NetCode
)
*
Retourne un pointeur sur la fin du net, ou NULL si net non trouve
*/
TRACK
*
TRACK
::
GetEndNetCode
(
int
NetCode
)
{
TRACK
*
NextS
,
*
Track
=
this
;
int
ii
=
0
;
if
(
Track
==
NULL
)
return
(
NULL
);
if
(
NetCode
==
-
1
)
NetCode
=
m_NetCode
;
while
(
Track
!=
NULL
)
{
NextS
=
(
TRACK
*
)
Track
->
Pnext
;
if
(
Track
->
m_NetCode
==
NetCode
)
ii
++
;
if
(
NextS
==
NULL
)
break
;
if
(
NextS
->
m_NetCode
>
NetCode
)
break
;
Track
=
NextS
;
}
if
(
ii
)
return
(
Track
);
else
return
(
NULL
);
TRACK
*
NextS
,
*
Track
=
this
;
int
ii
=
0
;
if
(
Track
==
NULL
)
return
NULL
;
if
(
NetCode
==
-
1
)
NetCode
=
m_NetCode
;
while
(
Track
!=
NULL
)
{
NextS
=
(
TRACK
*
)
Track
->
Pnext
;
if
(
Track
->
m_NetCode
==
NetCode
)
ii
++
;
if
(
NextS
==
NULL
)
break
;
if
(
NextS
->
m_NetCode
>
NetCode
)
break
;
Track
=
NextS
;
}
if
(
ii
)
return
Track
;
else
return
NULL
;
}
/**********************************/
TRACK
*
TRACK
::
Copy
(
int
NbSegm
)
TRACK
*
TRACK
::
Copy
(
int
NbSegm
)
/**********************************/
/* Copie d'un Element ou d'une chaine de n elements
Retourne un pointeur sur le nouvel element ou le debut de la
nouvelle chaine
*/
*
Retourne un pointeur sur le nouvel element ou le debut de la
*
nouvelle chaine
*/
{
TRACK
*
NewTrack
,
*
FirstTrack
,
*
OldTrack
,
*
Source
=
this
;
int
ii
;
FirstTrack
=
NewTrack
=
new
TRACK
(
*
Source
);
for
(
ii
=
1
;
ii
<
NbSegm
;
ii
++
)
{
Source
=
Source
->
Next
();
if
(
Source
==
NULL
)
break
;
OldTrack
=
NewTrack
;
NewTrack
=
new
TRACK
(
*
Source
);
NewTrack
->
Insert
(
NULL
,
OldTrack
);
}
return
(
FirstTrack
);
TRACK
*
NewTrack
,
*
FirstTrack
,
*
OldTrack
,
*
Source
=
this
;
int
ii
;
FirstTrack
=
NewTrack
=
new
TRACK
(
*
Source
);
for
(
ii
=
1
;
ii
<
NbSegm
;
ii
++
)
{
Source
=
Source
->
Next
();
if
(
Source
==
NULL
)
break
;
OldTrack
=
NewTrack
;
NewTrack
=
new
TRACK
(
*
Source
);
NewTrack
->
Insert
(
NULL
,
OldTrack
);
}
return
FirstTrack
;
}
/********************************************/
bool
TRACK
::
WriteTrackDescr
(
FILE
*
File
)
bool
TRACK
::
WriteTrackDescr
(
FILE
*
File
)
/********************************************/
{
int
type
;
int
type
;
type
=
0
;
if
(
m_StructType
==
TYPEVIA
)
type
=
1
;
type
=
0
;
if
(
m_StructType
==
TYPEVIA
)
type
=
1
;
if
(
GetState
(
DELETED
)
)
return
FALSE
;
if
(
GetState
(
DELETED
)
)
return
FALSE
;
fprintf
(
File
,
"Po %d %d %d %d %d %d %d
\n
"
,
m_Shape
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
m_Drill
);
fprintf
(
File
,
"Po %d %d %d %d %d %d %d
\n
"
,
m_Shape
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
m_Drill
);
fprintf
(
File
,
"De %d %d %d %lX %X
\n
"
,
m_Layer
,
type
,
m_NetCode
,
m_TimeStamp
,
ReturnStatus
()
);
return
TRUE
;
fprintf
(
File
,
"De %d %d %d %lX %X
\n
"
,
m_Layer
,
type
,
m_NetCode
,
m_TimeStamp
,
ReturnStatus
()
);
return
TRUE
;
}
/**********************************************************************/
void
TRACK
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
int
draw_mode
)
void
TRACK
::
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
int
draw_mode
)
/*********************************************************************/
/* routine de trace de 1 segment de piste.
Parametres :
draw_mode = mode ( GR_XOR, GR_OR..)
*/
/* routine de trace de 1 segment de piste.
* Parametres :
* draw_mode = mode ( GR_XOR, GR_OR..)
*/
{
int
l_piste
;
int
color
;
int
zoom
;
int
rayon
;
int
curr_layer
=
((
PCB_SCREEN
*
)
panel
->
GetScreen
())
->
m_Active_Layer
;
if
(
m_StructType
==
TYPEZONE
&&
(
!
DisplayOpt
.
DisplayZones
)
)
return
;
GRSetDrawMode
(
DC
,
draw_mode
);
if
(
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
color
=
g_DesignSettings
.
m_ViaColor
[
m_Shape
];
else
color
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
color
&
(
ITEM_NOT_SHOW
|
HIGHT_LIGHT_FLAG
))
==
ITEM_NOT_SHOW
)
return
;
if
(
DisplayOpt
.
ContrastModeDisplay
)
{
if
(
m_StructType
==
TYPEVIA
)
{
if
(
!
((
SEGVIA
*
)
this
)
->
IsViaOnLayer
(
curr_layer
)
)
{
color
&=
~
MASKCOLOR
;
color
|=
DARKDARKGRAY
;
}
}
else
if
(
m_Layer
!=
curr_layer
)
{
color
&=
~
MASKCOLOR
;
color
|=
DARKDARKGRAY
;
}
}
if
(
draw_mode
&
GR_SURBRILL
)
{
if
(
draw_mode
&
GR_AND
)
color
&=
~
HIGHT_LIGHT_FLAG
;
else
color
|=
HIGHT_LIGHT_FLAG
;
}
if
(
color
&
HIGHT_LIGHT_FLAG
)
color
=
ColorRefs
[
color
&
MASKCOLOR
].
m_LightColor
;
zoom
=
panel
->
GetZoom
();
l_piste
=
m_Width
>>
1
;
if
(
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
{
rayon
=
l_piste
;
if
(
rayon
<
zoom
)
rayon
=
zoom
;
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
)
;
if
(
rayon
>
(
4
*
zoom
)
)
{
int
drill_rayon
,
inner_rayon
=
rayon
-
(
2
*
zoom
);
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
inner_rayon
,
color
);
// Draw the via hole if the display option request it
if
(
DisplayOpt
.
m_DisplayViaMode
!=
VIA_HOLE_NOT_SHOW
)
{
if
(
(
DisplayOpt
.
m_DisplayViaMode
==
ALL_VIA_HOLE_SHOW
)
||
(
m_Drill
>
0
)
)
{
if
(
m_Drill
>
0
)
drill_rayon
=
m_Drill
/
2
;
else
drill_rayon
=
g_DesignSettings
.
m_ViaDrill
/
2
;
if
(
drill_rayon
<
inner_rayon
)
// We can show the via hole
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
drill_rayon
,
color
);
}
}
}
if
(
DisplayOpt
.
DisplayTrackIsol
)
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
+
g_DesignSettings
.
m_TrackClearence
,
color
);
}
return
;
}
if
(
m_Shape
==
S_CIRCLE
)
{
rayon
=
(
int
)
hypot
((
double
)(
m_End
.
x
-
m_Start
.
x
),
(
double
)(
m_End
.
y
-
m_Start
.
y
)
);
if
(
(
l_piste
/
zoom
)
<
L_MIN_DESSIN
)
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
)
;
}
else
{
if
(
l_piste
<=
zoom
)
/* trace simplifie si l_piste/zoom <= 1 */
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
);
}
else
if
(
(
!
DisplayOpt
.
DisplayPcbTrackFill
)
||
GetState
(
FORCE_SKETCH
))
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
-
l_piste
,
color
);
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
+
l_piste
,
color
);
}
else
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
m_Width
,
color
);
}
}
return
;
}
if
(
(
l_piste
/
zoom
)
<
L_MIN_DESSIN
)
{
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
0
,
color
);
return
;
}
if
(
(
!
DisplayOpt
.
DisplayPcbTrackFill
)
||
GetState
(
FORCE_SKETCH
)
)
{
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
color
)
;
}
else
{
GRFillCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
color
)
;
}
/* Trace de l'isolation (pour segments type CUIVRE et TRACK uniquement */
if
(
(
DisplayOpt
.
DisplayTrackIsol
)
&&
(
m_Layer
<=
CMP_N
)
&&
(
m_StructType
==
TYPETRACK
)
)
{
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
+
(
g_DesignSettings
.
m_TrackClearence
*
2
),
color
)
;
}
int
l_piste
;
int
color
;
int
zoom
;
int
rayon
;
int
curr_layer
=
(
(
PCB_SCREEN
*
)
panel
->
GetScreen
()
)
->
m_Active_Layer
;
if
(
m_StructType
==
TYPEZONE
&&
(
!
DisplayOpt
.
DisplayZones
)
)
return
;
GRSetDrawMode
(
DC
,
draw_mode
);
if
(
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
color
=
g_DesignSettings
.
m_ViaColor
[
m_Shape
];
else
color
=
g_DesignSettings
.
m_LayerColor
[
m_Layer
];
if
(
(
color
&
(
ITEM_NOT_SHOW
|
HIGHT_LIGHT_FLAG
)
)
==
ITEM_NOT_SHOW
)
return
;
if
(
DisplayOpt
.
ContrastModeDisplay
)
{
if
(
m_StructType
==
TYPEVIA
)
{
if
(
!
(
(
SEGVIA
*
)
this
)
->
IsViaOnLayer
(
curr_layer
)
)
{
color
&=
~
MASKCOLOR
;
color
|=
DARKDARKGRAY
;
}
}
else
if
(
m_Layer
!=
curr_layer
)
{
color
&=
~
MASKCOLOR
;
color
|=
DARKDARKGRAY
;
}
}
if
(
draw_mode
&
GR_SURBRILL
)
{
if
(
draw_mode
&
GR_AND
)
color
&=
~
HIGHT_LIGHT_FLAG
;
else
color
|=
HIGHT_LIGHT_FLAG
;
}
if
(
color
&
HIGHT_LIGHT_FLAG
)
color
=
ColorRefs
[
color
&
MASKCOLOR
].
m_LightColor
;
zoom
=
panel
->
GetZoom
();
l_piste
=
m_Width
>>
1
;
if
(
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
{
rayon
=
l_piste
;
if
(
rayon
<
zoom
)
rayon
=
zoom
;
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
);
if
(
rayon
>
(
4
*
zoom
)
)
{
int
drill_rayon
,
inner_rayon
=
rayon
-
(
2
*
zoom
);
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
inner_rayon
,
color
);
// Draw the via hole if the display option request it
if
(
DisplayOpt
.
m_DisplayViaMode
!=
VIA_HOLE_NOT_SHOW
)
{
if
(
(
DisplayOpt
.
m_DisplayViaMode
==
ALL_VIA_HOLE_SHOW
)
||
(
m_Drill
>
0
)
)
{
if
(
m_Drill
>
0
)
drill_rayon
=
m_Drill
/
2
;
else
drill_rayon
=
g_DesignSettings
.
m_ViaDrill
/
2
;
if
(
drill_rayon
<
inner_rayon
)
// We can show the via hole
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
drill_rayon
,
color
);
}
}
}
if
(
DisplayOpt
.
DisplayTrackIsol
)
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
+
g_DesignSettings
.
m_TrackClearence
,
color
);
}
return
;
}
if
(
m_Shape
==
S_CIRCLE
)
{
rayon
=
(
int
)
hypot
(
(
double
)
(
m_End
.
x
-
m_Start
.
x
),
(
double
)
(
m_End
.
y
-
m_Start
.
y
)
);
if
(
(
l_piste
/
zoom
)
<
L_MIN_DESSIN
)
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
);
}
else
{
if
(
l_piste
<=
zoom
)
/* trace simplifie si l_piste/zoom <= 1 */
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
color
);
}
else
if
(
(
!
DisplayOpt
.
DisplayPcbTrackFill
)
||
GetState
(
FORCE_SKETCH
)
)
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
-
l_piste
,
color
);
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
+
l_piste
,
color
);
}
else
{
GRCircle
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
rayon
,
m_Width
,
color
);
}
}
return
;
}
if
(
(
l_piste
/
zoom
)
<
L_MIN_DESSIN
)
{
GRLine
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
0
,
color
);
return
;
}
if
(
(
!
DisplayOpt
.
DisplayPcbTrackFill
)
||
GetState
(
FORCE_SKETCH
)
)
{
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
color
);
}
else
{
GRFillCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
,
color
);
}
/* Trace de l'isolation (pour segments type CUIVRE et TRACK uniquement */
if
(
(
DisplayOpt
.
DisplayTrackIsol
)
&&
(
m_Layer
<=
CMP_N
)
&&
(
m_StructType
==
TYPETRACK
)
)
{
GRCSegm
(
&
panel
->
m_ClipBox
,
DC
,
m_Start
.
x
,
m_Start
.
y
,
m_End
.
x
,
m_End
.
y
,
m_Width
+
(
g_DesignSettings
.
m_TrackClearence
*
2
),
color
);
}
}
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param ref_pos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
TRACK
::
HitTest
(
const
wxPoint
&
ref_pos
)
{
int
l_piste
;
/* demi-largeur de la piste */
int
dx
,
dy
,
spot_cX
,
spot_cY
;
int
ux0
,
uy0
;
/* calcul des coordonnees du segment teste */
l_piste
=
m_Width
>>
1
;
/* l_piste = demi largeur piste */
ux0
=
m_Start
.
x
;
uy0
=
m_Start
.
y
;
/* coord de depart */
dx
=
m_End
.
x
;
dy
=
m_End
.
y
;
/* coord d'arrivee */
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
-=
ux0
;
dy
-=
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
{
if
(
(
abs
(
spot_cX
)
<=
l_piste
)
&&
(
abs
(
spot_cY
)
<=
l_piste
)
)
return
true
;
else
return
false
;
}
else
{
if
(
DistanceTest
(
l_piste
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
}
return
false
;
}
pcbnew/class_track.h
View file @
c1e3416a
...
...
@@ -10,84 +10,135 @@
/* Type des Vias (shape)*/
/* Forme des Vias ( parametre .shape ) */
#define VIA_NORMALE
3
/* type via : traversante (throught via) */
#define VIA_ENTERREE
2
/* type via : enterree ou aveugle (blind via) */
#define VIA_BORGNE
1
/* type via : borgne ou demi-traversante (buried via) */
#define VIA_NOT_DEFINED 0
/* reserved */
#define SQUARE_VIA
0x80000000
/* Flag pour forme carree */
#define VIA_NORMALE
3
/* type via : traversante (throught via) */
#define VIA_ENTERREE
2
/* type via : enterree ou aveugle (blind via) */
#define VIA_BORGNE
1
/* type via : borgne ou demi-traversante (buried via) */
#define VIA_NOT_DEFINED 0
/* reserved */
#define SQUARE_VIA
0x80000000
/* Flag pour forme carree */
/***/
class
TRACK
:
public
EDA_BaseLineStruct
class
TRACK
:
public
EDA_BaseLineStruct
{
public
:
int
m_Shape
;
// vias: shape and type, Track = shape..
int
m_Drill
;
// for vias: via drill (- 1 for default value)
EDA_BaseStruct
*
start
,
*
end
;
// pointers on a connected item (pad or track)
int
m_NetCode
;
// Net number
int
m_Sous_Netcode
;
/* In rastnest routines : for the current net,
block number (number common to the current connected items found) */
// chain = 0 indique une connexion non encore traitee
int
m_Param
;
// Auxiliary variable ( used in some computations )
int
m_Shape
;
// vias: shape and type, Track = shape..
int
m_Drill
;
// for vias: via drill (- 1 for default value)
EDA_BaseStruct
*
start
,
*
end
;
// pointers on a connected item (pad or track)
int
m_NetCode
;
// Net number
int
m_Sous_Netcode
;
/* In rastnest routines : for the current net,
* block number (number common to the current connected items found) */
public
:
TRACK
(
EDA_BaseStruct
*
StructFather
,
DrawStructureType
idtype
=
TYPETRACK
);
TRACK
(
const
TRACK
&
track
);
TRACK
*
Next
(
void
);
// Retourne le chainage avant
TRACK
*
Back
(
void
)
// Retourne le chainage avant
{
return
(
TRACK
*
)
Pback
;
}
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
// Read/write data
bool
WriteTrackDescr
(
FILE
*
File
);
/* Ajoute un element a la liste */
void
Insert
(
BOARD
*
Pcb
,
EDA_BaseStruct
*
InsertPoint
);
/* Recherche du meilleur point d'insertion */
TRACK
*
GetBestInsertPoint
(
BOARD
*
Pcb
);
// chain = 0 indique une connexion non encore traitee
int
m_Param
;
// Auxiliary variable ( used in some computations )
/* Copie d'un Element d'une chaine de n elements */
TRACK
*
Copy
(
int
NbSegm
=
1
);
/* Recherche du debut du net
( les elements sont classes par net_code croissant ) */
TRACK
*
GetStartNetCode
(
int
NetCode
);
/* Recherche de la fin du net */
TRACK
*
GetEndNetCode
(
int
NetCode
);
/* Display on screen: */
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
int
draw_mode
);
/* divers */
int
Shape
(
void
)
{
return
m_Shape
&
0xFF
;
}
int
ReturnMaskLayer
(
void
);
int
IsPointOnEnds
(
const
wxPoint
&
point
,
int
min_dist
=
0
);
bool
IsNull
(
void
);
// return TRUE if segment lenght = 0
public
:
TRACK
(
EDA_BaseStruct
*
StructFather
,
DrawStructureType
idtype
=
TYPETRACK
);
TRACK
(
const
TRACK
&
track
);
TRACK
*
Next
(
void
);
// Retourne le chainage avant
TRACK
*
Back
(
void
)
// Retourne le chainage avant
{
return
(
TRACK
*
)
Pback
;
}
/* supprime du chainage la structure Struct */
void
UnLink
(
void
);
// Read/write data
bool
WriteTrackDescr
(
FILE
*
File
);
/* Ajoute un element a la liste */
void
Insert
(
BOARD
*
Pcb
,
EDA_BaseStruct
*
InsertPoint
);
/* Recherche du meilleur point d'insertion */
TRACK
*
GetBestInsertPoint
(
BOARD
*
Pcb
);
/* Copie d'un Element d'une chaine de n elements */
TRACK
*
Copy
(
int
NbSegm
=
1
);
/* Recherche du debut du net
* ( les elements sont classes par net_code croissant ) */
TRACK
*
GetStartNetCode
(
int
NetCode
);
/* Recherche de la fin du net */
TRACK
*
GetEndNetCode
(
int
NetCode
);
/* Display on screen: */
void
Draw
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
int
draw_mode
);
/* divers */
int
Shape
(
void
)
{
return
m_Shape
&
0xFF
;
}
int
ReturnMaskLayer
(
void
);
int
IsPointOnEnds
(
const
wxPoint
&
point
,
int
min_dist
=
0
);
bool
IsNull
(
void
);
// return TRUE if segment lenght = 0
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param refPos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
HitTest
(
const
wxPoint
&
refPos
);
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
* @return wxString
*/
wxString
GetClass
()
const
{
return
wxT
(
"TRACK"
);
}
#endif
};
class
SEGZONE
:
public
TRACK
class
SEGZONE
:
public
TRACK
{
public
:
SEGZONE
(
EDA_BaseStruct
*
StructFather
);
SEGZONE
(
EDA_BaseStruct
*
StructFather
);
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
* @return wxString
*/
wxString
GetClass
()
const
{
return
wxT
(
"ZONE"
);
}
#endif
};
class
SEGVIA
:
public
TRACK
class
SEGVIA
:
public
TRACK
{
public
:
SEGVIA
(
EDA_BaseStruct
*
StructFather
);
bool
IsViaOnLayer
(
int
layer
);
void
SetLayerPair
(
int
top_layer
,
int
bottom_layer
);
void
ReturnLayerPair
(
int
*
top_layer
,
int
*
bottom_layer
);
SEGVIA
(
EDA_BaseStruct
*
StructFather
);
bool
IsViaOnLayer
(
int
layer
);
void
SetLayerPair
(
int
top_layer
,
int
bottom_layer
);
void
ReturnLayerPair
(
int
*
top_layer
,
int
*
bottom_layer
);
#if defined(DEBUG)
/**
* Function GetClass
* returns the class name.
* @return wxString
*/
wxString
GetClass
()
const
{
return
wxT
(
"VIA"
);
}
#endif
};
#endif
/* CLASS_TRACK_H */
pcbnew/classpcb.cpp
View file @
c1e3416a
...
...
@@ -16,6 +16,7 @@
#endif
#include "protos.h"
#include "trigo.h"
/**************************************************************/
...
...
@@ -165,6 +166,61 @@ bool DRAWSEGMENT::ReadDrawSegmentDescr( FILE* File, int* LineNum )
}
/**
* Function HitTest
* tests if the given wxPoint is within the bounds of this object.
* @param ref_pos A wxPoint to test
* @return bool - true if a hit, else false
*/
bool
DRAWSEGMENT
::
HitTest
(
const
wxPoint
&
ref_pos
)
{
int
ux0
=
m_Start
.
x
;
int
uy0
=
m_Start
.
y
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
int
dx
=
m_End
.
x
-
ux0
;
int
dy
=
m_End
.
y
-
uy0
;
int
spot_cX
=
ref_pos
.
x
-
ux0
;
int
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
m_Shape
==
S_CIRCLE
||
m_Shape
==
S_ARC
)
{
int
rayon
,
dist
,
stAngle
,
endAngle
,
mouseAngle
;
rayon
=
(
int
)
hypot
(
(
double
)
(
dx
),
(
double
)
(
dy
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
spot_cX
),
(
double
)
(
spot_cY
)
);
if
(
abs
(
rayon
-
dist
)
<=
(
m_Width
/
2
)
)
{
if
(
m_Shape
==
S_CIRCLE
)
return
true
;
/* pour un arc, controle complementaire */
mouseAngle
=
(
int
)
ArcTangente
(
spot_cY
,
spot_cX
);
stAngle
=
(
int
)
ArcTangente
(
dy
,
dx
);
endAngle
=
stAngle
+
m_Angle
;
if
(
endAngle
>
3600
)
{
stAngle
-=
3600
;
endAngle
-=
3600
;
}
if
(
mouseAngle
>=
stAngle
&&
mouseAngle
<=
endAngle
)
return
true
;
}
}
else
{
if
(
DistanceTest
(
m_Width
/
2
,
dx
,
dy
,
spot_cX
,
spot_cY
)
)
return
true
;
}
return
false
;
}
/*******************/
/* Classe MARQUEUR */
/*******************/
...
...
pcbnew/drc.cpp
View file @
c1e3416a
/****************************/
/* DRC control */
/****************************/
/****************************/
/* DRC control */
/****************************/
#include "fctsys.h"
#include "gr_basic.h"
...
...
@@ -14,1345 +14,1542 @@
/* variables locales */
class
WinEDA_DrcFrame
;
WinEDA_DrcFrame
*
DrcFrame
;
WinEDA_DrcFrame
*
DrcFrame
;
/* saving drc options */
static
bool
s_Pad2PadTestOpt
=
true
;
static
bool
s_UnconnectedTestOpt
=
true
;
static
bool
s_ZonesTestOpt
=
false
;
static
bool
s_CreateRptFileOpt
=
false
;
static
FILE
*
s_RptFile
=
NULL
;
static
wxString
s_RptFilename
;
static
int
ErrorsDRC_Count
;
static
MARQUEUR
*
current_marqueur
;
/* Pour gestion des marqueurs sur pcb */
static
bool
AbortDrc
,
DrcInProgress
=
FALSE
;
static
int
spot_cX
,
spot_cY
;
/* position d'elements a tester */
static
int
finx
,
finy
;
// coord relatives de l'extremite du segm de reference
static
int
segm_angle
;
// angle d'inclinaison du segment de reference en 0,1 degre
static
int
segm_long
;
// longueur du segment de reference
static
int
xcliplo
,
ycliplo
,
xcliphi
,
ycliphi
;
/* coord de la surface de securite du segment a comparer */
static
bool
s_Pad2PadTestOpt
=
true
;
static
bool
s_UnconnectedTestOpt
=
true
;
static
bool
s_ZonesTestOpt
=
false
;
static
bool
s_CreateRptFileOpt
=
false
;
static
FILE
*
s_RptFile
=
NULL
;
static
wxString
s_RptFilename
;
static
int
ErrorsDRC_Count
;
static
MARQUEUR
*
current_marqueur
;
/* Pour gestion des marqueurs sur pcb */
static
bool
AbortDrc
,
DrcInProgress
=
FALSE
;
static
int
spot_cX
,
spot_cY
;
/* position d'elements a tester */
static
int
finx
,
finy
;
// coord relatives de l'extremite du segm de reference
static
int
segm_angle
;
// angle d'inclinaison du segment de reference en 0,1 degre
static
int
segm_long
;
// longueur du segment de reference
static
int
xcliplo
,
ycliplo
,
xcliphi
,
ycliphi
;
/* coord de la surface de securite du segment a comparer */
/* Routines Locales */
static
int
Pad_to_Pad_Isol
(
D_PAD
*
pad_ref
,
D_PAD
*
pad
,
const
int
dist_min
);
static
bool
Test_Pad_to_Pads_Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
D_PAD
*
pad_ref
,
LISTE_PAD
*
start_buffer
,
LISTE_PAD
*
end_buffer
,
int
max_size
,
bool
show_err
);
static
int
TestClearanceSegmToPad
(
const
D_PAD
*
pad_to_test
,
int
seg_width
,
int
isol
);
static
int
TestMarginToCircle
(
int
cx
,
int
cy
,
int
rayon
,
int
longueur
);
static
int
Tst_Ligne
(
int
x1
,
int
y1
,
int
x2
,
int
y2
);
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
TRACK
*
pt_ref
,
void
*
pt_item
,
int
errnumber
);
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
D_PAD
*
pad1
,
D_PAD
*
pad2
);
/*******************************************/
/* Frame d'option et execution DRC general */
/*******************************************/
static
int
Pad_to_Pad_Isol
(
D_PAD
*
pad_ref
,
D_PAD
*
pad
,
const
int
dist_min
);
static
bool
Test_Pad_to_Pads_Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
D_PAD
*
pad_ref
,
LISTE_PAD
*
start_buffer
,
LISTE_PAD
*
end_buffer
,
int
max_size
,
bool
show_err
);
static
int
TestClearanceSegmToPad
(
const
D_PAD
*
pad_to_test
,
int
seg_width
,
int
isol
);
static
int
TestMarginToCircle
(
int
cx
,
int
cy
,
int
rayon
,
int
longueur
);
static
int
Tst_Ligne
(
int
x1
,
int
y1
,
int
x2
,
int
y2
);
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
TRACK
*
pt_ref
,
void
*
pt_item
,
int
errnumber
);
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
D_PAD
*
pad1
,
D_PAD
*
pad2
);
/*******************************************/
/* Frame d'option et execution DRC general */
/*******************************************/
#include "dialog_drc.cpp"
/***************************************************************/
void
WinEDA_DrcFrame
::
ListUnconnectedPads
(
wxCommandEvent
&
event
)
void
WinEDA_DrcFrame
::
ListUnconnectedPads
(
wxCommandEvent
&
event
)
/***************************************************************/
{
if
(
(
m_Parent
->
m_Pcb
->
m_Status_Pcb
&
LISTE_CHEVELU_OK
)
==
0
)
{
m_Parent
->
Compile_Ratsnest
(
m_DC
,
TRUE
);
}
if
(
m_Parent
->
m_Pcb
->
m_Ratsnest
==
NULL
)
return
;
CHEVELU
*
Ratsnest
=
m_Parent
->
m_Pcb
->
m_Ratsnest
;
int
draw_mode
=
GR_SURBRILL
|
GR_OR
;
WinEDA_DrawPanel
*
panel
=
m_Parent
->
DrawPanel
;
int
ii
;
wxString
msg
;
float
convert
=
0.0001
;
msg
=
_
(
"Look for active routes
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
m_UnconnectedCount
=
0
;
for
(
ii
=
m_Parent
->
m_Pcb
->
GetNumRatsnests
()
;
ii
>
0
;
Ratsnest
++
,
ii
--
)
{
if
(
(
Ratsnest
->
status
&
CH_ACTIF
)
==
0
)
continue
;
m_UnconnectedCount
++
;
if
(
m_UnconnectedCount
==
1
)
m_logWindow
->
AppendText
(
_
(
"Unconnected found:
\n
"
)
);
D_PAD
*
pad
=
Ratsnest
->
pad_start
;
pad
->
Draw
(
panel
,
m_DC
,
wxPoint
(
0
,
0
),
draw_mode
);
wxString
pad_name
=
pad
->
ReturnStringPadName
();
wxString
module_name
=
((
MODULE
*
)(
pad
->
m_Parent
))
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"%d > Pad %s (%s) @ %.4f,%.4f and "
),
m_UnconnectedCount
,
pad_name
.
GetData
(),
module_name
.
GetData
(),
pad
->
m_Pos
.
x
*
convert
,
pad
->
m_Pos
.
y
*
convert
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
pad
=
Ratsnest
->
pad_end
;
pad
->
Draw
(
panel
,
m_DC
,
wxPoint
(
0
,
0
),
draw_mode
);
pad_name
=
pad
->
ReturnStringPadName
();
module_name
=
((
MODULE
*
)(
pad
->
m_Parent
))
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"Pad %s (%s) @ %.4f,%.4f
\n
"
),
pad_name
.
GetData
(),
module_name
.
GetData
(),
pad
->
m_Pos
.
x
*
convert
,
pad
->
m_Pos
.
y
*
convert
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
}
if
(
m_UnconnectedCount
)
msg
.
Printf
(
_
(
"Active routes: %d
\n
"
),
m_UnconnectedCount
);
else
msg
=
_
(
"OK! (No active routes)
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
(
m_Parent
->
m_Pcb
->
m_Status_Pcb
&
LISTE_CHEVELU_OK
)
==
0
)
{
m_Parent
->
Compile_Ratsnest
(
m_DC
,
TRUE
);
}
if
(
m_Parent
->
m_Pcb
->
m_Ratsnest
==
NULL
)
return
;
CHEVELU
*
Ratsnest
=
m_Parent
->
m_Pcb
->
m_Ratsnest
;
int
draw_mode
=
GR_SURBRILL
|
GR_OR
;
WinEDA_DrawPanel
*
panel
=
m_Parent
->
DrawPanel
;
int
ii
;
wxString
msg
;
float
convert
=
0.0001
;
msg
=
_
(
"Look for active routes
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
m_UnconnectedCount
=
0
;
for
(
ii
=
m_Parent
->
m_Pcb
->
GetNumRatsnests
();
ii
>
0
;
Ratsnest
++
,
ii
--
)
{
if
(
(
Ratsnest
->
status
&
CH_ACTIF
)
==
0
)
continue
;
m_UnconnectedCount
++
;
if
(
m_UnconnectedCount
==
1
)
m_logWindow
->
AppendText
(
_
(
"Unconnected found:
\n
"
)
);
D_PAD
*
pad
=
Ratsnest
->
pad_start
;
pad
->
Draw
(
panel
,
m_DC
,
wxPoint
(
0
,
0
),
draw_mode
);
wxString
pad_name
=
pad
->
ReturnStringPadName
();
wxString
module_name
=
(
(
MODULE
*
)
(
pad
->
m_Parent
)
)
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"%d > Pad %s (%s) @ %.4f,%.4f and "
),
m_UnconnectedCount
,
pad_name
.
GetData
(),
module_name
.
GetData
(
),
pad
->
m_Pos
.
x
*
convert
,
pad
->
m_Pos
.
y
*
convert
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
pad
=
Ratsnest
->
pad_end
;
pad
->
Draw
(
panel
,
m_DC
,
wxPoint
(
0
,
0
),
draw_mode
);
pad_name
=
pad
->
ReturnStringPadName
();
module_name
=
(
(
MODULE
*
)
(
pad
->
m_Parent
)
)
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"Pad %s (%s) @ %.4f,%.4f
\n
"
),
pad_name
.
GetData
(),
module_name
.
GetData
(
),
pad
->
m_Pos
.
x
*
convert
,
pad
->
m_Pos
.
y
*
convert
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
}
if
(
m_UnconnectedCount
)
msg
.
Printf
(
_
(
"Active routes: %d
\n
"
),
m_UnconnectedCount
);
else
msg
=
_
(
"OK! (No active routes)
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
}
/****************************************************/
void
WinEDA_DrcFrame
::
TestDrc
(
wxCommandEvent
&
event
)
void
WinEDA_DrcFrame
::
TestDrc
(
wxCommandEvent
&
event
)
/****************************************************/
{
int
errors
;
wxString
msg
;
if
(
!
DrcInProgress
)
{
if
(
m_CreateRptCtrl
->
IsChecked
()
)
// Create a file rpt
{
s_RptFilename
=
m_RptFilenameCtrl
->
GetValue
();
if
(
s_RptFilename
.
IsEmpty
()
)
OnButtonBrowseRptFileClick
(
event
);
if
(
!
s_RptFilename
.
IsEmpty
()
)
s_RptFile
=
wxFopen
(
s_RptFilename
,
wxT
(
"w"
));
else
s_RptFile
=
NULL
;
}
if
(
s_RptFile
)
{
fprintf
(
s_RptFile
,
"Drc report for %s
\n
"
,
CONV_TO_UTF8
(
m_Parent
->
m_CurrentScreen
->
m_FileName
)
);
char
line
[
256
];
fprintf
(
s_RptFile
,
"Created on %s
\n
"
,
DateAndTime
(
line
));
}
s_Pad2PadTestOpt
=
m_Pad2PadTestCtrl
->
IsChecked
();
s_UnconnectedTestOpt
=
m_UnconnectedTestCtrl
->
IsChecked
();
s_ZonesTestOpt
=
m_ZonesTestCtrl
->
IsChecked
();
AbortDrc
=
FALSE
;
m_logWindow
->
Clear
();
g_DesignSettings
.
m_TrackClearence
=
ReturnValueFromTextCtrl
(
*
m_SetClearance
,
m_Parent
->
m_InternalUnits
);
/* Test DRC errors (clearance errors, bad connections .. */
errors
=
m_Parent
->
Test_DRC
(
m_DC
,
m_Pad2PadTestCtrl
->
IsChecked
(),
m_ZonesTestCtrl
->
IsChecked
());
/* Search for active routes (unconnected pads) */
if
(
m_UnconnectedTestCtrl
->
IsChecked
()
)
ListUnconnectedPads
(
event
);
else
m_UnconnectedCount
=
0
;
if
(
errors
)
msg
.
Printf
(
_
(
"** End Drc: %d errors **
\n
"
),
errors
);
else
if
(
m_UnconnectedCount
==
0
)
msg
=
_
(
"** End Drc: No Error **
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
s_RptFile
)
{
msg
.
Printf
(
_
(
"Report file <%s> created
\n
"
),
s_RptFilename
.
GetData
());
m_logWindow
->
AppendText
(
msg
);
fclose
(
s_RptFile
);
s_RptFile
=
NULL
;
}
}
else
wxBell
();
int
errors
;
wxString
msg
;
if
(
!
DrcInProgress
)
{
if
(
m_CreateRptCtrl
->
IsChecked
()
)
// Create a file rpt
{
s_RptFilename
=
m_RptFilenameCtrl
->
GetValue
();
if
(
s_RptFilename
.
IsEmpty
()
)
OnButtonBrowseRptFileClick
(
event
);
if
(
!
s_RptFilename
.
IsEmpty
()
)
s_RptFile
=
wxFopen
(
s_RptFilename
,
wxT
(
"w"
)
);
else
s_RptFile
=
NULL
;
}
if
(
s_RptFile
)
{
fprintf
(
s_RptFile
,
"Drc report for %s
\n
"
,
CONV_TO_UTF8
(
m_Parent
->
m_CurrentScreen
->
m_FileName
)
);
char
line
[
256
];
fprintf
(
s_RptFile
,
"Created on %s
\n
"
,
DateAndTime
(
line
)
);
}
s_Pad2PadTestOpt
=
m_Pad2PadTestCtrl
->
IsChecked
();
s_UnconnectedTestOpt
=
m_UnconnectedTestCtrl
->
IsChecked
();
s_ZonesTestOpt
=
m_ZonesTestCtrl
->
IsChecked
();
AbortDrc
=
FALSE
;
m_logWindow
->
Clear
();
g_DesignSettings
.
m_TrackClearence
=
ReturnValueFromTextCtrl
(
*
m_SetClearance
,
m_Parent
->
m_InternalUnits
);
/* Test DRC errors (clearance errors, bad connections .. */
errors
=
m_Parent
->
Test_DRC
(
m_DC
,
m_Pad2PadTestCtrl
->
IsChecked
(
),
m_ZonesTestCtrl
->
IsChecked
()
);
/* Search for active routes (unconnected pads) */
if
(
m_UnconnectedTestCtrl
->
IsChecked
()
)
ListUnconnectedPads
(
event
);
else
m_UnconnectedCount
=
0
;
if
(
errors
)
msg
.
Printf
(
_
(
"** End Drc: %d errors **
\n
"
),
errors
);
else
if
(
m_UnconnectedCount
==
0
)
msg
=
_
(
"** End Drc: No Error **
\n
"
);
m_logWindow
->
AppendText
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
s_RptFile
)
{
msg
.
Printf
(
_
(
"Report file <%s> created
\n
"
),
s_RptFilename
.
GetData
()
);
m_logWindow
->
AppendText
(
msg
);
fclose
(
s_RptFile
);
s_RptFile
=
NULL
;
}
}
else
wxBell
();
}
/*********************************************************/
void
WinEDA_DrcFrame
::
DelDRCMarkers
(
wxCommandEvent
&
event
)
void
WinEDA_DrcFrame
::
DelDRCMarkers
(
wxCommandEvent
&
event
)
/*********************************************************/
{
if
(
!
DrcInProgress
)
{
m_Parent
->
Erase_Marqueurs
();
m_Parent
->
DrawPanel
->
ReDraw
(
m_DC
,
TRUE
);
}
else
wxBell
();
if
(
!
DrcInProgress
)
{
m_Parent
->
Erase_Marqueurs
();
m_Parent
->
DrawPanel
->
ReDraw
(
m_DC
,
TRUE
);
}
else
wxBell
();
}
/******************************************************/
void
WinEDA_PcbFrame
::
Install_Test_DRC_Frame
(
wxDC
*
DC
)
void
WinEDA_PcbFrame
::
Install_Test_DRC_Frame
(
wxDC
*
DC
)
/******************************************************/
/* Test des isolements : teste les isolements des pistes et place un
marqueur sur les divers segments en defaut
Principe:
Appelle la routine drc() pour chaque segment de piste existant
*/
*
marqueur sur les divers segments en defaut
*
Principe:
*
Appelle la routine drc() pour chaque segment de piste existant
*/
{
AbortDrc
=
FALSE
;
DrcFrame
=
new
WinEDA_DrcFrame
(
this
,
DC
);
DrcFrame
->
ShowModal
();
DrcFrame
->
Destroy
();
DrcFrame
=
NULL
;
AbortDrc
=
FALSE
;
DrcFrame
=
new
WinEDA_DrcFrame
(
this
,
DC
);
DrcFrame
->
ShowModal
();
DrcFrame
->
Destroy
();
DrcFrame
=
NULL
;
}
/************************************************************************/
int
WinEDA_PcbFrame
::
Test_DRC
(
wxDC
*
DC
,
bool
TestPad2Pad
,
bool
TestZone
)
int
WinEDA_PcbFrame
::
Test_DRC
(
wxDC
*
DC
,
bool
TestPad2Pad
,
bool
TestZone
)
/************************************************************************/
/* Test des isolements : teste les isolements des pistes et place un
marqueur sur les divers segments en defaut
Principe:
Appelle la routine drc() pour chaque segment de piste existant
*/
*
marqueur sur les divers segments en defaut
*
Principe:
*
Appelle la routine drc() pour chaque segment de piste existant
*/
{
int
ii
,
jj
,
old_net
;
int
flag_err_Drc
;
TRACK
*
pt_segm
;
D_PAD
*
pad
;
MARQUEUR
*
Marqueur
;
EDA_BaseStruct
*
PtStruct
;
wxString
Line
;
#define PRINT_NB_PAD_POS 42
#define PRINT_PAD_ERR_POS 48
#define PRINT_TST_POS 20
#define PRINT_NB_SEGM_POS 26
#define PRINT_TRACK_ERR_POS 32
int
ii
,
jj
,
old_net
;
int
flag_err_Drc
;
TRACK
*
pt_segm
;
D_PAD
*
pad
;
MARQUEUR
*
Marqueur
;
EDA_BaseStruct
*
PtStruct
;
wxString
Line
;
#define PRINT_NB_PAD_POS 42
#define PRINT_PAD_ERR_POS 48
#define PRINT_TST_POS 20
#define PRINT_NB_SEGM_POS 26
#define PRINT_TRACK_ERR_POS 32
#define PRINT_NB_ZONESEGM_POS 60
#define PRINT_ZONE_ERR_POS 70
#define PRINT_ZONE_ERR_POS
70
DrcInProgress
=
TRUE
;
DrcInProgress
=
TRUE
;
ErrorsDRC_Count
=
0
;
Compile_Ratsnest
(
DC
,
TRUE
);
MsgPanel
->
EraseMsgBox
();
m_CurrentScreen
->
SetRefreshReq
();
/* Effacement des anciens marqueurs */
Erase_Marqueurs
();
if
(
TestPad2Pad
)
/* Test DRC des pads entre eux */
{
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbPads
)
;
Affiche_1_Parametre
(
this
,
PRINT_NB_PAD_POS
,
wxT
(
"NbPad"
),
Line
,
RED
)
;
Affiche_1_Parametre
(
this
,
PRINT_PAD_ERR_POS
,
wxT
(
"Pad Err"
),
wxT
(
"0"
),
LIGHTRED
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Pad to Pad
\n
"
));
LISTE_PAD
*
pad_list_start
=
CreateSortedPadListByXCoord
(
m_Pcb
);
LISTE_PAD
*
pad_list_limit
=
&
pad_list_start
[
m_Pcb
->
m_NbPads
];
int
max_size
=
0
;
LISTE_PAD
*
pad_list
;
/* Compute the max size of the pads ( used to stop the test) */
for
(
pad_list
=
pad_list_start
;
pad_list
<
pad_list_limit
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
pad
->
m_Rayon
>
max_size
)
max_size
=
pad
->
m_Rayon
;
}
/* Test the pads */
for
(
pad_list
=
pad_list_start
;
pad_list
<
pad_list_limit
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
Test_Pad_to_Pads_Drc
(
this
,
DC
,
pad
,
pad_list
,
pad_list_limit
,
max_size
,
TRUE
)
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
));
return
ErrorsDRC_Count
;
}
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
)
;
Affiche_1_Parametre
(
this
,
PRINT_PAD_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
}
}
free
(
pad_list_start
);
}
/* Test track segments */
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbSegmTrack
)
;
Affiche_1_Parametre
(
this
,
PRINT_NB_SEGM_POS
,
_
(
"SegmNb"
),
Line
,
RED
)
;
Affiche_1_Parametre
(
this
,
PRINT_TRACK_ERR_POS
,
_
(
"Track Err"
),
wxT
(
"0"
),
LIGHTRED
);
pt_segm
=
m_Pcb
->
m_Track
;
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Tracks
\n
"
)
);
for
(
ii
=
0
,
old_net
=
-
1
,
jj
=
0
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
,
ii
++
,
jj
--
)
{
if
(
pt_segm
->
Pnext
==
NULL
)
break
;
if
(
jj
==
0
)
{
jj
=
10
;
wxYield
();
if
(
AbortDrc
)
{
AbortDrc
=
FALSE
;
break
;
}
/* Print stats */
Line
.
Printf
(
wxT
(
"%d"
),
ii
);
Affiche_1_Parametre
(
this
,
PRINT_TST_POS
,
wxT
(
"Test"
),
Line
,
CYAN
)
;
}
if
(
old_net
!=
pt_segm
->
m_NetCode
)
{
wxString
msg
;
jj
=
1
;
EQUIPOT
*
equipot
=
GetEquipot
(
m_Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
msg
=
equipot
->
m_Netname
+
wxT
(
" "
);
else
msg
=
wxT
(
"<noname>"
);
Affiche_1_Parametre
(
this
,
0
,
_
(
"Netname"
),
msg
,
YELLOW
);
old_net
=
pt_segm
->
m_NetCode
;
}
g_HightLigth_NetCode
=
pt_segm
->
m_NetCode
;
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,(
TRACK
*
)
pt_segm
->
Pnext
,
1
);
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
));
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_TRACK_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
}
/* Test zone segments segments */
if
(
TestZone
)
{
m_Pcb
->
m_NbSegmZone
=
0
;
for
(
pt_segm
=
(
TRACK
*
)
m_Pcb
->
m_Zone
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
)
m_Pcb
->
m_NbSegmZone
++
;
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbSegmZone
)
;
Affiche_1_Parametre
(
this
,
PRINT_NB_ZONESEGM_POS
,
_
(
"SegmNb"
),
Line
,
RED
)
;
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
_
(
"Zone Err"
),
wxT
(
"0"
),
LIGHTRED
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Zones
\n
"
)
);
pt_segm
=
(
TRACK
*
)
m_Pcb
->
m_Zone
;
for
(
ii
=
0
,
old_net
=
-
1
,
jj
=
0
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
,
ii
++
,
jj
--
)
{
if
(
pt_segm
->
Pnext
==
NULL
)
break
;
if
(
jj
==
0
)
{
jj
=
100
;
wxYield
();
if
(
AbortDrc
)
{
AbortDrc
=
FALSE
;
break
;
}
/* Print stats */
Line
.
Printf
(
wxT
(
"%d"
),
ii
);
Affiche_1_Parametre
(
this
,
PRINT_TST_POS
,
wxT
(
"Test"
),
Line
,
CYAN
)
;
}
if
(
old_net
!=
pt_segm
->
m_NetCode
)
{
jj
=
1
;
wxString
msg
;
EQUIPOT
*
equipot
=
GetEquipot
(
m_Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
msg
=
equipot
->
m_Netname
+
wxT
(
" "
);
else
msg
=
wxT
(
"<noname>"
);
Affiche_1_Parametre
(
this
,
0
,
_
(
"Netname"
),
msg
,
YELLOW
);
old_net
=
pt_segm
->
m_NetCode
;
}
g_HightLigth_NetCode
=
pt_segm
->
m_NetCode
;
/* Test drc with other zone segments, and pads */
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,(
TRACK
*
)
pt_segm
->
Pnext
,
1
);
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
));
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
/* Test drc with track segments */
int
tmp
=
m_Pcb
->
m_NbPads
;
m_Pcb
->
m_NbPads
=
0
;
// Pads already tested: disable pad test
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,
m_Pcb
->
m_Track
,
1
);
m_Pcb
->
m_NbPads
=
tmp
;
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
));
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
}
}
AbortDrc
=
FALSE
;
DrcInProgress
=
FALSE
;
return
ErrorsDRC_Count
;
Compile_Ratsnest
(
DC
,
TRUE
);
MsgPanel
->
EraseMsgBox
();
m_CurrentScreen
->
SetRefreshReq
();
/* Effacement des anciens marqueurs */
Erase_Marqueurs
();
if
(
TestPad2Pad
)
/* Test DRC des pads entre eux */
{
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbPads
);
Affiche_1_Parametre
(
this
,
PRINT_NB_PAD_POS
,
wxT
(
"NbPad"
),
Line
,
RED
);
Affiche_1_Parametre
(
this
,
PRINT_PAD_ERR_POS
,
wxT
(
"Pad Err"
),
wxT
(
"0"
),
LIGHTRED
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Pad to Pad
\n
"
)
);
LISTE_PAD
*
pad_list_start
=
CreateSortedPadListByXCoord
(
m_Pcb
);
LISTE_PAD
*
pad_list_limit
=
&
pad_list_start
[
m_Pcb
->
m_NbPads
];
int
max_size
=
0
;
LISTE_PAD
*
pad_list
;
/* Compute the max size of the pads ( used to stop the test) */
for
(
pad_list
=
pad_list_start
;
pad_list
<
pad_list_limit
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
pad
->
m_Rayon
>
max_size
)
max_size
=
pad
->
m_Rayon
;
}
/* Test the pads */
for
(
pad_list
=
pad_list_start
;
pad_list
<
pad_list_limit
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
Test_Pad_to_Pads_Drc
(
this
,
DC
,
pad
,
pad_list
,
pad_list_limit
,
max_size
,
TRUE
)
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
)
);
return
ErrorsDRC_Count
;
}
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_PAD_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
}
}
free
(
pad_list_start
);
}
/* Test track segments */
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbSegmTrack
);
Affiche_1_Parametre
(
this
,
PRINT_NB_SEGM_POS
,
_
(
"SegmNb"
),
Line
,
RED
);
Affiche_1_Parametre
(
this
,
PRINT_TRACK_ERR_POS
,
_
(
"Track Err"
),
wxT
(
"0"
),
LIGHTRED
);
pt_segm
=
m_Pcb
->
m_Track
;
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Tracks
\n
"
)
);
for
(
ii
=
0
,
old_net
=
-
1
,
jj
=
0
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
,
ii
++
,
jj
--
)
{
if
(
pt_segm
->
Pnext
==
NULL
)
break
;
if
(
jj
==
0
)
{
jj
=
10
;
wxYield
();
if
(
AbortDrc
)
{
AbortDrc
=
FALSE
;
break
;
}
/* Print stats */
Line
.
Printf
(
wxT
(
"%d"
),
ii
);
Affiche_1_Parametre
(
this
,
PRINT_TST_POS
,
wxT
(
"Test"
),
Line
,
CYAN
);
}
if
(
old_net
!=
pt_segm
->
m_NetCode
)
{
wxString
msg
;
jj
=
1
;
EQUIPOT
*
equipot
=
GetEquipot
(
m_Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
msg
=
equipot
->
m_Netname
+
wxT
(
" "
);
else
msg
=
wxT
(
"<noname>"
);
Affiche_1_Parametre
(
this
,
0
,
_
(
"Netname"
),
msg
,
YELLOW
);
old_net
=
pt_segm
->
m_NetCode
;
}
g_HightLigth_NetCode
=
pt_segm
->
m_NetCode
;
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,
(
TRACK
*
)
pt_segm
->
Pnext
,
1
);
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
)
);
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_TRACK_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
}
/* Test zone segments segments */
if
(
TestZone
)
{
m_Pcb
->
m_NbSegmZone
=
0
;
for
(
pt_segm
=
(
TRACK
*
)
m_Pcb
->
m_Zone
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
)
m_Pcb
->
m_NbSegmZone
++
;
Line
.
Printf
(
wxT
(
"%d"
),
m_Pcb
->
m_NbSegmZone
);
Affiche_1_Parametre
(
this
,
PRINT_NB_ZONESEGM_POS
,
_
(
"SegmNb"
),
Line
,
RED
);
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
_
(
"Zone Err"
),
wxT
(
"0"
),
LIGHTRED
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
_
(
"Tst Zones
\n
"
)
);
pt_segm
=
(
TRACK
*
)
m_Pcb
->
m_Zone
;
for
(
ii
=
0
,
old_net
=
-
1
,
jj
=
0
;
pt_segm
!=
NULL
;
pt_segm
=
(
TRACK
*
)
pt_segm
->
Pnext
,
ii
++
,
jj
--
)
{
if
(
pt_segm
->
Pnext
==
NULL
)
break
;
if
(
jj
==
0
)
{
jj
=
100
;
wxYield
();
if
(
AbortDrc
)
{
AbortDrc
=
FALSE
;
break
;
}
/* Print stats */
Line
.
Printf
(
wxT
(
"%d"
),
ii
);
Affiche_1_Parametre
(
this
,
PRINT_TST_POS
,
wxT
(
"Test"
),
Line
,
CYAN
);
}
if
(
old_net
!=
pt_segm
->
m_NetCode
)
{
jj
=
1
;
wxString
msg
;
EQUIPOT
*
equipot
=
GetEquipot
(
m_Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
msg
=
equipot
->
m_Netname
+
wxT
(
" "
);
else
msg
=
wxT
(
"<noname>"
);
Affiche_1_Parametre
(
this
,
0
,
_
(
"Netname"
),
msg
,
YELLOW
);
old_net
=
pt_segm
->
m_NetCode
;
}
g_HightLigth_NetCode
=
pt_segm
->
m_NetCode
;
/* Test drc with other zone segments, and pads */
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,
(
TRACK
*
)
pt_segm
->
Pnext
,
1
);
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
)
);
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
/* Test drc with track segments */
int
tmp
=
m_Pcb
->
m_NbPads
;
m_Pcb
->
m_NbPads
=
0
;
// Pads already tested: disable pad test
flag_err_Drc
=
Drc
(
this
,
DC
,
pt_segm
,
m_Pcb
->
m_Track
,
1
);
m_Pcb
->
m_NbPads
=
tmp
;
if
(
flag_err_Drc
==
BAD_DRC
)
{
Marqueur
=
current_marqueur
;
current_marqueur
=
NULL
;
if
(
Marqueur
==
NULL
)
{
DisplayError
(
this
,
wxT
(
"Test_Drc(): internal err"
)
);
return
ErrorsDRC_Count
;
}
Marqueur
->
Pnext
=
m_Pcb
->
m_Drawings
;
Marqueur
->
Pback
=
m_Pcb
;
PtStruct
=
m_Pcb
->
m_Drawings
;
if
(
PtStruct
)
PtStruct
->
Pback
=
Marqueur
;
m_Pcb
->
m_Drawings
=
Marqueur
;
GRSetDrawMode
(
DC
,
GR_OR
);
pt_segm
->
Draw
(
DrawPanel
,
DC
,
RED
^
LIGHTRED
);
Line
.
Printf
(
wxT
(
"%d"
),
ErrorsDRC_Count
);
Affiche_1_Parametre
(
this
,
PRINT_ZONE_ERR_POS
,
wxEmptyString
,
Line
,
LIGHTRED
);
}
}
}
AbortDrc
=
FALSE
;
DrcInProgress
=
FALSE
;
return
ErrorsDRC_Count
;
}
/***********************************************************************/
int
Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
TRACK
*
pt_segment
,
TRACK
*
StartBuffer
,
int
show_err
)
int
Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
TRACK
*
pt_segment
,
TRACK
*
StartBuffer
,
int
show_err
)
/***********************************************************************/
/*
Teste le segment en cours de trace:
pt_segment = pointeur sur segment a controler
StartBuffer = adresse de la zone des pistes a controler
(typiquement m_Pcb->m_Track)
show_err (flag) si 0 pas d'affichage d'erreur sur ecran
retourne :
BAD_DRC (1) si Violation DRC
OK_DRC (0) si OK
*/
*
Teste le segment en cours de trace:
*
pt_segment = pointeur sur segment a controler
*
StartBuffer = adresse de la zone des pistes a controler
*
(typiquement m_Pcb->m_Track)
*
show_err (flag) si 0 pas d'affichage d'erreur sur ecran
*
retourne :
*
BAD_DRC (1) si Violation DRC
*
OK_DRC (0) si OK
*/
{
int
ii
;
TRACK
*
pttrack
;
int
x0
,
y0
,
xf
,
yf
;
// coord des extremites du segment teste dans le repere modifie
int
dx
,
dy
;
// utilise pour calcul des dim x et dim y des segments
int
w_dist
;
int
MaskLayer
;
int
net_code_ref
;
int
org_X
,
org_Y
;
// Origine sur le PCB des axes du repere centre sur
// l'origine du segment de reference
wxPoint
shape_pos
;
org_X
=
pt_segment
->
m_Start
.
x
;
org_Y
=
pt_segment
->
m_Start
.
y
;
finx
=
dx
=
pt_segment
->
m_End
.
x
-
org_X
;
finy
=
dy
=
pt_segment
->
m_End
.
y
-
org_Y
;
MaskLayer
=
pt_segment
->
ReturnMaskLayer
();
net_code_ref
=
pt_segment
->
m_NetCode
;
segm_angle
=
0
;
if
(
dx
||
dy
)
{
/* calcul de l'angle d'inclinaison en 0,1 degre */
segm_angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul de la longueur du segment en segm_long : dx = longueur */
RotatePoint
(
&
dx
,
&
dy
,
segm_angle
);
/* segm_long = longueur, yf = 0 */
}
/* Ici le segment a ete tourne de segm_angle, et est horizontal, dx > 0 */
segm_long
=
dx
;
/******************************************/
/* Phase 1 : test DRC track to pads :*/
/******************************************/
/* calcul de la distance min aux pads : */
w_dist
=
(
unsigned
)(
pt_segment
->
m_Width
>>
1
)
;
for
(
ii
=
0
;
ii
<
frame
->
m_Pcb
->
m_NbPads
;
ii
++
)
{
D_PAD
*
pt_pad
=
frame
->
m_Pcb
->
m_Pads
[
ii
];
/* Pas de probleme si les pads sont en surface autre que la couche,
sauf si le trou de percage gene (cas des pastilles perces simple
face sur CI double face */
if
(
(
pt_pad
->
m_Masque_Layer
&
MaskLayer
)
==
0
)
{
/* We must test the pad hole. In order to use the function "TestClearanceSegmToPad",
a pseudo pad is used, with a shape and a size like the hole */
if
(
pt_pad
->
m_Drill
.
x
==
0
)
continue
;
D_PAD
pseudo_pad
((
MODULE
*
)
NULL
);
pseudo_pad
.
m_Size
=
pt_pad
->
m_Drill
;
pseudo_pad
.
m_Pos
=
pt_pad
->
m_Pos
;
pseudo_pad
.
m_PadShape
=
pt_pad
->
m_DrillShape
;
pseudo_pad
.
m_Orient
=
pt_pad
->
m_Orient
;
pseudo_pad
.
ComputeRayon
();
spot_cX
=
pseudo_pad
.
m_Pos
.
x
-
org_X
;
spot_cY
=
pseudo_pad
.
m_Pos
.
y
-
org_Y
;
if
(
TestClearanceSegmToPad
(
&
pseudo_pad
,
w_dist
,
g_DesignSettings
.
m_TrackClearence
)
!=
OK_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pt_pad
,
0
);
return
(
BAD_DRC
);
}
continue
;
}
/* Le pad doit faire partie d'un net mais pas de probleme
si le pad est du meme net */
if
(
pt_pad
->
m_NetCode
&&
(
net_code_ref
==
pt_pad
->
m_NetCode
)
)
continue
;
/* Test DRC pour les pads */
int
ii
;
TRACK
*
pttrack
;
int
x0
,
y0
,
xf
,
yf
;
// coord des extremites du segment teste dans le repere modifie
int
dx
,
dy
;
// utilise pour calcul des dim x et dim y des segments
int
w_dist
;
int
MaskLayer
;
int
net_code_ref
;
int
org_X
,
org_Y
;
// Origine sur le PCB des axes du repere centre sur
// l'origine du segment de reference
wxPoint
shape_pos
;
org_X
=
pt_segment
->
m_Start
.
x
;
org_Y
=
pt_segment
->
m_Start
.
y
;
finx
=
dx
=
pt_segment
->
m_End
.
x
-
org_X
;
finy
=
dy
=
pt_segment
->
m_End
.
y
-
org_Y
;
MaskLayer
=
pt_segment
->
ReturnMaskLayer
();
net_code_ref
=
pt_segment
->
m_NetCode
;
segm_angle
=
0
;
if
(
dx
||
dy
)
{
/* calcul de l'angle d'inclinaison en 0,1 degre */
segm_angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul de la longueur du segment en segm_long : dx = longueur */
RotatePoint
(
&
dx
,
&
dy
,
segm_angle
);
/* segm_long = longueur, yf = 0 */
}
/* Ici le segment a ete tourne de segm_angle, et est horizontal, dx > 0 */
segm_long
=
dx
;
/******************************************/
/* Phase 1 : test DRC track to pads :*/
/******************************************/
/* calcul de la distance min aux pads : */
w_dist
=
(
unsigned
)
(
pt_segment
->
m_Width
>>
1
);
for
(
ii
=
0
;
ii
<
frame
->
m_Pcb
->
m_NbPads
;
ii
++
)
{
D_PAD
*
pt_pad
=
frame
->
m_Pcb
->
m_Pads
[
ii
];
/* Pas de probleme si les pads sont en surface autre que la couche,
* sauf si le trou de percage gene (cas des pastilles perc�s simple
* face sur CI double face */
if
(
(
pt_pad
->
m_Masque_Layer
&
MaskLayer
)
==
0
)
{
/* We must test the pad hole. In order to use the function "TestClearanceSegmToPad",
* a pseudo pad is used, with a shape and a size like the hole */
if
(
pt_pad
->
m_Drill
.
x
==
0
)
continue
;
D_PAD
pseudo_pad
(
(
MODULE
*
)
NULL
);
pseudo_pad
.
m_Size
=
pt_pad
->
m_Drill
;
pseudo_pad
.
m_Pos
=
pt_pad
->
m_Pos
;
pseudo_pad
.
m_PadShape
=
pt_pad
->
m_DrillShape
;
pseudo_pad
.
m_Orient
=
pt_pad
->
m_Orient
;
pseudo_pad
.
ComputeRayon
();
spot_cX
=
pseudo_pad
.
m_Pos
.
x
-
org_X
;
spot_cY
=
pseudo_pad
.
m_Pos
.
y
-
org_Y
;
if
(
TestClearanceSegmToPad
(
&
pseudo_pad
,
w_dist
,
g_DesignSettings
.
m_TrackClearence
)
!=
OK_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pt_pad
,
0
);
return
BAD_DRC
;
}
continue
;
}
/* Le pad doit faire partie d'un net mais pas de probleme
* si le pad est du meme net */
if
(
pt_pad
->
m_NetCode
&&
(
net_code_ref
==
pt_pad
->
m_NetCode
)
)
continue
;
/* Test DRC pour les pads */
shape_pos
=
pt_pad
->
ReturnShapePos
();
spot_cX
=
shape_pos
.
x
-
org_X
;
spot_cY
=
shape_pos
.
y
-
org_Y
;
if
(
TestClearanceSegmToPad
(
pt_pad
,
w_dist
,
g_DesignSettings
.
m_TrackClearence
)
==
OK_DRC
)
continue
;
/* extremite sur pad ou defaut d'isolation trouve */
else
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pt_pad
,
1
);
return
(
BAD_DRC
);
}
}
/**********************************************/
/* Phase 2 : test DRC avec les autres pistes :*/
/**********************************************/
/* Ici le segment de reference est sur l'axe X */
/* Comparaison du segment de reference aux autres segments de piste */
pttrack
=
StartBuffer
;
for
(
;
pttrack
!=
NULL
;
pttrack
=
(
TRACK
*
)
pttrack
->
Pnext
)
{
//pas de probleme si le segment a tester est du meme net:
if
(
net_code_ref
==
pttrack
->
m_NetCode
)
continue
;
//pas de probleme si le segment a tester est sur une autre couche :
if
(
(
MaskLayer
&
pttrack
->
ReturnMaskLayer
()
)
==
0
)
continue
;
/* calcul de la Distance mini = Isol+ rayon ou demi largeur seg ref
+ rayon ou demi largeur seg a comparer */
w_dist
=
pt_segment
->
m_Width
>>
1
;
w_dist
+=
pttrack
->
m_Width
>>
1
;
w_dist
+=
g_DesignSettings
.
m_TrackClearence
;
/* si le segment de reference est une via, le traitement est ici */
if
(
pt_segment
->
m_StructType
==
TYPEVIA
)
{
int
orgx
,
orgy
;
// origine du repere d'axe X = segment a comparer
int
angle
=
0
;
// angle du segment a tester;
orgx
=
pttrack
->
m_Start
.
x
;
orgy
=
pttrack
->
m_Start
.
y
;
dx
=
pttrack
->
m_End
.
x
-
orgx
;
dy
=
pttrack
->
m_End
.
y
-
orgy
;
x0
=
pt_segment
->
m_Start
.
x
-
orgx
;
y0
=
pt_segment
->
m_Start
.
y
-
orgy
;
if
(
pttrack
->
m_StructType
==
TYPEVIA
)
/* Tst distance entre 2 vias */
{
if
(
(
int
)
hypot
((
float
)
x0
,(
float
)
y0
)
<
w_dist
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
21
);
return
(
BAD_DRC
)
;
}
}
else
/* Tst distance de via a segment */
{
/* calcul de l'angle */
angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul des coord dans le nouveau repere */
RotatePoint
(
&
dx
,
&
dy
,
angle
);
RotatePoint
(
&
x0
,
&
y0
,
angle
);
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
20
);
return
(
BAD_DRC
)
;
}
}
continue
;
}
/* calcule x0,y0, xf,yf = coord de debut et fin du segment de piste
a tester, dans le repere axe X = segment de reference */
x0
=
pttrack
->
m_Start
.
x
-
org_X
;
y0
=
pttrack
->
m_Start
.
y
-
org_Y
;
xf
=
pttrack
->
m_End
.
x
-
org_X
;
yf
=
pttrack
->
m_End
.
y
-
org_Y
;
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
RotatePoint
(
&
xf
,
&
yf
,
segm_angle
);
if
(
pttrack
->
m_StructType
==
TYPEVIA
)
{
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
OK_DRC
)
continue
;
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
21
);
return
(
BAD_DRC
)
;
}
/*
le segment de reference est Horizontal, par suite des modifs d'axe.
3 cas : segment a comparer parallele, perp ou incline
*/
if
(
y0
==
yf
)
// segments paralleles
{
if
(
abs
(
y0
)
>=
w_dist
)
continue
;
if
(
x0
>
xf
)
EXCHG
(
x0
,
xf
)
;
/* pour que x0 <= xf */
if
(
x0
>
(
-
w_dist
)
&&
x0
<
(
segm_long
+
w_dist
))
/* Risque de defaut */
{
/* test fin tenant compte des formes arrondies des extremites */
if
(
x0
>=
0
&&
x0
<=
segm_long
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
2
);
return
(
BAD_DRC
)
;
}
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
2
);
return
(
BAD_DRC
)
;
}
}
if
(
xf
>
(
-
w_dist
)
&&
xf
<
(
segm_long
+
w_dist
))
{
/* test fin tenant compte des formes arrondies des extremites */
if
(
xf
>=
0
&&
xf
<=
segm_long
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
3
);
return
(
BAD_DRC
)
;
}
if
(
TestMarginToCircle
(
xf
,
yf
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
3
);
return
(
BAD_DRC
)
;
}
}
if
(
x0
<=
0
&&
xf
>=
0
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
4
);
return
(
BAD_DRC
)
;
}
}
else
if
(
x0
==
xf
)
// segments perpendiculaires
{
if
(
(
x0
<=
(
-
w_dist
))
||
(
x0
>=
(
segm_long
+
w_dist
)))
continue
;
/* test si les segments se croisent */
if
(
y0
>
yf
)
EXCHG
(
y0
,
yf
);
if
(
(
y0
<
0
)
&&
(
yf
>
0
)
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
6
);
return
(
BAD_DRC
);
}
/* ici l'erreur est due a une extremite pres d'une extremite du segm
de reference */
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
7
);
return
(
BAD_DRC
)
;
}
if
(
TestMarginToCircle
(
xf
,
yf
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
8
);
return
(
BAD_DRC
)
;
}
}
else
// segments quelconques entre eux */
{
int
bflag
=
OK_DRC
;
/* calcul de la "surface de securite du segment de reference */
/* premiere passe : la piste est assimilee a un rectangle */
xcliplo
=
ycliplo
=
-
w_dist
;
xcliphi
=
segm_long
+
w_dist
;
ycliphi
=
w_dist
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
/* 2eme passe : la piste a des extremites arrondies.
Si le defaut de drc est du a une extremite : le calcul
est affine pour tenir compte de cet arrondi */
xcliplo
=
0
;
xcliphi
=
segm_long
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
)
;
if
(
bflag
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
9
);
return
(
BAD_DRC
)
;
}
else
// L'erreur est due a une extremite du segment de reference:
{
// il faut tester les extremites de ce segment
int
angle
,
rx0
,
ry0
,
rxf
,
ryf
;
x0
=
pttrack
->
m_Start
.
x
;
y0
=
pttrack
->
m_Start
.
y
;
xf
=
pttrack
->
m_End
.
x
;
yf
=
pttrack
->
m_End
.
y
;
dx
=
xf
-
x0
;
dy
=
yf
-
y0
;
/* calcul de l'angle d'inclinaison en 0,1 degre */
angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul de la longueur du segment: dx = longueur */
RotatePoint
(
&
dx
,
&
dy
,
angle
);
/* calcul des coord du segment de reference ds le repere
d'axe X = segment courant en tst */
rx0
=
pt_segment
->
m_Start
.
x
-
x0
;
ry0
=
pt_segment
->
m_Start
.
y
-
y0
;
rxf
=
pt_segment
->
m_End
.
x
-
x0
;
ryf
=
pt_segment
->
m_End
.
y
-
y0
;
RotatePoint
(
&
rx0
,
&
ry0
,
angle
);
RotatePoint
(
&
rxf
,
&
ryf
,
angle
);
if
(
TestMarginToCircle
(
rx0
,
ry0
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
10
);
return
(
BAD_DRC
)
;
}
if
(
TestMarginToCircle
(
rxf
,
ryf
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
11
);
return
(
BAD_DRC
)
;
}
}
}
}
}
return
(
OK_DRC
)
;
spot_cX
=
shape_pos
.
x
-
org_X
;
spot_cY
=
shape_pos
.
y
-
org_Y
;
if
(
TestClearanceSegmToPad
(
pt_pad
,
w_dist
,
g_DesignSettings
.
m_TrackClearence
)
==
OK_DRC
)
continue
;
/* extremite sur pad ou defaut d'isolation trouve */
else
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pt_pad
,
1
);
return
BAD_DRC
;
}
}
/**********************************************/
/* Phase 2 : test DRC avec les autres pistes :*/
/**********************************************/
/* Ici le segment de reference est sur l'axe X */
/* Comparaison du segment de reference aux autres segments de piste */
pttrack
=
StartBuffer
;
for
(
;
pttrack
!=
NULL
;
pttrack
=
(
TRACK
*
)
pttrack
->
Pnext
)
{
//pas de probleme si le segment a tester est du meme net:
if
(
net_code_ref
==
pttrack
->
m_NetCode
)
continue
;
//pas de probleme si le segment a tester est sur une autre couche :
if
(
(
MaskLayer
&
pttrack
->
ReturnMaskLayer
()
)
==
0
)
continue
;
/* calcul de la Distance mini = Isol+ rayon ou demi largeur seg ref
+ rayon ou demi largeur seg a comparer */
w_dist
=
pt_segment
->
m_Width
>>
1
;
w_dist
+=
pttrack
->
m_Width
>>
1
;
w_dist
+=
g_DesignSettings
.
m_TrackClearence
;
/* si le segment de reference est une via, le traitement est ici */
if
(
pt_segment
->
m_StructType
==
TYPEVIA
)
{
int
orgx
,
orgy
;
// origine du repere d'axe X = segment a comparer
int
angle
=
0
;
// angle du segment a tester;
orgx
=
pttrack
->
m_Start
.
x
;
orgy
=
pttrack
->
m_Start
.
y
;
dx
=
pttrack
->
m_End
.
x
-
orgx
;
dy
=
pttrack
->
m_End
.
y
-
orgy
;
x0
=
pt_segment
->
m_Start
.
x
-
orgx
;
y0
=
pt_segment
->
m_Start
.
y
-
orgy
;
if
(
pttrack
->
m_StructType
==
TYPEVIA
)
/* Tst distance entre 2 vias */
{
if
(
(
int
)
hypot
(
(
float
)
x0
,
(
float
)
y0
)
<
w_dist
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
21
);
return
BAD_DRC
;
}
}
else
/* Tst distance de via a segment */
{
/* calcul de l'angle */
angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul des coord dans le nouveau repere */
RotatePoint
(
&
dx
,
&
dy
,
angle
);
RotatePoint
(
&
x0
,
&
y0
,
angle
);
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
20
);
return
BAD_DRC
;
}
}
continue
;
}
/* calcule x0,y0, xf,yf = coord de debut et fin du segment de piste
* a tester, dans le repere axe X = segment de reference */
x0
=
pttrack
->
m_Start
.
x
-
org_X
;
y0
=
pttrack
->
m_Start
.
y
-
org_Y
;
xf
=
pttrack
->
m_End
.
x
-
org_X
;
yf
=
pttrack
->
m_End
.
y
-
org_Y
;
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
RotatePoint
(
&
xf
,
&
yf
,
segm_angle
);
if
(
pttrack
->
m_StructType
==
TYPEVIA
)
{
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
OK_DRC
)
continue
;
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
21
);
return
BAD_DRC
;
}
/*
* le segment de reference est Horizontal, par suite des modifs d'axe.
* 3 cas : segment a comparer parallele, perp ou incline
*/
if
(
y0
==
yf
)
// segments paralleles
{
if
(
abs
(
y0
)
>=
w_dist
)
continue
;
if
(
x0
>
xf
)
EXCHG
(
x0
,
xf
);
/* pour que x0 <= xf */
if
(
x0
>
(
-
w_dist
)
&&
x0
<
(
segm_long
+
w_dist
)
)
/* Risque de defaut */
{
/* test fin tenant compte des formes arrondies des extremites */
if
(
x0
>=
0
&&
x0
<=
segm_long
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
2
);
return
BAD_DRC
;
}
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
2
);
return
BAD_DRC
;
}
}
if
(
xf
>
(
-
w_dist
)
&&
xf
<
(
segm_long
+
w_dist
)
)
{
/* test fin tenant compte des formes arrondies des extremites */
if
(
xf
>=
0
&&
xf
<=
segm_long
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
3
);
return
BAD_DRC
;
}
if
(
TestMarginToCircle
(
xf
,
yf
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
3
);
return
BAD_DRC
;
}
}
if
(
x0
<=
0
&&
xf
>=
0
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
4
);
return
BAD_DRC
;
}
}
else
if
(
x0
==
xf
)
// segments perpendiculaires
{
if
(
(
x0
<=
(
-
w_dist
)
)
||
(
x0
>=
(
segm_long
+
w_dist
)
)
)
continue
;
/* test si les segments se croisent */
if
(
y0
>
yf
)
EXCHG
(
y0
,
yf
);
if
(
(
y0
<
0
)
&&
(
yf
>
0
)
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
6
);
return
BAD_DRC
;
}
/* ici l'erreur est due a une extremite pres d'une extremite du segm
* de reference */
if
(
TestMarginToCircle
(
x0
,
y0
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
7
);
return
BAD_DRC
;
}
if
(
TestMarginToCircle
(
xf
,
yf
,
w_dist
,
segm_long
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
8
);
return
BAD_DRC
;
}
}
else
// segments quelconques entre eux */
{
int
bflag
=
OK_DRC
;
/* calcul de la "surface de securite du segment de reference */
/* premiere passe : la piste est assimilee a un rectangle */
xcliplo
=
ycliplo
=
-
w_dist
;
xcliphi
=
segm_long
+
w_dist
;
ycliphi
=
w_dist
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
/* 2eme passe : la piste a des extremites arrondies.
* Si le defaut de drc est du a une extremite : le calcul
* est affine pour tenir compte de cet arrondi */
xcliplo
=
0
;
xcliphi
=
segm_long
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
9
);
return
BAD_DRC
;
}
else
// L'erreur est due a une extremite du segment de reference:
{
// il faut tester les extremites de ce segment
int
angle
,
rx0
,
ry0
,
rxf
,
ryf
;
x0
=
pttrack
->
m_Start
.
x
;
y0
=
pttrack
->
m_Start
.
y
;
xf
=
pttrack
->
m_End
.
x
;
yf
=
pttrack
->
m_End
.
y
;
dx
=
xf
-
x0
;
dy
=
yf
-
y0
;
/* calcul de l'angle d'inclinaison en 0,1 degre */
angle
=
ArcTangente
(
dy
,
dx
);
/* Calcul de la longueur du segment: dx = longueur */
RotatePoint
(
&
dx
,
&
dy
,
angle
);
/* calcul des coord du segment de reference ds le repere
* d'axe X = segment courant en tst */
rx0
=
pt_segment
->
m_Start
.
x
-
x0
;
ry0
=
pt_segment
->
m_Start
.
y
-
y0
;
rxf
=
pt_segment
->
m_End
.
x
-
x0
;
ryf
=
pt_segment
->
m_End
.
y
-
y0
;
RotatePoint
(
&
rx0
,
&
ry0
,
angle
);
RotatePoint
(
&
rxf
,
&
ryf
,
angle
);
if
(
TestMarginToCircle
(
rx0
,
ry0
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
10
);
return
BAD_DRC
;
}
if
(
TestMarginToCircle
(
rxf
,
ryf
,
w_dist
,
dx
)
==
BAD_DRC
)
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pt_segment
,
pttrack
,
11
);
return
BAD_DRC
;
}
}
}
}
}
return
OK_DRC
;
}
/*****************************************************************************/
static
bool
Test_Pad_to_Pads_Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
D_PAD
*
pad_ref
,
LISTE_PAD
*
start_buffer
,
LISTE_PAD
*
end_buffer
,
int
max_size
,
bool
show_err
)
static
bool
Test_Pad_to_Pads_Drc
(
WinEDA_BasePcbFrame
*
frame
,
wxDC
*
DC
,
D_PAD
*
pad_ref
,
LISTE_PAD
*
start_buffer
,
LISTE_PAD
*
end_buffer
,
int
max_size
,
bool
show_err
)
/*****************************************************************************/
/* Teste l'isolation de pad_ref avec les autres pads.
end_buffer = upper limit of the pad list.
max_size = size of the biggest pad (used to stop the test when the X distance is > max_size)
*/
*
end_buffer = upper limit of the pad list.
*
max_size = size of the biggest pad (used to stop the test when the X distance is > max_size)
*/
{
int
MaskLayer
;
D_PAD
*
pad
;
LISTE_PAD
*
pad_list
=
start_buffer
;
MaskLayer
=
pad_ref
->
m_Masque_Layer
&
ALL_CU_LAYERS
;
int
x_limite
=
max_size
+
g_DesignSettings
.
m_TrackClearence
+
pad_ref
->
m_Rayon
+
pad_ref
->
m_Pos
.
x
;
for
(
;
pad_list
<
end_buffer
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
pad
==
pad_ref
)
continue
;
/* We can stop the test when pad->m_Pos.x > x_limite
because the list is sorted by X values */
if
(
pad
->
m_Pos
.
x
>
x_limite
)
break
;
/* Pas de probleme si les pads ne sont pas sur les memes couches cuivre*/
if
(
(
pad
->
m_Masque_Layer
&
MaskLayer
)
==
0
)
continue
;
/* Le pad doit faire partie d'un net,
mais pas de probleme si les pads sont du meme net */
if
(
pad
->
m_NetCode
&&
(
pad_ref
->
m_NetCode
==
pad
->
m_NetCode
)
)
continue
;
/* pas de pb si les pads sont du meme module et
de la meme reference ( pads multiples ) */
if
(
(
pad
->
m_Parent
==
pad_ref
->
m_Parent
)
&&
(
pad
->
m_NumPadName
==
pad_ref
->
m_NumPadName
)
)
continue
;
if
(
Pad_to_Pad_Isol
(
pad_ref
,
pad
,
g_DesignSettings
.
m_TrackClearence
)
==
OK_DRC
)
continue
;
else
/* defaut d'isolation trouve */
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pad_ref
,
pad
);
return
(
BAD_DRC
);
}
}
return
OK_DRC
;
int
MaskLayer
;
D_PAD
*
pad
;
LISTE_PAD
*
pad_list
=
start_buffer
;
MaskLayer
=
pad_ref
->
m_Masque_Layer
&
ALL_CU_LAYERS
;
int
x_limite
=
max_size
+
g_DesignSettings
.
m_TrackClearence
+
pad_ref
->
m_Rayon
+
pad_ref
->
m_Pos
.
x
;
for
(
;
pad_list
<
end_buffer
;
pad_list
++
)
{
pad
=
*
pad_list
;
if
(
pad
==
pad_ref
)
continue
;
/* We can stop the test when pad->m_Pos.x > x_limite
* because the list is sorted by X values */
if
(
pad
->
m_Pos
.
x
>
x_limite
)
break
;
/* Pas de probleme si les pads ne sont pas sur les memes couches cuivre*/
if
(
(
pad
->
m_Masque_Layer
&
MaskLayer
)
==
0
)
continue
;
/* Le pad doit faire partie d'un net,
* mais pas de probleme si les pads sont du meme net */
if
(
pad
->
m_NetCode
&&
(
pad_ref
->
m_NetCode
==
pad
->
m_NetCode
)
)
continue
;
/* pas de pb si les pads sont du meme module et
* de la meme reference ( pads multiples ) */
if
(
(
pad
->
m_Parent
==
pad_ref
->
m_Parent
)
&&
(
pad
->
m_NumPadName
==
pad_ref
->
m_NumPadName
)
)
continue
;
if
(
Pad_to_Pad_Isol
(
pad_ref
,
pad
,
g_DesignSettings
.
m_TrackClearence
)
==
OK_DRC
)
continue
;
else
/* defaut d'isolation trouve */
{
ErrorsDRC_Count
++
;
if
(
show_err
)
Affiche_Erreur_DRC
(
frame
->
DrawPanel
,
DC
,
frame
->
m_Pcb
,
pad_ref
,
pad
);
return
BAD_DRC
;
}
}
return
OK_DRC
;
}
/**************************************************************************************/
static
int
Pad_to_Pad_Isol
(
D_PAD
*
pad_ref
,
D_PAD
*
pad
,
const
int
dist_min
)
static
int
Pad_to_Pad_Isol
(
D_PAD
*
pad_ref
,
D_PAD
*
pad
,
const
int
dist_min
)
/***************************************************************************************/
/* Return OK_DRC si clearance between pad_ref and pad is >= dist_min
or BAD_DRC if not */
*
or BAD_DRC if not */
{
wxPoint
rel_pos
;
int
dist
,
diag
;
wxPoint
shape_pos
;
int
pad_angle
;
rel_pos
=
pad
->
ReturnShapePos
();
wxPoint
rel_pos
;
int
dist
,
diag
;
wxPoint
shape_pos
;
int
pad_angle
;
rel_pos
=
pad
->
ReturnShapePos
();
shape_pos
=
pad_ref
->
ReturnShapePos
();
// rel_pos is pad position relative to the pad_ref position
rel_pos
.
x
-=
shape_pos
.
x
;
rel_pos
.
y
-=
shape_pos
.
y
;
dist
=
(
int
)
hypot
(
(
double
)
rel_pos
.
x
,
(
double
)
rel_pos
.
y
);
diag
=
OK_DRC
;
/* tst rapide: si les cercles exinscrits sont distants de dist_min au moins,
il n'y a pas de risque: */
if
(
(
dist
-
pad_ref
->
m_Rayon
-
pad
->
m_Rayon
)
>=
dist_min
)
return
OK_DRC
;
/* Ici les pads sont proches et les cercles exinxcrits sont trop proches
Selon les formes relatives il peut y avoir ou non erreur */
bool
swap_pads
=
false
;
if
(
(
pad_ref
->
m_PadShape
!=
CIRCLE
)
&&
(
pad
->
m_PadShape
==
CIRCLE
)
)
swap_pads
=
true
;
else
if
(
(
pad_ref
->
m_PadShape
!=
OVALE
)
&&
(
pad
->
m_PadShape
==
OVALE
)
)
swap_pads
=
true
;
if
(
swap_pads
)
{
EXCHG
(
pad_ref
,
pad
);
rel_pos
.
x
=
-
rel_pos
.
x
;
rel_pos
.
y
=
-
rel_pos
.
y
;
}
switch
(
pad_ref
->
m_PadShape
)
{
case
CIRCLE
:
// pad_ref is like a track segment with a null lenght
segm_long
=
0
;
segm_angle
=
0
;
finx
=
finy
=
0
;
spot_cX
=
rel_pos
.
x
;
spot_cY
=
rel_pos
.
y
;
diag
=
TestClearanceSegmToPad
(
pad
,
pad_ref
->
m_Rayon
,
dist_min
);
break
;
case
RECT
:
RotatePoint
(
&
rel_pos
.
x
,
&
rel_pos
.
y
,
pad_ref
->
m_Orient
);
pad_angle
=
pad_ref
->
m_Orient
+
pad
->
m_Orient
;
// pad_angle = pad orient relative to the pad_ref orient
NORMALIZE_ANGLE_POS
(
pad_angle
);
if
(
pad
->
m_PadShape
==
RECT
)
{
wxSize
size
=
pad
->
m_Size
;
if
(
(
pad_angle
==
0
)
||
(
pad_angle
==
900
)
||
(
pad_angle
==
1800
)
||
(
pad_angle
==
2700
))
{
if
(
(
pad_angle
==
900
)
||
(
pad_angle
==
2700
)
)
{
EXCHG
(
size
.
x
,
size
.
y
);
}
// Test DRC:
diag
=
BAD_DRC
;
rel_pos
.
x
=
ABS
(
rel_pos
.
x
);
rel_pos
.
y
=
ABS
(
rel_pos
.
y
);
if
(
(
rel_pos
.
x
-
((
size
.
x
+
pad_ref
->
m_Size
.
x
)
/
2
)
)
>=
dist_min
)
diag
=
OK_DRC
;
if
(
(
rel_pos
.
y
-
((
size
.
y
+
pad_ref
->
m_Size
.
y
)
/
2
)
)
>=
dist_min
)
diag
=
OK_DRC
;
}
else
// Any other orient
{
/* TODO : any orient ... */
}
}
break
;
case
OVALE
:
/* an oval pad is like a track segment */
{
/* Create and test a track segment with same dimensions */
int
segm_width
;
segm_angle
=
pad_ref
->
m_Orient
;
// Segment orient.
if
(
pad_ref
->
m_Size
.
y
<
pad_ref
->
m_Size
.
x
)
/* We suppose the pad is an horizontal oval */
{
segm_width
=
pad_ref
->
m_Size
.
y
;
segm_long
=
pad_ref
->
m_Size
.
x
-
pad_ref
->
m_Size
.
y
;
}
else
// it was a vertical oval, change to a rotated horizontal one
{
segm_width
=
pad_ref
->
m_Size
.
x
;
segm_long
=
pad_ref
->
m_Size
.
y
-
pad_ref
->
m_Size
.
x
;
segm_angle
+=
900
;
}
/* the start point must be 0,0 and currently rel_pos is relative the center of pad coordinate */
int
sx
=
-
segm_long
/
2
,
sy
=
0
;
// Start point coordinate of the horizontal equivalent segment
RotatePoint
(
&
sx
,
&
sy
,
segm_angle
);
// True start point coordinate of the equivalent segment
spot_cX
=
rel_pos
.
x
+
sx
;
spot_cY
=
rel_pos
.
y
+
sy
;
// pad position / segment origin
finx
=
-
sx
;
finy
=
-
sy
;
// end of segment coordinate
diag
=
TestClearanceSegmToPad
(
pad
,
segm_width
/
2
,
dist_min
);
break
;
}
default
:
/* TODO...*/
break
;
}
return
diag
;
// rel_pos is pad position relative to the pad_ref position
rel_pos
.
x
-=
shape_pos
.
x
;
rel_pos
.
y
-=
shape_pos
.
y
;
dist
=
(
int
)
hypot
(
(
double
)
rel_pos
.
x
,
(
double
)
rel_pos
.
y
);
diag
=
OK_DRC
;
/* tst rapide: si les cercles exinscrits sont distants de dist_min au moins,
* il n'y a pas de risque: */
if
(
(
dist
-
pad_ref
->
m_Rayon
-
pad
->
m_Rayon
)
>=
dist_min
)
return
OK_DRC
;
/* Ici les pads sont proches et les cercles exinxcrits sont trop proches
* Selon les formes relatives il peut y avoir ou non erreur */
bool
swap_pads
=
false
;
if
(
(
pad_ref
->
m_PadShape
!=
CIRCLE
)
&&
(
pad
->
m_PadShape
==
CIRCLE
)
)
swap_pads
=
true
;
else
if
(
(
pad_ref
->
m_PadShape
!=
OVALE
)
&&
(
pad
->
m_PadShape
==
OVALE
)
)
swap_pads
=
true
;
if
(
swap_pads
)
{
EXCHG
(
pad_ref
,
pad
);
rel_pos
.
x
=
-
rel_pos
.
x
;
rel_pos
.
y
=
-
rel_pos
.
y
;
}
switch
(
pad_ref
->
m_PadShape
)
{
case
CIRCLE
:
// pad_ref is like a track segment with a null lenght
segm_long
=
0
;
segm_angle
=
0
;
finx
=
finy
=
0
;
spot_cX
=
rel_pos
.
x
;
spot_cY
=
rel_pos
.
y
;
diag
=
TestClearanceSegmToPad
(
pad
,
pad_ref
->
m_Rayon
,
dist_min
);
break
;
case
RECT
:
RotatePoint
(
&
rel_pos
.
x
,
&
rel_pos
.
y
,
pad_ref
->
m_Orient
);
pad_angle
=
pad_ref
->
m_Orient
+
pad
->
m_Orient
;
// pad_angle = pad orient relative to the pad_ref orient
NORMALIZE_ANGLE_POS
(
pad_angle
);
if
(
pad
->
m_PadShape
==
RECT
)
{
wxSize
size
=
pad
->
m_Size
;
if
(
(
pad_angle
==
0
)
||
(
pad_angle
==
900
)
||
(
pad_angle
==
1800
)
||
(
pad_angle
==
2700
)
)
{
if
(
(
pad_angle
==
900
)
||
(
pad_angle
==
2700
)
)
{
EXCHG
(
size
.
x
,
size
.
y
);
}
// Test DRC:
diag
=
BAD_DRC
;
rel_pos
.
x
=
ABS
(
rel_pos
.
x
);
rel_pos
.
y
=
ABS
(
rel_pos
.
y
);
if
(
(
rel_pos
.
x
-
(
(
size
.
x
+
pad_ref
->
m_Size
.
x
)
/
2
)
)
>=
dist_min
)
diag
=
OK_DRC
;
if
(
(
rel_pos
.
y
-
(
(
size
.
y
+
pad_ref
->
m_Size
.
y
)
/
2
)
)
>=
dist_min
)
diag
=
OK_DRC
;
}
else
// Any other orient
{
/* TODO : any orient ... */
}
}
break
;
case
OVALE
:
/* an oval pad is like a track segment */
{
/* Create and test a track segment with same dimensions */
int
segm_width
;
segm_angle
=
pad_ref
->
m_Orient
;
// Segment orient.
if
(
pad_ref
->
m_Size
.
y
<
pad_ref
->
m_Size
.
x
)
/* We suppose the pad is an horizontal oval */
{
segm_width
=
pad_ref
->
m_Size
.
y
;
segm_long
=
pad_ref
->
m_Size
.
x
-
pad_ref
->
m_Size
.
y
;
}
else
// it was a vertical oval, change to a rotated horizontal one
{
segm_width
=
pad_ref
->
m_Size
.
x
;
segm_long
=
pad_ref
->
m_Size
.
y
-
pad_ref
->
m_Size
.
x
;
segm_angle
+=
900
;
}
/* the start point must be 0,0 and currently rel_pos is relative the center of pad coordinate */
int
sx
=
-
segm_long
/
2
,
sy
=
0
;
// Start point coordinate of the horizontal equivalent segment
RotatePoint
(
&
sx
,
&
sy
,
segm_angle
);
// True start point coordinate of the equivalent segment
spot_cX
=
rel_pos
.
x
+
sx
;
spot_cY
=
rel_pos
.
y
+
sy
;
// pad position / segment origin
finx
=
-
sx
;
finy
=
-
sy
;
// end of segment coordinate
diag
=
TestClearanceSegmToPad
(
pad
,
segm_width
/
2
,
dist_min
);
break
;
}
default
:
/* TODO...*/
break
;
}
return
diag
;
}
/***************************************************************************/
static
int
TestClearanceSegmToPad
(
const
D_PAD
*
pad_to_test
,
int
w_segm
,
int
dist_min
)
static
int
TestClearanceSegmToPad
(
const
D_PAD
*
pad_to_test
,
int
w_segm
,
int
dist_min
)
/****************************************************************************/
/*
Routine adaptee de la "distance()" (LOCATE.CPP)
teste la distance du pad au segment de droite en cours
retourne:
0 si distance >= dist_min
1 si distance < dist_min
Parametres d'appel:
pad_to_test = pointeur sur le pad a tester
w_segm = demi largeur du segment a tester
dist_min = marge a respecter
en variables globales
segm_long = longueur du segment en test
segm_angle = angle d'inclinaison du segment;
finx, finy = coord fin du segment / origine
spot_cX, spot_cY = position du pad / origine du segment
*/
*
Routine adaptee de la "distance()" (LOCATE.CPP)
*
teste la distance du pad au segment de droite en cours
*
*
retourne:
*
0 si distance >= dist_min
*
1 si distance < dist_min
*
Parametres d'appel:
*
pad_to_test = pointeur sur le pad a tester
*
w_segm = demi largeur du segment a tester
*
dist_min = marge a respecter
*
*
en variables globales
*
segm_long = longueur du segment en test
*
segm_angle = angle d'inclinaison du segment;
*
finx, finy = coord fin du segment / origine
*
spot_cX, spot_cY = position du pad / origine du segment
*/
{
int
p_dimx
,
p_dimy
;
/* demi - dimensions X et Y du pad a controler */
int
bflag
;
int
orient
;
int
x0
,
y0
,
xf
,
yf
;
int
seuil
;
int
deltay
;
seuil
=
w_segm
+
dist_min
;
p_dimx
=
pad_to_test
->
m_Size
.
x
>>
1
;
p_dimy
=
pad_to_test
->
m_Size
.
y
>>
1
;
if
(
pad_to_test
->
m_PadShape
==
CIRCLE
)
{
/* calcul des coord centre du pad dans le repere axe X confondu
avec le segment en tst */
RotatePoint
(
&
spot_cX
,
&
spot_cY
,
segm_angle
);
return
(
TestMarginToCircle
(
spot_cX
,
spot_cY
,
seuil
+
p_dimx
,
segm_long
));
}
else
{
/* calcul de la "surface de securite" du pad de reference */
xcliplo
=
spot_cX
-
seuil
-
p_dimx
;
ycliplo
=
spot_cY
-
seuil
-
p_dimy
;
xcliphi
=
spot_cX
+
seuil
+
p_dimx
;
ycliphi
=
spot_cY
+
seuil
+
p_dimy
;
x0
=
y0
=
0
;
xf
=
finx
;
yf
=
finy
;
orient
=
pad_to_test
->
m_Orient
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
-
orient
);
RotatePoint
(
&
xf
,
&
yf
,
spot_cX
,
spot_cY
,
-
orient
);
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
)
;
if
(
bflag
==
OK_DRC
)
return
(
OK_DRC
);
/* Erreur DRC : analyse fine de la forme de la pastille */
switch
(
pad_to_test
->
m_PadShape
)
{
default
:
return
(
BAD_DRC
);
case
OVALE
:
/* test de la pastille ovale ramenee au type ovale vertical */
if
(
p_dimx
>
p_dimy
)
{
EXCHG
(
p_dimx
,
p_dimy
);
orient
+=
900
;
if
(
orient
>=
3600
)
orient
-=
3600
;
}
deltay
=
p_dimy
-
p_dimx
;
/* ici: p_dimx = rayon,
delta = dist centre cercles a centre pad */
/* Test du rectangle separant les 2 demi cercles */
xcliplo
=
spot_cX
-
seuil
-
p_dimx
;
ycliplo
=
spot_cY
-
w_segm
-
deltay
;
xcliphi
=
spot_cX
+
seuil
+
p_dimx
;
ycliphi
=
spot_cY
+
w_segm
+
deltay
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
return
(
BAD_DRC
);
/* test des 2 cercles */
x0
=
spot_cX
;
/* x0,y0 = centre du cercle superieur du pad ovale */
y0
=
spot_cY
+
deltay
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
p_dimx
+
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
return
(
BAD_DRC
);
x0
=
spot_cX
;
/* x0,y0 = centre du cercle inferieur du pad ovale */
y0
=
spot_cY
-
deltay
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
p_dimx
+
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
return
(
BAD_DRC
);
break
;
case
RECT
:
/* 2 rectangle + 4 1/4 cercles a tester */
/* Test du rectangle dimx + seuil, dimy */
xcliplo
=
spot_cX
-
p_dimx
-
seuil
;
ycliplo
=
spot_cY
-
p_dimy
;
xcliphi
=
spot_cX
+
p_dimx
+
seuil
;
ycliphi
=
spot_cY
+
p_dimy
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
/* Test du rectangle dimx , dimy + seuil */
xcliplo
=
spot_cX
-
p_dimx
;
ycliplo
=
spot_cY
-
p_dimy
-
seuil
;
xcliphi
=
spot_cX
+
p_dimx
;
ycliphi
=
spot_cY
+
p_dimy
+
seuil
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
/* test des 4 cercles ( surface d'solation autour des sommets */
/* test du coin sup. gauche du pad */
x0
=
spot_cX
-
p_dimx
;
y0
=
spot_cY
-
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
/* test du coin sup. droit du pad */
x0
=
spot_cX
+
p_dimx
;
y0
=
spot_cY
-
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
/* test du coin inf. gauche du pad */
x0
=
spot_cX
-
p_dimx
;
y0
=
spot_cY
+
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
/* test du coin inf. droit du pad */
x0
=
spot_cX
+
p_dimx
;
y0
=
spot_cY
+
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
(
BAD_DRC
);
}
break
;
}
}
return
(
OK_DRC
)
;
int
p_dimx
,
p_dimy
;
/* demi - dimensions X et Y du pad a controler */
int
bflag
;
int
orient
;
int
x0
,
y0
,
xf
,
yf
;
int
seuil
;
int
deltay
;
seuil
=
w_segm
+
dist_min
;
p_dimx
=
pad_to_test
->
m_Size
.
x
>>
1
;
p_dimy
=
pad_to_test
->
m_Size
.
y
>>
1
;
if
(
pad_to_test
->
m_PadShape
==
CIRCLE
)
{
/* calcul des coord centre du pad dans le repere axe X confondu
* avec le segment en tst */
RotatePoint
(
&
spot_cX
,
&
spot_cY
,
segm_angle
);
return
TestMarginToCircle
(
spot_cX
,
spot_cY
,
seuil
+
p_dimx
,
segm_long
);
}
else
{
/* calcul de la "surface de securite" du pad de reference */
xcliplo
=
spot_cX
-
seuil
-
p_dimx
;
ycliplo
=
spot_cY
-
seuil
-
p_dimy
;
xcliphi
=
spot_cX
+
seuil
+
p_dimx
;
ycliphi
=
spot_cY
+
seuil
+
p_dimy
;
x0
=
y0
=
0
;
xf
=
finx
;
yf
=
finy
;
orient
=
pad_to_test
->
m_Orient
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
-
orient
);
RotatePoint
(
&
xf
,
&
yf
,
spot_cX
,
spot_cY
,
-
orient
);
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
OK_DRC
)
return
OK_DRC
;
/* Erreur DRC : analyse fine de la forme de la pastille */
switch
(
pad_to_test
->
m_PadShape
)
{
default
:
return
BAD_DRC
;
case
OVALE
:
/* test de la pastille ovale ramenee au type ovale vertical */
if
(
p_dimx
>
p_dimy
)
{
EXCHG
(
p_dimx
,
p_dimy
);
orient
+=
900
;
if
(
orient
>=
3600
)
orient
-=
3600
;
}
deltay
=
p_dimy
-
p_dimx
;
/* ici: p_dimx = rayon,
* delta = dist centre cercles a centre pad */
/* Test du rectangle separant les 2 demi cercles */
xcliplo
=
spot_cX
-
seuil
-
p_dimx
;
ycliplo
=
spot_cY
-
w_segm
-
deltay
;
xcliphi
=
spot_cX
+
seuil
+
p_dimx
;
ycliphi
=
spot_cY
+
w_segm
+
deltay
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
return
BAD_DRC
;
/* test des 2 cercles */
x0
=
spot_cX
;
/* x0,y0 = centre du cercle superieur du pad ovale */
y0
=
spot_cY
+
deltay
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
p_dimx
+
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
return
BAD_DRC
;
x0
=
spot_cX
;
/* x0,y0 = centre du cercle inferieur du pad ovale */
y0
=
spot_cY
-
deltay
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
p_dimx
+
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
return
BAD_DRC
;
break
;
case
RECT
:
/* 2 rectangle + 4 1/4 cercles a tester */
/* Test du rectangle dimx + seuil, dimy */
xcliplo
=
spot_cX
-
p_dimx
-
seuil
;
ycliplo
=
spot_cY
-
p_dimy
;
xcliphi
=
spot_cX
+
p_dimx
+
seuil
;
ycliphi
=
spot_cY
+
p_dimy
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
/* Test du rectangle dimx , dimy + seuil */
xcliplo
=
spot_cX
-
p_dimx
;
ycliplo
=
spot_cY
-
p_dimy
-
seuil
;
xcliphi
=
spot_cX
+
p_dimx
;
ycliphi
=
spot_cY
+
p_dimy
+
seuil
;
bflag
=
Tst_Ligne
(
x0
,
y0
,
xf
,
yf
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
/* test des 4 cercles ( surface d'solation autour des sommets */
/* test du coin sup. gauche du pad */
x0
=
spot_cX
-
p_dimx
;
y0
=
spot_cY
-
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
/* test du coin sup. droit du pad */
x0
=
spot_cX
+
p_dimx
;
y0
=
spot_cY
-
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
/* test du coin inf. gauche du pad */
x0
=
spot_cX
-
p_dimx
;
y0
=
spot_cY
+
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
/* test du coin inf. droit du pad */
x0
=
spot_cX
+
p_dimx
;
y0
=
spot_cY
+
p_dimy
;
RotatePoint
(
&
x0
,
&
y0
,
spot_cX
,
spot_cY
,
orient
);
RotatePoint
(
&
x0
,
&
y0
,
segm_angle
);
bflag
=
TestMarginToCircle
(
x0
,
y0
,
seuil
,
segm_long
);
if
(
bflag
==
BAD_DRC
)
{
return
BAD_DRC
;
}
break
;
}
}
return
OK_DRC
;
}
/*******************************************************************/
static
int
TestMarginToCircle
(
int
cx
,
int
cy
,
int
rayon
,
int
longueur
)
static
int
TestMarginToCircle
(
int
cx
,
int
cy
,
int
rayon
,
int
longueur
)
/*******************************************************************/
/*
Routine analogue a TestClearanceSegmToPad.
Calcul de la distance d'un cercle (via ronde, extremite de piste)
au segment de droite en cours de controle (segment de reference dans
son repere )
parametres:
cx, cy: centre du cercle (surface ronde) a tester, dans le repere
segment de reference
rayon = rayon du cercle
longueur = longueur du segment dans son repere (i.e. coord de fin)
retourne:
OK_DRC si distance >= rayon
BAD_DRC si distance < rayon
*/
*
Routine analogue a TestClearanceSegmToPad.
*
Calcul de la distance d'un cercle (via ronde, extremite de piste)
*
au segment de droite en cours de controle (segment de reference dans
*
son repere )
*
parametres:
*
cx, cy: centre du cercle (surface ronde) a tester, dans le repere
*
segment de reference
*
rayon = rayon du cercle
*
longueur = longueur du segment dans son repere (i.e. coord de fin)
*
retourne:
*
OK_DRC si distance >= rayon
*
BAD_DRC si distance < rayon
*/
{
if
(
abs
(
cy
)
>
rayon
)
return
(
OK_DRC
);
if
(
(
cx
>=
-
rayon
)
&&
(
cx
<=
(
longueur
+
rayon
)
)
)
{
if
(
(
cx
>=
0
)
&&
(
cx
<=
longueur
)
)
return
(
BAD_DRC
)
;
if
(
cx
>
longueur
)
cx
-=
longueur
;
if
(
hypot
((
double
)
cx
,
(
double
)
cy
)
<
rayon
)
return
(
BAD_DRC
);
}
return
(
OK_DRC
)
;
if
(
abs
(
cy
)
>
rayon
)
return
OK_DRC
;
if
(
(
cx
>=
-
rayon
)
&&
(
cx
<=
(
longueur
+
rayon
)
)
)
{
if
(
(
cx
>=
0
)
&&
(
cx
<=
longueur
)
)
return
BAD_DRC
;
if
(
cx
>
longueur
)
cx
-=
longueur
;
if
(
hypot
(
(
double
)
cx
,
(
double
)
cy
)
<
rayon
)
return
BAD_DRC
;
}
return
OK_DRC
;
}
/******************************************************************************/
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
TRACK
*
pt_ref
,
void
*
pt_item
,
int
errnumber
)
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
TRACK
*
pt_ref
,
void
*
pt_item
,
int
errnumber
)
/******************************************************************************/
/* affiche les erreurs de DRC :
Message d'erreur
+
Marqueur
number = numero d'identification
*/
*
Message d'erreur
+
*
Marqueur
*
number = numero d'identification
*/
{
wxPoint
erc_pos
;
TRACK
*
pt_segm
;
wxString
msg
;
wxString
tracktype
,
netname1
,
netname2
;
EQUIPOT
*
equipot
=
GetEquipot
(
Pcb
,
pt_ref
->
m_NetCode
);
if
(
equipot
)
netname1
=
equipot
->
m_Netname
;
else
netname1
=
wxT
(
"<noname>"
);
netname2
=
wxT
(
"<noname>"
);
tracktype
=
wxT
(
"Track"
);
if
(
pt_ref
->
m_StructType
==
TYPEVIA
)
tracktype
=
wxT
(
"Via"
);
if
(
pt_ref
->
m_StructType
==
TYPEZONE
)
tracktype
=
wxT
(
"Zone"
);
if
(
((
EDA_BaseStruct
*
)
pt_item
)
->
m_StructType
==
TYPEPAD
)
{
D_PAD
*
pad
=
(
D_PAD
*
)
pt_item
;
equipot
=
GetEquipot
(
Pcb
,
pad
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
erc_pos
=
pad
->
m_Pos
;
wxString
pad_name
=
pad
->
ReturnStringPadName
();
wxString
module_name
=
((
MODULE
*
)(
pad
->
m_Parent
))
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"%d Drc Err %d %s (net %s)and PAD %s (%s) net %s @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
pad_name
.
GetData
(),
module_name
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
else
/* erreur sur segment de piste */
{
pt_segm
=
(
TRACK
*
)
pt_item
;
equipot
=
GetEquipot
(
Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
erc_pos
=
pt_segm
->
m_Start
;
if
(
pt_segm
->
m_StructType
==
TYPEVIA
)
{
msg
.
Printf
(
_
(
"%d Err type %d: %s (net %s) and VIA (net %s) @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
else
{
wxPoint
erc_pos_f
=
pt_segm
->
m_End
;
if
(
hypot
(
(
double
)(
erc_pos_f
.
x
-
pt_ref
->
m_End
.
x
),(
double
)(
erc_pos_f
.
y
-
pt_ref
->
m_End
.
y
)
)
<
hypot
(
(
double
)(
erc_pos
.
x
-
pt_ref
->
m_End
.
x
),(
double
)(
erc_pos
.
y
-
pt_ref
->
m_End
.
y
)
)
)
{
EXCHG
(
erc_pos_f
.
x
,
erc_pos
.
x
);
EXCHG
(
erc_pos_f
.
y
,
erc_pos
.
y
);
}
msg
.
Printf
(
_
(
"%d Err type %d: %s (net %s) and track (net %s) @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
}
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
msg
);
else
panel
->
m_Parent
->
Affiche_Message
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
current_marqueur
==
NULL
)
current_marqueur
=
new
MARQUEUR
(
Pcb
);
current_marqueur
->
m_Pos
=
wxPoint
(
erc_pos
.
x
,
erc_pos
.
y
);
current_marqueur
->
m_Color
=
WHITE
;
current_marqueur
->
m_Diag
=
msg
;
current_marqueur
->
Draw
(
panel
,
DC
,
GR_OR
);
wxPoint
erc_pos
;
TRACK
*
pt_segm
;
wxString
msg
;
wxString
tracktype
,
netname1
,
netname2
;
EQUIPOT
*
equipot
=
GetEquipot
(
Pcb
,
pt_ref
->
m_NetCode
);
if
(
equipot
)
netname1
=
equipot
->
m_Netname
;
else
netname1
=
wxT
(
"<noname>"
);
netname2
=
wxT
(
"<noname>"
);
tracktype
=
wxT
(
"Track"
);
if
(
pt_ref
->
m_StructType
==
TYPEVIA
)
tracktype
=
wxT
(
"Via"
);
if
(
pt_ref
->
m_StructType
==
TYPEZONE
)
tracktype
=
wxT
(
"Zone"
);
if
(
(
(
EDA_BaseStruct
*
)
pt_item
)
->
m_StructType
==
TYPEPAD
)
{
D_PAD
*
pad
=
(
D_PAD
*
)
pt_item
;
equipot
=
GetEquipot
(
Pcb
,
pad
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
erc_pos
=
pad
->
m_Pos
;
wxString
pad_name
=
pad
->
ReturnStringPadName
();
wxString
module_name
=
(
(
MODULE
*
)
(
pad
->
m_Parent
)
)
->
m_Reference
->
m_Text
;
msg
.
Printf
(
_
(
"%d Drc Err %d %s (net %s)and PAD %s (%s) net %s @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
pad_name
.
GetData
(),
module_name
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
else
/* erreur sur segment de piste */
{
pt_segm
=
(
TRACK
*
)
pt_item
;
equipot
=
GetEquipot
(
Pcb
,
pt_segm
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
erc_pos
=
pt_segm
->
m_Start
;
if
(
pt_segm
->
m_StructType
==
TYPEVIA
)
{
msg
.
Printf
(
_
(
"%d Err type %d: %s (net %s) and VIA (net %s) @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
else
{
wxPoint
erc_pos_f
=
pt_segm
->
m_End
;
if
(
hypot
(
(
double
)
(
erc_pos_f
.
x
-
pt_ref
->
m_End
.
x
),
(
double
)
(
erc_pos_f
.
y
-
pt_ref
->
m_End
.
y
)
)
<
hypot
(
(
double
)
(
erc_pos
.
x
-
pt_ref
->
m_End
.
x
),
(
double
)
(
erc_pos
.
y
-
pt_ref
->
m_End
.
y
)
)
)
{
EXCHG
(
erc_pos_f
.
x
,
erc_pos
.
x
);
EXCHG
(
erc_pos_f
.
y
,
erc_pos
.
y
);
}
msg
.
Printf
(
_
(
"%d Err type %d: %s (net %s) and track (net %s) @ %d,%d
\n
"
),
ErrorsDRC_Count
,
errnumber
,
tracktype
.
GetData
(),
netname1
.
GetData
(),
netname2
.
GetData
(),
erc_pos
.
x
,
erc_pos
.
y
);
}
}
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
msg
);
else
panel
->
m_Parent
->
Affiche_Message
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
current_marqueur
==
NULL
)
current_marqueur
=
new
MARQUEUR
(
Pcb
);
current_marqueur
->
m_Pos
=
wxPoint
(
erc_pos
.
x
,
erc_pos
.
y
);
current_marqueur
->
m_Color
=
WHITE
;
current_marqueur
->
m_Diag
=
msg
;
current_marqueur
->
Draw
(
panel
,
DC
,
GR_OR
);
}
/******************************************************************************/
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
D_PAD
*
pad1
,
D_PAD
*
pad2
)
static
void
Affiche_Erreur_DRC
(
WinEDA_DrawPanel
*
panel
,
wxDC
*
DC
,
BOARD
*
Pcb
,
D_PAD
*
pad1
,
D_PAD
*
pad2
)
/******************************************************************************/
/* affiche les erreurs de DRC :
Message d'erreur
+
Marqueur
number = numero d'identification
*/
*
Message d'erreur
+
*
Marqueur
*
number = numero d'identification
*/
{
wxString
msg
;
wxString
pad_name1
=
pad1
->
ReturnStringPadName
();
wxString
module_name1
=
((
MODULE
*
)(
pad1
->
m_Parent
))
->
m_Reference
->
m_Text
;
wxString
pad_name2
=
pad2
->
ReturnStringPadName
();
wxString
module_name2
=
((
MODULE
*
)(
pad2
->
m_Parent
))
->
m_Reference
->
m_Text
;
wxString
netname1
,
netname2
;
EQUIPOT
*
equipot
=
GetEquipot
(
Pcb
,
pad1
->
m_NetCode
);
if
(
equipot
)
netname1
=
equipot
->
m_Netname
;
else
netname1
=
wxT
(
"<noname>"
);
equipot
=
GetEquipot
(
Pcb
,
pad2
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
else
netname2
=
wxT
(
"<noname>"
);
msg
.
Printf
(
_
(
"%d Drc Err: PAD %s (%s) net %s @ %d,%d and PAD %s (%s) net %s @ %d,%d
\n
"
),
ErrorsDRC_Count
,
pad_name1
.
GetData
(),
module_name1
.
GetData
(),
netname1
.
GetData
(),
pad1
->
m_Pos
.
x
,
pad1
->
m_Pos
.
y
,
pad_name2
.
GetData
(),
module_name2
.
GetData
(),
netname2
.
GetData
(),
pad2
->
m_Pos
.
x
,
pad2
->
m_Pos
.
y
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
msg
);
else
panel
->
m_Parent
->
Affiche_Message
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
current_marqueur
==
NULL
)
current_marqueur
=
new
MARQUEUR
(
Pcb
);
current_marqueur
->
m_Pos
=
pad1
->
m_Pos
;
current_marqueur
->
m_Color
=
WHITE
;
current_marqueur
->
m_Diag
=
msg
;
current_marqueur
->
Draw
(
panel
,
DC
,
GR_OR
);
wxString
msg
;
wxString
pad_name1
=
pad1
->
ReturnStringPadName
();
wxString
module_name1
=
(
(
MODULE
*
)
(
pad1
->
m_Parent
)
)
->
m_Reference
->
m_Text
;
wxString
pad_name2
=
pad2
->
ReturnStringPadName
();
wxString
module_name2
=
(
(
MODULE
*
)
(
pad2
->
m_Parent
)
)
->
m_Reference
->
m_Text
;
wxString
netname1
,
netname2
;
EQUIPOT
*
equipot
=
GetEquipot
(
Pcb
,
pad1
->
m_NetCode
);
if
(
equipot
)
netname1
=
equipot
->
m_Netname
;
else
netname1
=
wxT
(
"<noname>"
);
equipot
=
GetEquipot
(
Pcb
,
pad2
->
m_NetCode
);
if
(
equipot
)
netname2
=
equipot
->
m_Netname
;
else
netname2
=
wxT
(
"<noname>"
);
msg
.
Printf
(
_
(
"%d Drc Err: PAD %s (%s) net %s @ %d,%d and PAD %s (%s) net %s @ %d,%d
\n
"
),
ErrorsDRC_Count
,
pad_name1
.
GetData
(),
module_name1
.
GetData
(),
netname1
.
GetData
(),
pad1
->
m_Pos
.
x
,
pad1
->
m_Pos
.
y
,
pad_name2
.
GetData
(),
module_name2
.
GetData
(),
netname2
.
GetData
(),
pad2
->
m_Pos
.
x
,
pad2
->
m_Pos
.
y
);
if
(
DrcFrame
)
DrcFrame
->
m_logWindow
->
AppendText
(
msg
);
else
panel
->
m_Parent
->
Affiche_Message
(
msg
);
if
(
s_RptFile
)
fprintf
(
s_RptFile
,
"%s"
,
CONV_TO_UTF8
(
msg
)
);
if
(
current_marqueur
==
NULL
)
current_marqueur
=
new
MARQUEUR
(
Pcb
);
current_marqueur
->
m_Pos
=
pad1
->
m_Pos
;
current_marqueur
->
m_Color
=
WHITE
;
current_marqueur
->
m_Diag
=
msg
;
current_marqueur
->
Draw
(
panel
,
DC
,
GR_OR
);
}
/**********************************************/
/* int Tst_Ligne(int x1,int y1,int x2,int y2) */
/**********************************************/
/**********************************************/
/* int Tst_Ligne(int x1,int y1,int x2,int y2) */
/**********************************************/
/* Routine utilisee pour tester si une piste est en contact avec une autre piste.
Cette routine controle si la ligne (x1,y1 x2,y2) a une partie s'inscrivant
dans le cadre (xcliplo,ycliplo xcliphi,ycliphi) (variables globales,
locales a ce fichier)
Retourne OK_DRC si aucune partie commune
Retourne BAD_DRC si partie commune
*/
*
*
Cette routine controle si la ligne (x1,y1 x2,y2) a une partie s'inscrivant
*
dans le cadre (xcliplo,ycliplo xcliphi,ycliphi) (variables globales,
*
locales a ce fichier)
*
*
Retourne OK_DRC si aucune partie commune
*
Retourne BAD_DRC si partie commune
*/
#define us unsigned int
static
inline
int
USCALE
(
us
arg
,
us
num
,
us
den
)
{
int
ii
;
static
inline
int
USCALE
(
us
arg
,
us
num
,
us
den
)
{
int
ii
;
ii
=
(
int
)
(
(
(
float
)
arg
*
num
)
/
den
);
return
ii
;
}
ii
=
(
int
)(
((
float
)
arg
*
num
)
/
den
);
return
(
ii
);
}
#define WHEN_OUTSIDE return(OK_DRC)
#define WHEN_OUTSIDE return
(OK_DRC)
#define WHEN_INSIDE
static
int
Tst_Ligne
(
int
x1
,
int
y1
,
int
x2
,
int
y2
)
static
int
Tst_Ligne
(
int
x1
,
int
y1
,
int
x2
,
int
y2
)
{
int
temp
;
do
{
if
(
x1
>
x2
)
{
EXCHG
(
x1
,
x2
);
EXCHG
(
y1
,
y2
);
}
if
((
x2
<
xcliplo
)
||
(
x1
>
xcliphi
))
{
WHEN_OUTSIDE
;
}
if
(
y1
<
y2
)
{
if
((
y2
<
ycliplo
)
||
(
y1
>
ycliphi
))
{
WHEN_OUTSIDE
;}
if
(
y1
<
ycliplo
)
{
temp
=
USCALE
((
x2
-
x1
),(
ycliplo
-
y1
),(
y2
-
y1
));
if
((
x1
+=
temp
)
>
xcliphi
)
{
WHEN_OUTSIDE
;
}
y1
=
ycliplo
;
WHEN_INSIDE
;
}
if
(
y2
>
ycliphi
)
{
temp
=
USCALE
((
x2
-
x1
),(
y2
-
ycliphi
),(
y2
-
y1
));
if
((
x2
-=
temp
)
<
xcliplo
)
{
WHEN_OUTSIDE
;
}
y2
=
ycliphi
;
WHEN_INSIDE
;
}
if
(
x1
<
xcliplo
)
{
temp
=
USCALE
((
y2
-
y1
),(
xcliplo
-
x1
),(
x2
-
x1
));
y1
+=
temp
;
x1
=
xcliplo
;
WHEN_INSIDE
;
}
if
(
x2
>
xcliphi
)
{
temp
=
USCALE
((
y2
-
y1
),(
x2
-
xcliphi
),(
x2
-
x1
));
y2
-=
temp
;
x2
=
xcliphi
;
WHEN_INSIDE
;
}
}
else
{
if
((
y1
<
ycliplo
)
||
(
y2
>
ycliphi
))
{
WHEN_OUTSIDE
;
}
if
(
y1
>
ycliphi
)
{
temp
=
USCALE
((
x2
-
x1
),(
y1
-
ycliphi
),(
y1
-
y2
));
if
((
x1
+=
temp
)
>
xcliphi
)
{
WHEN_OUTSIDE
;
}
y1
=
ycliphi
;
WHEN_INSIDE
;
}
if
(
y2
<
ycliplo
)
{
temp
=
USCALE
((
x2
-
x1
),(
ycliplo
-
y2
),(
y1
-
y2
));
if
((
x2
-=
temp
)
<
xcliplo
)
{
WHEN_OUTSIDE
;
}
y2
=
ycliplo
;
WHEN_INSIDE
;
}
if
(
x1
<
xcliplo
)
{
temp
=
USCALE
((
y1
-
y2
),(
xcliplo
-
x1
),(
x2
-
x1
));
y1
-=
temp
;
x1
=
xcliplo
;
WHEN_INSIDE
;
}
if
(
x2
>
xcliphi
)
{
temp
=
USCALE
((
y1
-
y2
),(
x2
-
xcliphi
),(
x2
-
x1
));
y2
+=
temp
;
x2
=
xcliphi
;
WHEN_INSIDE
;
}
}
}
while
(
0
);
if
(
((
x2
+
x1
)
/
2
<=
xcliphi
)
&&
((
x2
+
x1
)
/
2
>=
xcliplo
)
\
&&
((
y2
+
y1
)
/
2
<=
ycliphi
)
&&
((
y2
+
y1
)
/
2
>=
ycliplo
)
)
{
return
(
BAD_DRC
)
;
}
else
return
(
OK_DRC
);
int
temp
;
do
{
if
(
x1
>
x2
)
{
EXCHG
(
x1
,
x2
);
EXCHG
(
y1
,
y2
);
}
if
(
(
x2
<
xcliplo
)
||
(
x1
>
xcliphi
)
)
{
WHEN_OUTSIDE
;
}
if
(
y1
<
y2
)
{
if
(
(
y2
<
ycliplo
)
||
(
y1
>
ycliphi
)
)
{
WHEN_OUTSIDE
;
}
if
(
y1
<
ycliplo
)
{
temp
=
USCALE
(
(
x2
-
x1
),
(
ycliplo
-
y1
),
(
y2
-
y1
)
);
if
(
(
x1
+=
temp
)
>
xcliphi
)
{
WHEN_OUTSIDE
;
}
y1
=
ycliplo
;
WHEN_INSIDE
;
}
if
(
y2
>
ycliphi
)
{
temp
=
USCALE
(
(
x2
-
x1
),
(
y2
-
ycliphi
),
(
y2
-
y1
)
);
if
(
(
x2
-=
temp
)
<
xcliplo
)
{
WHEN_OUTSIDE
;
}
y2
=
ycliphi
;
WHEN_INSIDE
;
}
if
(
x1
<
xcliplo
)
{
temp
=
USCALE
(
(
y2
-
y1
),
(
xcliplo
-
x1
),
(
x2
-
x1
)
);
y1
+=
temp
;
x1
=
xcliplo
;
WHEN_INSIDE
;
}
if
(
x2
>
xcliphi
)
{
temp
=
USCALE
(
(
y2
-
y1
),
(
x2
-
xcliphi
),
(
x2
-
x1
)
);
y2
-=
temp
;
x2
=
xcliphi
;
WHEN_INSIDE
;
}
}
else
{
if
(
(
y1
<
ycliplo
)
||
(
y2
>
ycliphi
)
)
{
WHEN_OUTSIDE
;
}
if
(
y1
>
ycliphi
)
{
temp
=
USCALE
(
(
x2
-
x1
),
(
y1
-
ycliphi
),
(
y1
-
y2
)
);
if
(
(
x1
+=
temp
)
>
xcliphi
)
{
WHEN_OUTSIDE
;
}
y1
=
ycliphi
;
WHEN_INSIDE
;
}
if
(
y2
<
ycliplo
)
{
temp
=
USCALE
(
(
x2
-
x1
),
(
ycliplo
-
y2
),
(
y1
-
y2
)
);
if
(
(
x2
-=
temp
)
<
xcliplo
)
{
WHEN_OUTSIDE
;
}
y2
=
ycliplo
;
WHEN_INSIDE
;
}
if
(
x1
<
xcliplo
)
{
temp
=
USCALE
(
(
y1
-
y2
),
(
xcliplo
-
x1
),
(
x2
-
x1
)
);
y1
-=
temp
;
x1
=
xcliplo
;
WHEN_INSIDE
;
}
if
(
x2
>
xcliphi
)
{
temp
=
USCALE
(
(
y1
-
y2
),
(
x2
-
xcliphi
),
(
x2
-
x1
)
);
y2
+=
temp
;
x2
=
xcliphi
;
WHEN_INSIDE
;
}
}
}
while
(
0
);
if
(
(
(
x2
+
x1
)
/
2
<=
xcliphi
)
&&
(
(
x2
+
x1
)
/
2
>=
xcliplo
)
\
&&
(
(
y2
+
y1
)
/
2
<=
ycliphi
)
&&
(
(
y2
+
y1
)
/
2
>=
ycliplo
)
)
{
return
BAD_DRC
;
}
else
return
OK_DRC
;
}
pcbnew/edit.cpp
View file @
c1e3416a
...
...
@@ -128,8 +128,7 @@ void WinEDA_PcbFrame::OnLeftClick( wxDC* DC, const wxPoint& MousePos )
#if defined(DEBUG)
DrawStruct
=
m_Pcb
->
FindPadOrModule
(
GetScreen
()
->
RefPos
(
true
),
GetScreen
()
->
m_Active_Layer
,
VISIBLE_ONLY
);
GetScreen
()
->
m_Active_Layer
);
#else
DrawStruct
=
PcbGeneralLocateAndDisplay
();
#endif
...
...
pcbnew/locate.cpp
View file @
c1e3416a
...
...
@@ -13,10 +13,7 @@
#include "protos.h"
/* variables locales */
int
ux0
,
uy0
,
dx
,
dy
,
spot_cX
,
spot_cY
;
/* Variables utilisees pour
* la localisation des segments */
/* fonctions locales */
EDA_BaseStruct
*
Locate_MirePcb
(
EDA_BaseStruct
*
PtStruct
,
int
LayerSearch
,
int
typeloc
);
...
...
@@ -302,72 +299,21 @@ EDGE_MODULE* Locate_Edge_Module( MODULE* module, int typeloc )
* NULL si rien trouve
*/
{
EDGE_MODULE
*
edge_mod
;
EDA_BaseStruct
*
PtStruct
;
int
uxf
,
uyf
,
type_trace
;
int
rayon
,
dist
;
wxPoint
ref_pos
;
/* coord du point de localisation */
/* pour localisation d'arcs, angle du point de debut, de fin et du point de reference */
int
StAngle
,
EndAngle
,
MouseAngle
;
if
(
!
module
)
return
NULL
;
ref_pos
=
RefPos
(
typeloc
);
/* coord du point de localisation */
wxPoint
ref_pos
=
RefPos
(
typeloc
);
PtStruct
=
module
->
m_Drawings
;
for
(
;
PtStruct
!=
NULL
;
PtStruct
=
PtStruct
->
Pnext
)
EDA_BaseStruct
*
PtStruct
=
module
->
m_Drawings
;
for
(
;
PtStruct
!=
NULL
;
PtStruct
=
PtStruct
->
Pnext
)
{
if
(
PtStruct
->
m_StructType
!=
TYPEEDGEMODULE
)
continue
;
edge_mod
=
(
EDGE_MODULE
*
)
PtStruct
;
type_trace
=
edge_mod
->
m_Shape
;
ux0
=
edge_mod
->
m_Start
.
x
;
uy0
=
edge_mod
->
m_Start
.
y
;
uxf
=
edge_mod
->
m_End
.
x
;
uyf
=
edge_mod
->
m_End
.
y
;
switch
(
type_trace
)
{
case
S_SEGMENT
:
/* recalcul des coordonnees avec ux0,uy0 = origine des coord. */
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
dx
=
uxf
-
ux0
;
dy
=
uyf
-
uy0
;
/* detection : */
if
(
distance
(
edge_mod
->
m_Width
/
2
)
)
return
edge_mod
;
break
;
case
S_CIRCLE
:
rayon
=
(
int
)
hypot
(
(
double
)
(
uxf
-
ux0
),
(
double
)
(
uyf
-
uy0
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
ref_pos
.
x
-
ux0
),
(
double
)
(
ref_pos
.
y
-
uy0
)
);
if
(
abs
(
rayon
-
dist
)
<=
edge_mod
->
m_Width
)
return
edge_mod
;
break
;
case
S_ARC
:
rayon
=
(
int
)
hypot
(
(
double
)
(
uxf
-
ux0
),
(
double
)
(
uyf
-
uy0
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
ref_pos
.
x
-
ux0
),
(
double
)
(
ref_pos
.
y
-
uy0
)
);
if
(
abs
(
rayon
-
dist
)
>
edge_mod
->
m_Width
)
break
;
/* pour un arc, controle complementaire */
MouseAngle
=
(
int
)
ArcTangente
(
ref_pos
.
y
-
uy0
,
ref_pos
.
x
-
ux0
);
StAngle
=
(
int
)
ArcTangente
(
uyf
-
uy0
,
uxf
-
ux0
);
EndAngle
=
StAngle
+
edge_mod
->
m_Angle
;
if
(
EndAngle
>
3600
)
{
StAngle
-=
3600
;
EndAngle
-=
3600
;
}
if
(
(
MouseAngle
>=
StAngle
)
&&
(
MouseAngle
<=
EndAngle
)
)
return
edge_mod
;
break
;
}
// calls virtual EDGE_MODULE::HitTest()
if
(
PtStruct
->
HitTest
(
ref_pos
)
)
return
(
EDGE_MODULE
*
)
PtStruct
;
}
return
NULL
;
...
...
@@ -383,105 +329,17 @@ EDA_BaseStruct* Locate_Cotation( BOARD* Pcb, int LayerSearch, int typeloc )
* return a pointer to the located item, or NULL
*/
{
EDA_BaseStruct
*
PtStruct
;
COTATION
*
Cotation
;
TEXTE_PCB
*
pt_txt
;
wxPoint
ref_pos
;
int
ux0
,
uy0
;
wxPoint
ref_pos
=
RefPos
(
typeloc
);
ref_pos
=
RefPos
(
typeloc
);
PtStruct
=
Pcb
->
m_Drawings
;
EDA_BaseStruct
*
PtStruct
=
Pcb
->
m_Drawings
;
for
(
;
PtStruct
!=
NULL
;
PtStruct
=
PtStruct
->
Pnext
)
{
if
(
PtStruct
->
m_StructType
!=
TYPECOTATION
)
continue
;
Cotation
=
(
COTATION
*
)
PtStruct
;
if
(
(
Cotation
->
m_Layer
!=
LayerSearch
)
&&
(
LayerSearch
!=
-
1
)
)
continue
;
/* Localisation du texte ? */
pt_txt
=
Cotation
->
m_Text
;
if
(
pt_txt
)
{
// because HitTest() is present in both base classes of TEXTE_PCB
// use a dis-ambiguating cast to tell compiler which HitTest()
// to call.
if
(
static_cast
<
EDA_TextStruct
*>
(
pt_txt
)
->
HitTest
(
ref_pos
)
)
return
PtStruct
;
}
/* Localisation des SEGMENTS ?) */
ux0
=
Cotation
->
Barre_ox
;
uy0
=
Cotation
->
Barre_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
Barre_fx
-
ux0
;
dy
=
Cotation
->
Barre_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
TraitG_ox
;
uy0
=
Cotation
->
TraitG_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
TraitG_fx
-
ux0
;
dy
=
Cotation
->
TraitG_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
TraitD_ox
;
uy0
=
Cotation
->
TraitD_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
TraitD_fx
-
ux0
;
dy
=
Cotation
->
TraitD_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
FlecheD1_ox
;
uy0
=
Cotation
->
FlecheD1_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
FlecheD1_fx
-
ux0
;
dy
=
Cotation
->
FlecheD1_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
FlecheD2_ox
;
uy0
=
Cotation
->
FlecheD2_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
FlecheD2_fx
-
ux0
;
dy
=
Cotation
->
FlecheD2_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
FlecheG1_ox
;
uy0
=
Cotation
->
FlecheG1_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
FlecheG1_fx
-
ux0
;
dy
=
Cotation
->
FlecheG1_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
ux0
=
Cotation
->
FlecheG2_ox
;
uy0
=
Cotation
->
FlecheG2_oy
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
Cotation
->
FlecheG2_fx
-
ux0
;
dy
=
Cotation
->
FlecheG2_fy
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
/* detection : */
if
(
distance
(
Cotation
->
m_Width
/
2
)
)
return
PtStruct
;
// calls virtual COTATION::HitTest()
if
(
PtStruct
->
HitTest
(
ref_pos
)
)
return
(
COTATION
*
)
PtStruct
;
}
return
NULL
;
...
...
@@ -499,73 +357,32 @@ DRAWSEGMENT* Locate_Segment_Pcb( BOARD* Pcb, int LayerSearch, int typeloc )
* Le segment sur la couche active est dtect en priorite
*/
{
EDA_BaseStruct
*
PtStruct
;
DRAWSEGMENT
*
pts
,
*
locate_segm
=
NULL
;
wxPoint
ref_pos
;
PCB_SCREEN
*
screen
=
(
PCB_SCREEN
*
)
ActiveScreen
;
ref_pos
=
RefPos
(
typeloc
);
DRAWSEGMENT
*
locate_segm
=
NULL
;
PCB_SCREEN
*
screen
=
(
PCB_SCREEN
*
)
ActiveScreen
;
wxPoint
ref_pos
=
RefPos
(
typeloc
);
PtStruct
=
Pcb
->
m_Drawings
;
EDA_BaseStruct
*
PtStruct
=
Pcb
->
m_Drawings
;
for
(
;
PtStruct
!=
NULL
;
PtStruct
=
PtStruct
->
Pnext
)
{
if
(
PtStruct
->
m_StructType
!=
TYPEDRAWSEGMENT
)
continue
;
pts
=
(
DRAWSEGMENT
*
)
PtStruct
;
if
(
(
pts
->
m_Layer
!=
LayerSearch
)
&&
(
LayerSearch
!=
-
1
)
)
continue
;
ux0
=
pts
->
m_Start
.
x
;
uy0
=
pts
->
m_Start
.
y
;
DRAWSEGMENT
*
pts
=
(
DRAWSEGMENT
*
)
PtStruct
;
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
=
pts
->
m_End
.
x
-
ux0
;
dy
=
pts
->
m_End
.
y
-
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
(
pts
->
m_Layer
!=
LayerSearch
)
&&
(
LayerSearch
!=
-
1
)
)
continue
;
/* detection : */
if
(
(
pts
->
m_Shape
==
S_CIRCLE
)
||
(
pts
->
m_Shape
==
S_ARC
)
)
if
(
pts
->
HitTest
(
ref_pos
)
)
{
int
rayon
,
dist
,
StAngle
,
EndAngle
,
MouseAngle
;
rayon
=
(
int
)
hypot
(
(
double
)
(
dx
),
(
double
)
(
dy
)
);
dist
=
(
int
)
hypot
(
(
double
)
(
spot_cX
),
(
double
)
(
spot_cY
)
);
if
(
abs
(
rayon
-
dist
)
<=
(
pts
->
m_Width
/
2
)
)
{
if
(
pts
->
m_Shape
==
S_CIRCLE
)
{
if
(
pts
->
m_Layer
==
screen
->
m_Active_Layer
)
return
pts
;
else
if
(
!
locate_segm
)
locate_segm
=
pts
;
}
// return this hit if layer matches, else remember in
// case no layer match is found.
if
(
pts
->
m_Layer
==
screen
->
m_Active_Layer
)
return
pts
;
/* pour un arc, controle complementaire */
MouseAngle
=
(
int
)
ArcTangente
(
spot_cY
,
spot_cX
);
StAngle
=
(
int
)
ArcTangente
(
dy
,
dx
);
EndAngle
=
StAngle
+
pts
->
m_Angle
;
if
(
EndAngle
>
3600
)
{
StAngle
-=
3600
;
EndAngle
-=
3600
;
}
if
(
(
MouseAngle
>=
StAngle
)
&&
(
MouseAngle
<=
EndAngle
)
)
{
if
(
pts
->
m_Layer
==
screen
->
m_Active_Layer
)
return
pts
;
else
if
(
!
locate_segm
)
locate_segm
=
pts
;
}
}
}
else
{
if
(
distance
(
pts
->
m_Width
/
2
)
)
{
if
(
pts
->
m_Layer
==
screen
->
m_Active_Layer
)
return
pts
;
else
if
(
!
locate_segm
)
locate_segm
=
pts
;
}
else
if
(
!
locate_segm
)
locate_segm
=
pts
;
}
}
...
...
@@ -651,14 +468,6 @@ D_PAD* Locate_Pads( MODULE* module, const wxPoint& ref_pos, int masque_layer )
D_PAD
*
pt_pad
=
module
->
m_Pads
;
for
(
;
pt_pad
!=
NULL
;
pt_pad
=
(
D_PAD
*
)
pt_pad
->
Pnext
)
{
/*
wxPoint shape_pos = ReturnShapePos();
why the global ux0?
ux0 = shape_pos.x;
uy0 = shape_pos.y; // pos x,y du centre du pad
*/
/* ... et sur la bonne couche */
if
(
(
pt_pad
->
m_Masque_Layer
&
masque_layer
)
==
0
)
continue
;
...
...
@@ -704,8 +513,6 @@ MODULE* Locate_Prefered_Module( BOARD* Pcb, int typeloc )
if
(
(
typeloc
&
IGNORE_LOCKED
)
&&
pt_module
->
IsLocked
()
)
continue
;
/* Localisation: test des dimensions minimales, choix du meilleur candidat */
/* calcul de priorite: la priorite est donnee a la couche
* d'appartenance du module et a la couche cuivre si le module
* est sur couche serigr,adhesive cuivre, a la couche cmp si le module
...
...
@@ -718,6 +525,8 @@ MODULE* Locate_Prefered_Module( BOARD* Pcb, int typeloc )
else
if
(
layer
==
ADHESIVE_N_CMP
||
layer
==
SILKSCREEN_N_CMP
)
layer
=
CMP_N
;
/* Localisation: test des dimensions minimales, choix du meilleur candidat */
/* calcul des dimensions du cadre :*/
lx
=
pt_module
->
m_BoundaryBox
.
GetWidth
();
ly
=
pt_module
->
m_BoundaryBox
.
GetHeight
();
...
...
@@ -998,42 +807,30 @@ TRACK* Locate_Pistes( TRACK* start_adresse, int MasqueLayer, int typeloc )
TRACK
*
Locate_Pistes
(
TRACK
*
start_adresse
,
const
wxPoint
&
ref_pos
,
int
MasqueLayer
)
{
TRACK
*
Track
;
/* pointeur sur les pistes */
int
l_piste
;
/* demi-largeur de la piste */
for
(
Track
=
start_adresse
;
Track
!=
NULL
;
Track
=
(
TRACK
*
)
Track
->
Pnext
)
for
(
TRACK
*
Track
=
start_adresse
;
Track
;
Track
=
(
TRACK
*
)
Track
->
Pnext
)
{
if
(
Track
->
GetState
(
BUSY
|
DELETED
)
)
continue
;
if
(
(
g_DesignSettings
.
m_LayerColor
[
Track
->
m_Layer
]
&
ITEM_NOT_SHOW
)
)
continue
;
/* calcul des coordonnees du segment teste */
l_piste
=
Track
->
m_Width
>>
1
;
/* l_piste = demi largeur piste */
ux0
=
Track
->
m_Start
.
x
;
uy0
=
Track
->
m_Start
.
y
;
/* coord de depart */
dx
=
Track
->
m_End
.
x
;
dy
=
Track
->
m_End
.
y
;
/* coord d'arrivee */
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
-=
ux0
;
dy
-=
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
Track
->
m_StructType
==
TYPEVIA
)
/* VIA rencontree */
{
if
(
(
abs
(
spot_cX
)
<=
l_piste
)
&&
(
abs
(
spot_cY
)
<=
l_piste
)
)
{
if
(
Track
->
HitTest
(
ref_pos
)
)
return
Track
;
}
else
{
if
(
MasqueLayer
!=
-
1
)
if
(
(
g_TabOneLayerMask
[
Track
->
m_Layer
]
&
MasqueLayer
)
==
0
)
continue
;
/* Segments sur couches differentes */
if
(
Track
->
HitTest
(
ref_pos
)
)
return
Track
;
}
continue
;
}
if
(
MasqueLayer
!=
-
1
)
if
(
(
g_TabOneLayerMask
[
Track
->
m_Layer
]
&
MasqueLayer
)
==
0
)
continue
;
/* Segments sur couches differentes */
if
(
distance
(
l_piste
)
)
return
Track
;
}
return
NULL
;
}
...
...
@@ -1065,23 +862,12 @@ TRACK* Locate_Zone( TRACK* start_adresse, int layer, int typeloc )
TRACK
*
Locate_Zone
(
TRACK
*
start_adresse
,
const
wxPoint
&
ref_pos
,
int
layer
)
{
TRACK
*
Zone
;
/* pointeur sur les pistes */
int
l_segm
;
/* demi-largeur de la piste */
for
(
Zone
=
start_adresse
;
Zone
!=
NULL
;
Zone
=
(
TRACK
*
)
Zone
->
Pnext
)
for
(
TRACK
*
Zone
=
start_adresse
;
Zone
;
Zone
=
(
TRACK
*
)
Zone
->
Pnext
)
{
/* calcul des coordonnees du segment teste */
l_segm
=
Zone
->
m_Width
>>
1
;
/* l_piste = demi largeur piste */
ux0
=
Zone
->
m_Start
.
x
;
uy0
=
Zone
->
m_Start
.
y
;
/* coord de depart */
dx
=
Zone
->
m_End
.
x
;
dy
=
Zone
->
m_End
.
y
;
/* coord d'arrivee */
/* recalcul des coordonnees avec ux0, uy0 = origine des coordonnees */
dx
-=
ux0
;
dy
-=
uy0
;
spot_cX
=
ref_pos
.
x
-
ux0
;
spot_cY
=
ref_pos
.
y
-
uy0
;
if
(
(
layer
!=
-
1
)
&&
(
Zone
->
m_Layer
!=
layer
)
)
continue
;
if
(
distance
(
l_segm
)
)
if
(
Zone
->
HitTest
(
ref_pos
)
)
return
Zone
;
}
...
...
@@ -1123,159 +909,6 @@ TEXTE_PCB* Locate_Texte_Pcb( EDA_BaseStruct* PtStruct, int LayerSearch, int type
}
/*****************************/
int
distance
(
int
seuil
)
/*****************************/
/*
* Calcul de la distance du curseur souris a un segment de droite :
* ( piste, edge, contour module ..
* retourne:
* 0 si distance > seuil
* 1 si distance <= seuil
* Variables utilisees ( doivent etre initialisees avant appel , et
* sont ramenees au repere centre sur l'origine du segment)
* dx, dy = coord de l'extremite segment.
* spot_cX,spot_cY = coord du curseur souris
* la recherche se fait selon 4 cas:
* segment horizontal
* segment vertical
* segment 45
* segment quelconque
*/
{
int
cXrot
,
cYrot
,
/* coord du point (souris) dans le repere tourne */
segX
,
segY
;
/* coord extremite segment tj >= 0 */
int
pointX
,
pointY
;
/* coord point a tester dans repere modifie dans lequel
* segX et segY sont >=0 */
segX
=
dx
;
segY
=
dy
;
pointX
=
spot_cX
;
pointY
=
spot_cY
;
/*Recalcul coord pour que le segment soit dans 1er quadrant (coord >= 0)*/
if
(
segX
<
0
)
/* mise en >0 par symetrie par rapport a l'axe Y */
{
segX
=
-
segX
;
pointX
=
-
pointX
;
}
if
(
segY
<
0
)
/* mise en > 0 par symetrie par rapport a l'axe X */
{
segY
=
-
segY
;
pointY
=
-
pointY
;
}
if
(
segY
==
0
)
/* piste Horizontale */
{
if
(
abs
(
pointY
)
<=
seuil
)
{
if
(
(
pointX
>=
0
)
&&
(
pointX
<=
segX
)
)
return
1
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
pointX
<
0
)
&&
(
pointX
>=
-
seuil
)
)
{
if
(
(
(
pointX
*
pointX
)
+
(
pointY
*
pointY
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
if
(
(
pointX
>
segX
)
&&
(
pointX
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
pointX
-
segX
)
*
(
pointX
-
segX
)
)
+
(
pointY
*
pointY
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
}
}
else
if
(
segX
==
0
)
/* piste verticale */
{
if
(
abs
(
pointX
)
<=
seuil
)
{
if
(
(
pointY
>=
0
)
&&
(
pointY
<=
segY
)
)
return
1
;
if
(
(
pointY
<
0
)
&&
(
pointY
>=
-
seuil
)
)
{
if
(
(
(
pointY
*
pointY
)
+
(
pointX
*
pointX
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
if
(
(
pointY
>
segY
)
&&
(
pointY
<=
(
segY
+
seuil
)
)
)
{
if
(
(
(
(
pointY
-
segY
)
*
(
pointY
-
segY
)
)
+
(
pointX
*
pointX
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
}
}
else
if
(
segX
==
segY
)
/* piste a 45 degre */
{
/* on fait tourner les axes de 45 degre. la souris a alors les
* coord : x1 = x*cos45 + y*sin45
* y1 = y*cos45 - x*sin45
* et le segment de piste est alors horizontal.
* recalcul des coord de la souris ( sin45 = cos45 = .707 = 7/10
* remarque : sin ou cos45 = .707, et lors du recalcul des coord
* dx45 et dy45, lec coeff .707 est neglige, dx et dy sont en fait .707 fois
* trop grands. (c.a.d trop petits)
* spot_cX,Y doit etre * par .707 * .707 = 0.5 */
cXrot
=
(
pointX
+
pointY
)
>>
1
;
cYrot
=
(
pointY
-
pointX
)
>>
1
;
/* recalcul des coord de l'extremite du segment , qui sera vertical
* suite a l'orientation des axes sur l'ecran : dx45 = pointX (ou pointY)
* et est en fait 1,414 plus grand , et dy45 = 0 */
// seuil doit etre * .707 pour tenir compte du coeff de reduction sur dx,dy
seuil
*=
7
;
seuil
/=
10
;
if
(
abs
(
cYrot
)
<=
seuil
)
/* ok sur axe vertical) */
{
if
(
(
cXrot
>=
0
)
&&
(
cXrot
<=
segX
)
)
return
1
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
cXrot
<
0
)
&&
(
cXrot
>=
-
seuil
)
)
{
if
(
(
(
cXrot
*
cXrot
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
if
(
(
cXrot
>
segX
)
&&
(
cXrot
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
cXrot
-
segX
)
*
(
cXrot
-
segX
)
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
}
}
else
/* orientation quelconque */
{
/* On fait un changement d'axe (rotation) de facon a ce que le segment
* de piste soit horizontal dans le nouveau repere */
int
angle
;
angle
=
(
int
)
(
atan2
(
(
float
)
segY
,
(
float
)
segX
)
*
1800
/
M_PI
);
cXrot
=
pointX
;
cYrot
=
pointY
;
RotatePoint
(
&
cXrot
,
&
cYrot
,
angle
);
/* Rotation du point a tester */
RotatePoint
(
&
segX
,
&
segY
,
angle
);
/* Rotation du segment */
/* la piste est Horizontale , par suite des modifs de coordonnes
* et d'axe, donc segX = longueur du segment */
if
(
abs
(
cYrot
)
<=
seuil
)
/* ok sur axe vertical) */
{
if
(
(
cXrot
>=
0
)
&&
(
cXrot
<=
segX
)
)
return
1
;
/* Etude des extremites : cercle de rayon seuil */
if
(
(
cXrot
<
0
)
&&
(
cXrot
>=
-
seuil
)
)
{
if
(
(
(
cXrot
*
cXrot
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
if
(
(
cXrot
>
segX
)
&&
(
cXrot
<=
(
segX
+
seuil
)
)
)
{
if
(
(
(
(
cXrot
-
segX
)
*
(
cXrot
-
segX
)
)
+
(
cYrot
*
cYrot
)
)
<=
(
seuil
*
seuil
)
)
return
1
;
}
}
}
return
0
;
}
/*******************************************************************************/
D_PAD
*
Fast_Locate_Pad_Connecte
(
BOARD
*
Pcb
,
const
wxPoint
&
ref_pos
,
int
masque_layer
)
...
...
@@ -1396,11 +1029,10 @@ EDA_BaseStruct* Locate_MirePcb( EDA_BaseStruct* PtStruct, int LayerSearch,
int
typeloc
)
/***********************************************************************/
/* Se
ra
ch for a photo target
/* Se
ar
ch for a photo target
*/
{
wxPoint
ref_pos
;
/* coord du point de localisation */
int
dX
,
dY
,
rayon
;
if
(
PtStruct
==
NULL
)
return
NULL
;
...
...
@@ -1417,13 +1049,10 @@ EDA_BaseStruct* Locate_MirePcb( EDA_BaseStruct* PtStruct, int LayerSearch,
if
(
LayerSearch
!=
-
1
&&
item
->
m_Layer
!=
LayerSearch
)
continue
;
dX
=
ref_pos
.
x
-
item
->
m_Pos
.
x
;
dY
=
ref_pos
.
y
-
item
->
m_Pos
.
y
;
rayon
=
item
->
m_Size
/
2
;
if
(
(
abs
(
dX
)
<=
rayon
)
&&
(
abs
(
dY
)
<=
rayon
)
)
break
;
/* Mire Localisee */
if
(
item
->
HitTest
(
ref_pos
)
)
break
;
}
return
PtStruct
;
}
pcbnew/protos.h
View file @
c1e3416a
...
...
@@ -198,24 +198,6 @@ D_PAD * Fast_Locate_Pad_Connecte(BOARD * Pcb, const wxPoint & ref_pos, int layer
(bonne position ET bonne couche). */
int
distance
(
int
seuil
);
/*
Calcul de la distance du curseur souris a un segment de droite :
( piste, edge, contour module ..
retourne:
0 si distance > seuil
1 si distance <= seuil
Variables utilisees ( externes doivent etre initialisees avant appel , et
sont ramenees au repere centre sur l'origine du segment)
dx, dy = coord de l'extremite segment.
spot_cX,spot_cY = coord du curseur souris
la recherche se fait selon 4 cas:
segment horizontal
segment vertical
segment 45
segment quelconque
*/
TRACK
*
Locate_Zone
(
TRACK
*
start_adresse
,
int
layer
,
int
typeloc
);
TRACK
*
Locate_Zone
(
TRACK
*
start_adresse
,
const
wxPoint
&
ref_pos
,
int
layer
);
/*
...
...
pcbnew/zones.h
View file @
c1e3416a
...
...
@@ -122,5 +122,5 @@ public:
WinEDA_PcbFrame
*
m_Parent
;
};
#endif
// _ZONES_H_
#endif
// _ZONES_H_
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