kicad/pcbnew/class_pad_draw_functions.cpp

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/*******************************/
/* class_pad_draw_function.cpp */
/*******************************/
#include "fctsys.h"
#include "gr_basic.h"
#include "common.h"
#include "trigo.h"
#include "pcbnew_id.h" // ID_TRACK_BUTT
#include "class_drawpanel.h"
#include "drawtxt.h"
#include "pcbnew.h"
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#include "class_board_design_settings.h"
#include "colors_selection.h"
/* uncomment this line to show this pad with its specfic size and color
* when it is not on copper layers, and only one solder mask layer or solder paste layer
* is displayed for this pad
* After testing this feature,I am not sure this is a good idea
* but the code is left here.
*/
//#define SHOW_PADMASK_REAL_SIZE_AND_COLOR
// Helper class to store parameters used to draw a pad
PAD_DRAWINFO::PAD_DRAWINFO()
{
m_DrawPanel = NULL;
m_DrawMode = 0;
m_Color = BLACK;
m_HoleColor = BLACK; // could be DARKGRAY;
m_PadClearance = 0;
m_Display_padnum = true;
m_Display_netname = true;
m_ShowPadFilled = true;
m_ShowNCMark = true;
m_IsPrinting = false;
}
/** Draw a pad:
* @param aPanel = the EDA_DRAW_PANEL panel
* @param aDraw_mode = mode: GR_OR, GR_XOR, GR_AND...
* @param aOffset = draw offset
*/
void D_PAD::Draw( EDA_DRAW_PANEL* aPanel, wxDC* aDC, int aDraw_mode, const wxPoint& aOffset )
{
int color = 0;
wxSize mask_margin; // margin (clearance) used for some non copper layers
int showActualMaskSize = 0; /* == layer number if the actual pad size on mask layer can be displayed
* i.e. if only one layer is shown for this pad
* and this layer is a mask (solder mask or sloder paste
*/
if( m_Flags & DO_NOT_DRAW )
return;
PAD_DRAWINFO drawInfo;
drawInfo.m_Offset = aOffset;
/* We can show/hide pads from the layer manager.
* options are show/hide pads on front and/or back side of the board
* For through pads, we hide them only if both sides are hidden.
* smd pads on back are hidden for all layers (copper and technical layers)
* on back side of the board
* smd pads on front are hidden for all layers (copper and technical layers)
* on front side of the board
* ECO, edge and Draw layers and not considered
*/
// Mask layers for Back side of board
#define BACK_SIDE_LAYERS \
(LAYER_BACK | ADHESIVE_LAYER_BACK | SOLDERPASTE_LAYER_BACK \
| SILKSCREEN_LAYER_BACK | SOLDERMASK_LAYER_BACK)
// Mask layers for Front side of board
#define FRONT_SIDE_LAYERS \
(LAYER_FRONT | ADHESIVE_LAYER_FRONT | SOLDERPASTE_LAYER_FRONT \
| SILKSCREEN_LAYER_FRONT | SOLDERMASK_LAYER_FRONT)
BOARD* brd = GetBoard();
bool frontVisible = brd->IsElementVisible( PCB_VISIBLE( PAD_FR_VISIBLE ) );
bool backVisible = brd->IsElementVisible( PCB_VISIBLE( PAD_BK_VISIBLE ) );
if( !frontVisible && !backVisible )
return;
/* If pad are only on front side (no layer on back side)
* and if hide front side pads is enabled, do not draw
*/
if( !frontVisible && ( (m_Masque_Layer & BACK_SIDE_LAYERS) == 0 ) )
return;
/* If pad are only on back side (no layer on front side)
* and if hide back side pads is enabled, do not draw
*/
if( !backVisible && ( (m_Masque_Layer & FRONT_SIDE_LAYERS) == 0 ) )
return;
WinEDA_BasePcbFrame* frame = (WinEDA_BasePcbFrame*) aPanel->GetParent();
PCB_SCREEN* screen = frame->GetScreen();
if( frame->m_DisplayPadFill == FILLED )
drawInfo.m_ShowPadFilled = true;
else
drawInfo.m_ShowPadFilled = false;
if( m_Masque_Layer & LAYER_FRONT )
{
color = brd->GetVisibleElementColor( PAD_FR_VISIBLE );
}
if( m_Masque_Layer & LAYER_BACK )
{
color |= brd->GetVisibleElementColor( PAD_BK_VISIBLE );
}
if( color == 0 ) /* Not on copper layer */
{
// If the pad in on only one tech layer, use the layer color
// else use DARKGRAY
int mask_non_copper_layers = m_Masque_Layer & ~ALL_CU_LAYERS;
#ifdef SHOW_PADMASK_REAL_SIZE_AND_COLOR
mask_non_copper_layers &= brd->GetVisibleLayers();
#endif
switch( mask_non_copper_layers )
{
case 0:
break;
case ADHESIVE_LAYER_BACK:
color = brd->GetLayerColor( ADHESIVE_N_BACK );
break;
case ADHESIVE_LAYER_FRONT:
color = brd->GetLayerColor( ADHESIVE_N_FRONT );
break;
case SOLDERPASTE_LAYER_BACK:
color = brd->GetLayerColor( SOLDERPASTE_N_BACK );
showActualMaskSize = SOLDERPASTE_N_BACK;
break;
case SOLDERPASTE_LAYER_FRONT:
color = brd->GetLayerColor( SOLDERPASTE_N_FRONT );
showActualMaskSize = SOLDERPASTE_N_FRONT;
break;
case SILKSCREEN_LAYER_BACK:
color = brd->GetLayerColor( SILKSCREEN_N_BACK );
break;
case SILKSCREEN_LAYER_FRONT:
color = brd->GetLayerColor( SILKSCREEN_N_FRONT );
break;
case SOLDERMASK_LAYER_BACK:
color = brd->GetLayerColor( SOLDERMASK_N_BACK );
showActualMaskSize = SOLDERMASK_N_BACK;
break;
case SOLDERMASK_LAYER_FRONT:
color = brd->GetLayerColor( SOLDERMASK_N_FRONT );
showActualMaskSize = SOLDERMASK_N_FRONT;
break;
case DRAW_LAYER:
color = brd->GetLayerColor( DRAW_N );
break;
case COMMENT_LAYER:
color = brd->GetLayerColor( COMMENT_N );
break;
case ECO1_LAYER:
color = brd->GetLayerColor( ECO1_N );
break;
case ECO2_LAYER:
color = brd->GetLayerColor( ECO2_N );
break;
case EDGE_LAYER:
color = brd->GetLayerColor( EDGE_N );
break;
default:
color = DARKGRAY;
break;
}
}
// if PAD_SMD pad and high contrast mode
if( ( m_Attribut == PAD_SMD || m_Attribut == PAD_CONN )
&& DisplayOpt.ContrastModeDisplay )
{
// when routing tracks
if( frame && frame->m_ID_current_state == ID_TRACK_BUTT )
{
int routeTop = screen->m_Route_Layer_TOP;
int routeBot = screen->m_Route_Layer_BOTTOM;
// if routing between copper and component layers,
// or the current layer is one of said 2 external copper layers,
// then highlight only the current layer.
if( ( ( 1 << routeTop ) | ( 1 << routeBot ) )
== ( LAYER_BACK | LAYER_FRONT )
|| ( ( 1 << screen->m_Active_Layer )
& ( LAYER_BACK | LAYER_FRONT ) ) )
{
if( !IsOnLayer( screen->m_Active_Layer ) )
{
color &= ~MASKCOLOR;
color |= DARKDARKGRAY;
}
}
// else routing between an internal signal layer and some other
// layer. Grey out all PAD_SMD pads not on current or the single
// selected external layer.
else if( !IsOnLayer( screen->m_Active_Layer )
&& !IsOnLayer( routeTop )
&& !IsOnLayer( routeBot ) )
{
color &= ~MASKCOLOR;
color |= DARKDARKGRAY;
}
}
// when not edting tracks, show PAD_SMD components not on active layer
// as greyed out
else
{
if( !IsOnLayer( screen->m_Active_Layer ) )
{
color &= ~MASKCOLOR;
color |= DARKDARKGRAY;
}
}
}
#ifdef SHOW_PADMASK_REAL_SIZE_AND_COLOR
if( showActualMaskSize )
{
switch( showActualMaskSize )
{
case SOLDERMASK_N_BACK:
case SOLDERMASK_N_FRONT:
mask_margin.x = mask_margin.y = GetSolderMaskMargin();
break;
case SOLDERPASTE_N_BACK:
case SOLDERPASTE_N_FRONT:
mask_margin = GetSolderPasteMargin();
break;
default:
break;
}
}
#endif
// if Contrast mode is ON and a technical layer active, show pads on this
// layer so we can see pads on paste or solder layer and the size of the
// mask
if( DisplayOpt.ContrastModeDisplay && screen->m_Active_Layer > LAST_COPPER_LAYER )
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{
if( IsOnLayer( screen->m_Active_Layer ) )
{
color = brd->GetLayerColor( screen->m_Active_Layer );
// In hight contrast mode, and if the active layer is the mask
// layer shows the pad size with the mask clearance
switch( screen->m_Active_Layer )
{
case SOLDERMASK_N_BACK:
case SOLDERMASK_N_FRONT:
mask_margin.x = mask_margin.y = GetSolderMaskMargin();
break;
case SOLDERPASTE_N_BACK:
case SOLDERPASTE_N_FRONT:
mask_margin = GetSolderPasteMargin();
break;
default:
break;
}
}
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else
color = DARKDARKGRAY;
}
if( aDraw_mode & GR_SURBRILL )
{
if( aDraw_mode & GR_AND )
color &= ~HIGHLIGHT_FLAG;
else
color |= HIGHLIGHT_FLAG;
}
if( color & HIGHLIGHT_FLAG )
color = ColorRefs[color & MASKCOLOR].m_LightColor;
bool DisplayIsol = DisplayOpt.DisplayPadIsol;
if( ( m_Masque_Layer & ALL_CU_LAYERS ) == 0 )
DisplayIsol = FALSE;
drawInfo.m_DrawMode = aDraw_mode;
drawInfo.m_Color = color;
drawInfo.m_DrawPanel = aPanel;
drawInfo.m_Mask_margin = mask_margin;
drawInfo.m_ShowNCMark = brd->IsElementVisible( PCB_VISIBLE( NO_CONNECTS_VISIBLE ) );
drawInfo.m_IsPrinting = screen->m_IsPrinting;
SetAlpha( &color, 170 );
/* Get the pad clearance. This has a meaning only for Pcbnew.
* for Cvpcb (and Gerbview) GetClearance() creates debug errors because
* there is no net classes so a call to GetClearance() is made only when
* needed (never needed in Cvpcb nor in Gerbview)
*/
drawInfo.m_PadClearance = DisplayIsol ? GetClearance() : 0;
/* Draw the pad number */
if( frame && !frame->m_DisplayPadNum )
drawInfo.m_Display_padnum = false;
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if( ( DisplayOpt.DisplayNetNamesMode == 0 )
|| ( DisplayOpt.DisplayNetNamesMode == 2 ) )
drawInfo.m_Display_netname = false;
// Display net names is restricted to pads that are on the active layer
// in cotranst mode displae
if( !IsOnLayer( screen->m_Active_Layer ) && DisplayOpt.ContrastModeDisplay )
drawInfo.m_Display_netname = false;
DrawShape( &aPanel->m_ClipBox, aDC, drawInfo );
}
/**
* Function DrawShape
* basic function to draw a pad.
* used by D_PAD::Draw after calculation of parameters (color, final orientation ...)
* this function can be called to draw a pad on a panel
* even if this panel is not a EDA_DRAW_PANEL (for instance on a wxPanel inside the pad editor)
*/
void D_PAD::DrawShape( EDA_Rect* aClipBox, wxDC* aDC, PAD_DRAWINFO& aDrawInfo )
{
wxPoint coord[4];
int delta_cx, delta_cy;
int angle = m_Orient;
int seg_width;
GRSetDrawMode( aDC, aDrawInfo.m_DrawMode );
// calculate pad shape position :
wxPoint shape_pos = ReturnShapePos() - aDrawInfo.m_Offset;
wxSize halfsize = m_Size;
halfsize.x >>= 1;
halfsize.y >>= 1;
switch( GetShape() )
{
case PAD_CIRCLE:
if( aDrawInfo.m_ShowPadFilled )
GRFilledCircle( aClipBox, aDC, shape_pos.x, shape_pos.y,
halfsize.x + aDrawInfo.m_Mask_margin.x, 0,
aDrawInfo.m_Color, aDrawInfo.m_Color );
else
GRCircle( aClipBox, aDC, shape_pos.x, shape_pos.y,
halfsize.x + aDrawInfo.m_Mask_margin.x,
m_PadSketchModePenSize, aDrawInfo.m_Color );
if( aDrawInfo.m_PadClearance )
{
GRCircle( aClipBox,
aDC, shape_pos.x, shape_pos.y,
halfsize.x + aDrawInfo.m_PadClearance,
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0,
aDrawInfo.m_Color );
}
break;
case PAD_OVAL:
{
wxPoint segStart, segEnd;
seg_width = BuildSegmentFromOvalShape(segStart, segEnd, angle);
segStart += shape_pos;
segEnd += shape_pos;
if( aDrawInfo.m_ShowPadFilled )
{
GRFillCSegm( aClipBox, aDC, segStart.x, segStart.y, segEnd.x, segEnd.y,
seg_width, aDrawInfo.m_Color );
}
else
{
GRCSegm( aClipBox, aDC, segStart.x, segStart.y, segEnd.x, segEnd.y,
seg_width, m_PadSketchModePenSize, aDrawInfo.m_Color );
}
/* Draw the isolation line. */
if( aDrawInfo.m_PadClearance )
{
seg_width += 2 * aDrawInfo.m_PadClearance;
GRCSegm( aClipBox, aDC, segStart.x, segStart.y, segEnd.x, segEnd.y,
seg_width, aDrawInfo.m_Color );
}
}
break;
case PAD_RECT:
case PAD_TRAPEZOID:
BuildPadPolygon( coord, aDrawInfo.m_Mask_margin, angle );
for( int ii = 0; ii < 4; ii++ )
coord[ii] += shape_pos;
GRClosedPoly( aClipBox, aDC, 4, coord, aDrawInfo.m_ShowPadFilled,
aDrawInfo.m_ShowPadFilled ? 0 : m_PadSketchModePenSize,
aDrawInfo.m_Color, aDrawInfo.m_Color );
if( aDrawInfo.m_PadClearance )
{
BuildPadPolygon( coord, wxSize( aDrawInfo.m_PadClearance,
aDrawInfo.m_PadClearance ), angle );
for( int ii = 0; ii < 4; ii++ )
coord[ii] += shape_pos;
GRClosedPoly( aClipBox, aDC, 4, coord, 0, aDrawInfo.m_Color, aDrawInfo.m_Color );
}
break;
default:
break;
}
/* Draw the pad hole */
wxPoint holepos = m_Pos - aDrawInfo.m_Offset;
int hole = m_Drill.x >> 1;
if( aDrawInfo.m_ShowPadFilled && hole )
{
bool blackpenstate = false;
if( aDrawInfo.m_IsPrinting )
{
blackpenstate = GetGRForceBlackPenState();
GRForceBlackPen( false );
aDrawInfo.m_HoleColor = g_DrawBgColor;
}
if( aDrawInfo.m_DrawMode != GR_XOR )
GRSetDrawMode( aDC, GR_COPY );
else
GRSetDrawMode( aDC, GR_XOR );
switch( m_DrillShape )
{
case PAD_CIRCLE:
if( aDC->LogicalToDeviceXRel( hole ) > 1 )
GRFilledCircle( aClipBox, aDC, holepos.x, holepos.y, hole, 0,
aDrawInfo.m_Color, aDrawInfo.m_HoleColor );
break;
case PAD_OVAL:
halfsize.x = m_Drill.x >> 1;
halfsize.y = m_Drill.y >> 1;
if( m_Drill.x > m_Drill.y ) /* horizontal */
{
delta_cx = halfsize.x - halfsize.y;
delta_cy = 0;
seg_width = m_Drill.y;
}
else /* vertical */
{
delta_cx = 0;
delta_cy = halfsize.y - halfsize.x;
seg_width = m_Drill.x;
}
RotatePoint( &delta_cx, &delta_cy, angle );
GRFillCSegm( aClipBox, aDC, holepos.x + delta_cx, holepos.y + delta_cy,
holepos.x - delta_cx, holepos.y - delta_cy, seg_width,
aDrawInfo.m_HoleColor );
break;
default:
break;
}
if( aDrawInfo.m_IsPrinting )
GRForceBlackPen( blackpenstate );
}
GRSetDrawMode( aDC, aDrawInfo.m_DrawMode );
/* Draw "No connect" ( / or \ or cross X ) if necessary. : */
if( m_Netname.IsEmpty() && aDrawInfo.m_ShowNCMark )
{
int dx0 = MIN( halfsize.x, halfsize.y );
int nc_color = BLUE;
if( m_Masque_Layer & LAYER_FRONT ) /* Draw \ */
GRLine( aClipBox, aDC, holepos.x - dx0, holepos.y - dx0,
holepos.x + dx0, holepos.y + dx0, 0, nc_color );
if( m_Masque_Layer & LAYER_BACK ) /* Draw / */
GRLine( aClipBox, aDC, holepos.x + dx0, holepos.y - dx0,
holepos.x - dx0, holepos.y + dx0, 0, nc_color );
}
/* Draw the pad number */
if( !aDrawInfo.m_Display_padnum && !aDrawInfo.m_Display_netname )
return;
wxPoint tpos0 = shape_pos; // Position of the centre of text
wxPoint tpos = tpos0;
wxSize AreaSize; // size of text area, normalized to
// AreaSize.y < AreaSize.x
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int shortname_len = m_ShortNetname.Len();
if( !aDrawInfo.m_Display_netname )
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shortname_len = 0;
if( GetShape() == PAD_CIRCLE )
angle = 0;
AreaSize = m_Size;
if( m_Size.y > m_Size.x )
{
angle += 900;
AreaSize.x = m_Size.y;
AreaSize.y = m_Size.x;
}
if( shortname_len > 0 ) // if there is a netname, provides room
// to display this netname
{
AreaSize.y /= 2; // Text used only the upper area of the
// pad. The lower area displays the net
// name
tpos.y -= AreaSize.y / 2;
}
// Calculate the position of text, that is the middle point of the upper
// area of the pad
RotatePoint( &tpos, shape_pos, angle );
/* Draw text with an angle between -90 deg and + 90 deg */
int t_angle = angle;
NORMALIZE_ANGLE_90( t_angle );
/* Note: in next calculations, texte size is calculated for 3 or more
* chars. Of course, pads numbers and nets names can have less than 3
* chars. but after some tries, i found this is gives the best look
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*/
#define MIN_CHAR_COUNT 3
wxString buffer;
int tsize;
if( aDrawInfo.m_Display_padnum )
{
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ReturnStringPadName( buffer );
int numpad_len = buffer.Len();
numpad_len = MAX( numpad_len, MIN_CHAR_COUNT );
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tsize = min( AreaSize.y, AreaSize.x / numpad_len );
#define CHAR_SIZE_MIN 5
if( aDC->LogicalToDeviceXRel( tsize ) >= CHAR_SIZE_MIN ) // Not drawable when size too small.
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{
// tsize reserve room for marges and segments thickness
tsize = (int) ( tsize * 0.8 );
DrawGraphicText( aDrawInfo.m_DrawPanel, aDC, tpos, WHITE, buffer, t_angle,
wxSize( tsize, tsize ), GR_TEXT_HJUSTIFY_CENTER,
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GR_TEXT_VJUSTIFY_CENTER, tsize / 7, false, false );
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}
}
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// display the short netname, if exists
if( shortname_len == 0 )
return;
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shortname_len = MAX( shortname_len, MIN_CHAR_COUNT );
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tsize = min( AreaSize.y, AreaSize.x / shortname_len );
if( aDC->LogicalToDeviceXRel( tsize ) >= CHAR_SIZE_MIN ) // Not drawable in size too small.
{
tpos = tpos0;
if( aDrawInfo.m_Display_padnum )
tpos.y += AreaSize.y / 2;
RotatePoint( &tpos, shape_pos, angle );
// tsize reserve room for marges and segments thickness
tsize = (int) ( tsize * 0.8 );
DrawGraphicText( aDrawInfo.m_DrawPanel, aDC, tpos, WHITE, m_ShortNetname, t_angle,
wxSize( tsize, tsize ), GR_TEXT_HJUSTIFY_CENTER,
GR_TEXT_VJUSTIFY_CENTER, tsize / 7, false, false );
}
}
/**
* Function BuildSegmentFromOvalShape
* Has meaning only for OVAL (and ROUND) pads.
* Build an equivalent segment having the same shape as the OVAL shape,
* aSegStart and aSegEnd are the ending points of the equivalent segment of the shape
* aRotation is the asked rotation of the segment (usually m_Orient)
*/
int D_PAD::BuildSegmentFromOvalShape(wxPoint& aSegStart, wxPoint& aSegEnd, int aRotation) const
{
int width;
if( m_Size.y < m_Size.x ) // Build an horizontal equiv segment
{
int delta = ( m_Size.x - m_Size.y ) / 2;
aSegStart.x = -delta;
aSegStart.y = 0;
aSegEnd.x = delta;
aSegEnd.y = 0;
width = m_Size.y;
}
else // Vertical oval: build a vertical equiv segment
{
int delta = ( m_Size.y -m_Size.x ) / 2;
aSegStart.x = 0;
aSegStart.y = -delta;
aSegEnd.x = 0;
aSegEnd.y = delta;
width = m_Size.x;
}
if( aRotation )
{
RotatePoint( &aSegStart, aRotation);
RotatePoint( &aSegEnd, aRotation);
}
return width;
}
/**
* Function BuildPadPolygon
* Has meaning only for polygonal pads (trapeziod and rectangular)
* Build the Corner list of the polygonal shape,
* depending on shape, extra size (clearance ...) and orientation
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* @param aCoord = a buffer to fill.
* @param aInflateValue = wxSize: the clearance or margin value. value > 0: inflate, < 0 deflate
* @param aRotation = full rotation of the polygon, usually m_Orient
*/
void D_PAD::BuildPadPolygon( wxPoint aCoord[4], wxSize aInflateValue, int aRotation ) const
{
if( (GetShape() != PAD_RECT) && (GetShape() != PAD_TRAPEZOID) )
return;
wxSize delta;
wxSize halfsize;
halfsize.x = m_Size.x >> 1;
halfsize.y = m_Size.y >> 1;
/* For rectangular shapes, inflate is easy
*/
if( GetShape() == PAD_RECT )
{
halfsize += aInflateValue;
// Verify if do not deflate more than than size
// Only possible for inflate negative values.
if( halfsize.x < 0 )
halfsize.x = 0;
if( halfsize.y < 0 )
halfsize.y = 0;
}
else
{
// Trapezoidal pad: verify delta values
delta.x = ( m_DeltaSize.x >> 1 );
delta.y = ( m_DeltaSize.y >> 1 );
// be sure delta values are not to large
if( (delta.x < 0) && (delta.x <= -halfsize.y) )
delta.x = -halfsize.y + 1;
if( (delta.x > 0) && (delta.x >= halfsize.y) )
delta.x = halfsize.y - 1;
if( (delta.y < 0) && (delta.y <= -halfsize.x) )
delta.y = -halfsize.x + 1;
if( (delta.y > 0) && (delta.y >= halfsize.x) )
delta.y = halfsize.x - 1;
}
// Build the basic rectangular or trapezoid shape
// delta is null for rectangular shapes
aCoord[0].x = -halfsize.x - delta.y; // lower left
aCoord[0].y = +halfsize.y + delta.x;
aCoord[1].x = -halfsize.x + delta.y; // upper left
aCoord[1].y = -halfsize.y - delta.x;
aCoord[2].x = +halfsize.x - delta.y; // upper right
aCoord[2].y = -halfsize.y + delta.x;
aCoord[3].x = +halfsize.x + delta.y; // lower right
aCoord[3].y = +halfsize.y - delta.x;
// Offsetting the trapezoid shape id needed
// It is assumed delta.x or/and delta.y == 0
if( GetShape() == PAD_TRAPEZOID && (aInflateValue.x != 0 || aInflateValue.y != 0) )
{
double angle;
wxSize corr;
if( delta.y ) // lower and upper segment is horizontal
{
// Calculate angle of left (or right) segment with vertical axis
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angle = atan2( double( m_DeltaSize.y ), double( m_Size.y ) );
// left and right sides are moved by aInflateValue.x in their perpendicular direction
// We must calculate the corresponding displacement on the horizontal axis
// that is delta.x +- corr.x depending on the corner
corr.x = wxRound( tan( angle ) * aInflateValue.x );
delta.x = wxRound( aInflateValue.x / cos( angle ) );
// Horizontal sides are moved up and down by aInflateValue.y
delta.y = aInflateValue.y;
// corr.y = 0 by the constructor
}
else if( delta.x ) // left and right segment is vertical
{
// Calculate angle of lower (or upper) segment with horizontal axis
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angle = atan2( double( m_DeltaSize.x ), double( m_Size.x ) );
// lower and upper sides are moved by aInflateValue.x in their perpendicular direction
// We must calculate the corresponding displacement on the vertical axis
// that is delta.y +- corr.y depending on the corner
corr.y = wxRound( tan( angle ) * aInflateValue.y );
delta.y = wxRound( aInflateValue.y / cos( angle ) );
// Vertical sides are moved left and right by aInflateValue.x
delta.x = aInflateValue.x;
// corr.x = 0 by the constructor
}
else // the trapezoid is a rectangle
{
delta = aInflateValue; // this pad is rectangular (delta null).
}
aCoord[0].x += -delta.x - corr.x; // lower left
aCoord[0].y += delta.y + corr.y;
aCoord[1].x += -delta.x + corr.x; // upper left
aCoord[1].y += -delta.y - corr.y;
aCoord[2].x += delta.x - corr.x; // upper right
aCoord[2].y += -delta.y + corr.y;
aCoord[3].x += delta.x + corr.x; // lower right
aCoord[3].y += delta.y - corr.y;
/* test coordinates and clamp them if the offset correction is too large:
* Note: if a coordinate is bad, the other "symmetric" coordinate is bad
* So when a bad coordinate is found, the 2 symmetric coordinates
* are set to the minimun value (0)
*/
if( aCoord[0].x > 0 ) // lower left x coordinate must be <= 0
aCoord[0].x = aCoord[3].x = 0;
if( aCoord[1].x > 0 ) // upper left x coordinate must be <= 0
aCoord[1].x = aCoord[2].x = 0;
if( aCoord[0].y < 0 ) // lower left y coordinate must be >= 0
aCoord[0].y = aCoord[1].y = 0;
if( aCoord[3].y < 0 ) // lower right y coordinate must be >= 0
aCoord[3].y = aCoord[2].y = 0;
}
if( aRotation )
{
for( int ii = 0; ii < 4; ii++ )
RotatePoint( &aCoord[ii], aRotation );
}
}