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# include "GLCanvas3D.hpp"
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# include "../../slic3r/GUI/3DScene.hpp"
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# include "../../libslic3r/ClipperUtils.hpp"
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# include <wx/glcanvas.h>
# include <iostream>
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static const bool TURNTABLE_MODE = true ;
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static const float GIMBALL_LOCK_THETA_MAX = 180.0f ;
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static const float GROUND_Z = - 0.02f ;
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// phi / theta angles to orient the camera.
static const float VIEW_DEFAULT [ 2 ] = { 45.0f , 45.0f } ;
static const float VIEW_LEFT [ 2 ] = { 90.0f , 90.0f } ;
static const float VIEW_RIGHT [ 2 ] = { - 90.0f , 90.0f } ;
static const float VIEW_TOP [ 2 ] = { 0.0f , 0.0f } ;
static const float VIEW_BOTTOM [ 2 ] = { 0.0f , 180.0f } ;
static const float VIEW_FRONT [ 2 ] = { 0.0f , 90.0f } ;
static const float VIEW_REAR [ 2 ] = { 180.0f , 90.0f } ;
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namespace Slic3r {
namespace GUI {
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bool GeometryBuffer : : set_from_triangles ( const Polygons & triangles , float z )
{
m_data . clear ( ) ;
unsigned int size = 9 * ( unsigned int ) triangles . size ( ) ;
if ( size = = 0 )
return false ;
m_data = std : : vector < float > ( size , 0.0f ) ;
unsigned int coord = 0 ;
for ( const Polygon & t : triangles )
{
for ( unsigned int v = 0 ; v < 3 ; + + v )
{
const Point & p = t . points [ v ] ;
m_data [ coord + + ] = ( float ) unscale ( p . x ) ;
m_data [ coord + + ] = ( float ) unscale ( p . y ) ;
m_data [ coord + + ] = z ;
}
}
return true ;
}
bool GeometryBuffer : : set_from_lines ( const Lines & lines , float z )
{
m_data . clear ( ) ;
unsigned int size = 6 * ( unsigned int ) lines . size ( ) ;
if ( size = = 0 )
return false ;
m_data = std : : vector < float > ( size , 0.0f ) ;
unsigned int coord = 0 ;
for ( const Line & l : lines )
{
m_data [ coord + + ] = ( float ) unscale ( l . a . x ) ;
m_data [ coord + + ] = ( float ) unscale ( l . a . y ) ;
m_data [ coord + + ] = z ;
m_data [ coord + + ] = ( float ) unscale ( l . b . x ) ;
m_data [ coord + + ] = ( float ) unscale ( l . b . y ) ;
m_data [ coord + + ] = z ;
}
return true ;
}
const float * GeometryBuffer : : get_data ( ) const
{
return m_data . data ( ) ;
}
unsigned int GeometryBuffer : : get_data_size ( ) const
{
return ( unsigned int ) m_data . size ( ) ;
}
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GLCanvas3D : : Camera : : Camera ( )
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: m_type ( CT_Ortho )
, m_zoom ( 1.0f )
, m_phi ( 45.0f )
, m_theta ( 45.0f )
, m_distance ( 0.0f )
, m_target ( 0.0 , 0.0 , 0.0 )
{
}
GLCanvas3D : : Camera : : EType GLCanvas3D : : Camera : : get_type ( ) const
{
return m_type ;
}
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void GLCanvas3D : : Camera : : set_type ( GLCanvas3D : : Camera : : EType type )
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{
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m_type = type ;
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}
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std : : string GLCanvas3D : : Camera : : get_type_as_string ( ) const
{
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switch ( m_type )
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{
default :
case CT_Unknown :
return " unknown " ;
case CT_Perspective :
return " perspective " ;
case CT_Ortho :
return " ortho " ;
} ;
}
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float GLCanvas3D : : Camera : : get_zoom ( ) const
{
return m_zoom ;
}
void GLCanvas3D : : Camera : : set_zoom ( float zoom )
{
m_zoom = zoom ;
}
float GLCanvas3D : : Camera : : get_phi ( ) const
{
return m_phi ;
}
void GLCanvas3D : : Camera : : set_phi ( float phi )
{
m_phi = phi ;
}
float GLCanvas3D : : Camera : : get_theta ( ) const
{
return m_theta ;
}
void GLCanvas3D : : Camera : : set_theta ( float theta )
{
m_theta = theta ;
// clamp angle
if ( m_theta > GIMBALL_LOCK_THETA_MAX )
m_theta = GIMBALL_LOCK_THETA_MAX ;
if ( m_theta < 0.0f )
m_theta = 0.0f ;
}
float GLCanvas3D : : Camera : : get_distance ( ) const
{
return m_distance ;
}
void GLCanvas3D : : Camera : : set_distance ( float distance )
{
m_distance = distance ;
}
const Pointf3 & GLCanvas3D : : Camera : : get_target ( ) const
{
return m_target ;
}
void GLCanvas3D : : Camera : : set_target ( const Pointf3 & target )
{
m_target = target ;
}
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const Pointfs & GLCanvas3D : : Bed : : get_shape ( ) const
{
return m_shape ;
}
void GLCanvas3D : : Bed : : set_shape ( const Pointfs & shape )
{
m_shape = shape ;
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_calc_bounding_box ( ) ;
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ExPolygon poly ;
for ( const Pointf & p : m_shape )
{
poly . contour . append ( Point ( scale_ ( p . x ) , scale_ ( p . y ) ) ) ;
}
_calc_triangles ( poly ) ;
const BoundingBox & bed_bbox = poly . contour . bounding_box ( ) ;
_calc_gridlines ( poly , bed_bbox ) ;
m_polygon = offset_ex ( poly . contour , bed_bbox . radius ( ) * 1.7 , jtRound , scale_ ( 0.5 ) ) [ 0 ] . contour ;
set_origin ( Pointf ( 0.0 , 0.0 ) ) ;
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}
const BoundingBoxf3 & GLCanvas3D : : Bed : : get_bounding_box ( ) const
{
return m_bounding_box ;
}
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const Pointf & GLCanvas3D : : Bed : : get_origin ( ) const
{
return m_origin ;
}
void GLCanvas3D : : Bed : : set_origin ( const Pointf & origin )
{
m_origin = origin ;
}
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void GLCanvas3D : : Bed : : render ( )
{
unsigned int triangles_vcount = m_triangles . get_data_size ( ) / 3 ;
if ( triangles_vcount > 0 )
{
: : glDisable ( GL_DEPTH_TEST ) ;
: : glEnable ( GL_BLEND ) ;
: : glBlendFunc ( GL_SRC_ALPHA , GL_ONE_MINUS_SRC_ALPHA ) ;
: : glEnableClientState ( GL_VERTEX_ARRAY ) ;
: : glColor4f ( 0.8f , 0.6f , 0.5f , 0.4f ) ;
: : glNormal3d ( 0.0f , 0.0f , 1.0f ) ;
: : glVertexPointer ( 3 , GL_FLOAT , 0 , ( GLvoid * ) m_triangles . get_data ( ) ) ;
: : glDrawArrays ( GL_TRIANGLES , 0 , triangles_vcount ) ;
// ::glDisableClientState(GL_VERTEX_ARRAY);
// we need depth test for grid, otherwise it would disappear when looking
//<2F> the object from below
glEnable ( GL_DEPTH_TEST ) ;
// draw grid
unsigned int gridlines_vcount = m_gridlines . get_data_size ( ) / 3 ;
: : glLineWidth ( 3.0f ) ;
: : glColor4f ( 0.2f , 0.2f , 0.2f , 0.4f ) ;
// ::glEnableClientState(GL_VERTEX_ARRAY);
: : glVertexPointer ( 3 , GL_FLOAT , 0 , ( GLvoid * ) m_gridlines . get_data ( ) ) ;
: : glDrawArrays ( GL_LINES , 0 , gridlines_vcount ) ;
: : glDisableClientState ( GL_VERTEX_ARRAY ) ;
: : glDisable ( GL_BLEND ) ;
}
}
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void GLCanvas3D : : Bed : : _calc_bounding_box ( )
{
m_bounding_box = BoundingBoxf3 ( ) ;
for ( const Pointf & p : m_shape )
{
m_bounding_box . merge ( Pointf3 ( p . x , p . y , 0.0 ) ) ;
}
}
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void GLCanvas3D : : Bed : : _calc_triangles ( const ExPolygon & poly )
{
Polygons triangles ;
poly . triangulate ( & triangles ) ;
if ( ! m_triangles . set_from_triangles ( triangles , GROUND_Z ) )
printf ( " Unable to create bed triangles \n " ) ;
}
void GLCanvas3D : : Bed : : _calc_gridlines ( const ExPolygon & poly , const BoundingBox & bed_bbox )
{
Polylines axes_lines ;
for ( coord_t x = bed_bbox . min . x ; x < = bed_bbox . max . x ; x + = scale_ ( 10.0 ) )
{
Polyline line ;
line . append ( Point ( x , bed_bbox . min . y ) ) ;
line . append ( Point ( x , bed_bbox . max . y ) ) ;
axes_lines . push_back ( line ) ;
}
for ( coord_t y = bed_bbox . min . y ; y < = bed_bbox . max . y ; y + = scale_ ( 10.0 ) )
{
Polyline line ;
line . append ( Point ( bed_bbox . min . x , y ) ) ;
line . append ( Point ( bed_bbox . max . x , y ) ) ;
axes_lines . push_back ( line ) ;
}
// clip with a slightly grown expolygon because our lines lay on the contours and may get erroneously clipped
Lines gridlines = to_lines ( intersection_pl ( axes_lines , offset ( poly , SCALED_EPSILON ) ) ) ;
// append bed contours
Lines contour_lines = to_lines ( poly ) ;
std : : copy ( contour_lines . begin ( ) , contour_lines . end ( ) , std : : back_inserter ( gridlines ) ) ;
if ( ! m_gridlines . set_from_lines ( gridlines , GROUND_Z ) )
printf ( " Unable to create bed grid lines \n " ) ;
}
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GLCanvas3D : : GLCanvas3D ( wxGLCanvas * canvas , wxGLContext * context )
: m_canvas ( canvas )
, m_context ( context )
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, m_volumes ( nullptr )
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, m_dirty ( true )
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, m_apply_zoom_to_volumes_filter ( false )
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{
}
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GLCanvas3D : : ~ GLCanvas3D ( )
{
_deregister_callbacks ( ) ;
}
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void GLCanvas3D : : set_current ( )
{
if ( ( m_canvas ! = nullptr ) & & ( m_context ! = nullptr ) )
m_canvas - > SetCurrent ( * m_context ) ;
}
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bool GLCanvas3D : : is_dirty ( ) const
{
return m_dirty ;
}
void GLCanvas3D : : set_dirty ( bool dirty )
{
m_dirty = dirty ;
}
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bool GLCanvas3D : : is_shown_on_screen ( ) const
{
return ( m_canvas ! = nullptr ) ? m_canvas - > IsShownOnScreen ( ) : false ;
}
void GLCanvas3D : : resize ( unsigned int w , unsigned int h )
{
if ( m_context = = nullptr )
return ;
set_current ( ) ;
: : glViewport ( 0 , 0 , w , h ) ;
: : glMatrixMode ( GL_PROJECTION ) ;
: : glLoadIdentity ( ) ;
BoundingBoxf3 bbox = max_bounding_box ( ) ;
switch ( get_camera_type ( ) )
{
case Camera : : CT_Ortho :
{
float w2 = w ;
float h2 = h ;
float two_zoom = 2.0f * get_camera_zoom ( ) ;
if ( two_zoom ! = 0.0f )
{
float inv_two_zoom = 1.0f / two_zoom ;
w2 * = inv_two_zoom ;
h2 * = inv_two_zoom ;
}
// FIXME: calculate a tighter value for depth will improve z-fighting
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float depth = 5.0f * ( float ) bbox . max_size ( ) ;
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: : glOrtho ( - w2 , w2 , - h2 , h2 , - depth , depth ) ;
break ;
}
case Camera : : CT_Perspective :
{
float bbox_r = ( float ) bbox . radius ( ) ;
float fov = PI * 45.0f / 180.0f ;
float fov_tan = tan ( 0.5f * fov ) ;
float cam_distance = 0.5f * bbox_r / fov_tan ;
set_camera_distance ( cam_distance ) ;
float nr = cam_distance - bbox_r * 1.1f ;
float fr = cam_distance + bbox_r * 1.1f ;
if ( nr < 1.0f )
nr = 1.0f ;
if ( fr < nr + 1.0f )
fr = nr + 1.0f ;
float h2 = fov_tan * nr ;
float w2 = h2 * w / h ;
: : glFrustum ( - w2 , w2 , - h2 , h2 , nr , fr ) ;
break ;
}
default :
{
throw std : : runtime_error ( " Invalid camera type. " ) ;
break ;
}
}
: : glMatrixMode ( GL_MODELVIEW ) ;
set_dirty ( false ) ;
}
GLVolumeCollection * GLCanvas3D : : get_volumes ( )
{
return m_volumes ;
}
void GLCanvas3D : : set_volumes ( GLVolumeCollection * volumes )
{
m_volumes = volumes ;
}
void GLCanvas3D : : set_bed_shape ( const Pointfs & shape )
{
m_bed . set_shape ( shape ) ;
}
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void GLCanvas3D : : set_auto_bed_shape ( )
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{
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// draw a default square bed around object center
const BoundingBoxf3 & bbox = volumes_bounding_box ( ) ;
coordf_t max_size = bbox . max_size ( ) ;
const Pointf3 & center = bbox . center ( ) ;
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Pointfs bed_shape ;
bed_shape . reserve ( 4 ) ;
bed_shape . emplace_back ( center . x - max_size , center . y - max_size ) ;
bed_shape . emplace_back ( center . x + max_size , center . y - max_size ) ;
bed_shape . emplace_back ( center . x + max_size , center . y + max_size ) ;
bed_shape . emplace_back ( center . x - max_size , center . y + max_size ) ;
set_bed_shape ( bed_shape ) ;
// Set the origin for painting of the coordinate system axes.
set_bed_origin ( Pointf ( center . x , center . y ) ) ;
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}
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const Pointf & GLCanvas3D : : get_bed_origin ( ) const
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{
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return m_bed . get_origin ( ) ;
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}
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void GLCanvas3D : : set_bed_origin ( const Pointf & origin )
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{
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m_bed . set_origin ( origin ) ;
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}
GLCanvas3D : : Camera : : EType GLCanvas3D : : get_camera_type ( ) const
{
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return m_camera . get_type ( ) ;
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}
void GLCanvas3D : : set_camera_type ( GLCanvas3D : : Camera : : EType type )
{
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m_camera . set_type ( type ) ;
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}
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std : : string GLCanvas3D : : get_camera_type_as_string ( ) const
{
return m_camera . get_type_as_string ( ) ;
}
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float GLCanvas3D : : get_camera_zoom ( ) const
{
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return m_camera . get_zoom ( ) ;
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}
void GLCanvas3D : : set_camera_zoom ( float zoom )
{
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m_camera . set_zoom ( zoom ) ;
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}
float GLCanvas3D : : get_camera_phi ( ) const
{
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return m_camera . get_phi ( ) ;
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}
void GLCanvas3D : : set_camera_phi ( float phi )
{
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m_camera . set_phi ( phi ) ;
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}
float GLCanvas3D : : get_camera_theta ( ) const
{
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return m_camera . get_theta ( ) ;
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}
void GLCanvas3D : : set_camera_theta ( float theta )
{
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m_camera . set_theta ( theta ) ;
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}
float GLCanvas3D : : get_camera_distance ( ) const
{
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return m_camera . get_distance ( ) ;
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}
void GLCanvas3D : : set_camera_distance ( float distance )
{
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m_camera . set_distance ( distance ) ;
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}
const Pointf3 & GLCanvas3D : : get_camera_target ( ) const
{
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return m_camera . get_target ( ) ;
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}
void GLCanvas3D : : set_camera_target ( const Pointf3 & target )
{
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m_camera . set_target ( target ) ;
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}
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BoundingBoxf3 GLCanvas3D : : bed_bounding_box ( ) const
{
return m_bed . get_bounding_box ( ) ;
}
BoundingBoxf3 GLCanvas3D : : volumes_bounding_box ( ) const
{
BoundingBoxf3 bb ;
if ( m_volumes ! = nullptr )
{
for ( const GLVolume * volume : m_volumes - > volumes )
{
if ( ! m_apply_zoom_to_volumes_filter | | ( ( volume ! = nullptr ) & & volume - > zoom_to_volumes ) )
bb . merge ( volume - > transformed_bounding_box ( ) ) ;
}
}
return bb ;
}
BoundingBoxf3 GLCanvas3D : : max_bounding_box ( ) const
{
BoundingBoxf3 bb = bed_bounding_box ( ) ;
bb . merge ( volumes_bounding_box ( ) ) ;
return bb ;
}
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void GLCanvas3D : : zoom_to_bed ( )
{
_zoom_to_bounding_box ( bed_bounding_box ( ) ) ;
}
void GLCanvas3D : : zoom_to_volumes ( )
{
m_apply_zoom_to_volumes_filter = true ;
_zoom_to_bounding_box ( volumes_bounding_box ( ) ) ;
m_apply_zoom_to_volumes_filter = false ;
}
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void GLCanvas3D : : select_view ( const std : : string & direction )
{
const float * dir_vec = nullptr ;
if ( direction = = " iso " )
dir_vec = VIEW_DEFAULT ;
else if ( direction = = " left " )
dir_vec = VIEW_LEFT ;
else if ( direction = = " right " )
dir_vec = VIEW_RIGHT ;
else if ( direction = = " top " )
dir_vec = VIEW_TOP ;
else if ( direction = = " bottom " )
dir_vec = VIEW_BOTTOM ;
else if ( direction = = " front " )
dir_vec = VIEW_FRONT ;
else if ( direction = = " rear " )
dir_vec = VIEW_REAR ;
if ( ( dir_vec ! = nullptr ) & & ! empty ( volumes_bounding_box ( ) ) )
{
m_camera . set_phi ( dir_vec [ 0 ] ) ;
m_camera . set_theta ( dir_vec [ 1 ] ) ;
m_on_viewport_changed_callback . call ( ) ;
if ( m_canvas ! = nullptr )
m_canvas - > Refresh ( ) ;
}
}
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void GLCanvas3D : : render ( )
{
m_bed . render ( ) ;
}
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void GLCanvas3D : : register_on_viewport_changed_callback ( void * callback )
{
if ( callback ! = nullptr )
m_on_viewport_changed_callback . register_callback ( callback ) ;
}
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void GLCanvas3D : : on_size ( wxSizeEvent & evt )
{
set_dirty ( true ) ;
}
void GLCanvas3D : : on_idle ( wxIdleEvent & evt )
{
if ( ! is_dirty ( ) | | ! is_shown_on_screen ( ) )
return ;
if ( m_canvas ! = nullptr )
{
std : : pair < int , int > size = _get_canvas_size ( ) ;
resize ( ( unsigned int ) size . first , ( unsigned int ) size . second ) ;
m_canvas - > Refresh ( ) ;
}
}
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void GLCanvas3D : : _zoom_to_bounding_box ( const BoundingBoxf3 & bbox )
{
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// Calculate the zoom factor needed to adjust viewport to bounding box.
float zoom = _get_zoom_to_bounding_box_factor ( bbox ) ;
if ( zoom > 0.0f )
{
set_camera_zoom ( zoom ) ;
// center view around bounding box center
set_camera_target ( bbox . center ( ) ) ;
m_on_viewport_changed_callback . call ( ) ;
if ( is_shown_on_screen ( ) )
{
std : : pair < int , int > size = _get_canvas_size ( ) ;
resize ( ( unsigned int ) size . first , ( unsigned int ) size . second ) ;
if ( m_canvas ! = nullptr )
m_canvas - > Refresh ( ) ;
}
}
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}
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std : : pair < int , int > GLCanvas3D : : _get_canvas_size ( ) const
{
std : : pair < int , int > ret ( 0 , 0 ) ;
if ( m_canvas ! = nullptr )
m_canvas - > GetSize ( & ret . first , & ret . second ) ;
return ret ;
}
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float GLCanvas3D : : _get_zoom_to_bounding_box_factor ( const BoundingBoxf3 & bbox ) const
{
float max_bb_size = bbox . max_size ( ) ;
if ( max_bb_size = = 0.0f )
return - 1.0f ;
// project the bbox vertices on a plane perpendicular to the camera forward axis
// then calculates the vertices coordinate on this plane along the camera xy axes
// we need the view matrix, we let opengl calculate it(same as done in render sub)
: : glMatrixMode ( GL_MODELVIEW ) ;
: : glLoadIdentity ( ) ;
if ( TURNTABLE_MODE )
{
// Turntable mode is enabled by default.
: : glRotatef ( - get_camera_theta ( ) , 1.0f , 0.0f , 0.0f ) ; //<2F> pitch
: : glRotatef ( get_camera_phi ( ) , 0.0f , 0.0f , 1.0f ) ; // yaw
}
else
{
// Shift the perspective camera.
Pointf3 camera_pos ( 0.0 , 0.0 , - ( coordf_t ) get_camera_distance ( ) ) ;
: : glTranslatef ( ( float ) camera_pos . x , ( float ) camera_pos . y , ( float ) camera_pos . z ) ;
// my @rotmat = quat_to_rotmatrix($self->quat); <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< TEMPORARY COMMENTED OUT
// glMultMatrixd_p(@rotmat[0..15]); <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< TEMPORARY COMMENTED OUT
}
const Pointf3 & target = get_camera_target ( ) ;
: : glTranslatef ( - ( float ) target . x , - ( float ) target . y , - ( float ) target . z ) ;
// get the view matrix back from opengl
GLfloat matrix [ 16 ] ;
: : glGetFloatv ( GL_MODELVIEW_MATRIX , matrix ) ;
// camera axes
Pointf3 right ( ( coordf_t ) matrix [ 0 ] , ( coordf_t ) matrix [ 4 ] , ( coordf_t ) matrix [ 8 ] ) ;
Pointf3 up ( ( coordf_t ) matrix [ 1 ] , ( coordf_t ) matrix [ 5 ] , ( coordf_t ) matrix [ 9 ] ) ;
Pointf3 forward ( ( coordf_t ) matrix [ 2 ] , ( coordf_t ) matrix [ 6 ] , ( coordf_t ) matrix [ 10 ] ) ;
Pointf3 bb_min = bbox . min ;
Pointf3 bb_max = bbox . max ;
Pointf3 bb_center = bbox . center ( ) ;
// bbox vertices in world space
std : : vector < Pointf3 > vertices ;
vertices . reserve ( 8 ) ;
vertices . push_back ( bb_min ) ;
vertices . emplace_back ( bb_max . x , bb_min . y , bb_min . z ) ;
vertices . emplace_back ( bb_max . x , bb_max . y , bb_min . z ) ;
vertices . emplace_back ( bb_min . x , bb_max . y , bb_min . z ) ;
vertices . emplace_back ( bb_min . x , bb_min . y , bb_max . z ) ;
vertices . emplace_back ( bb_max . x , bb_min . y , bb_max . z ) ;
vertices . push_back ( bb_max ) ;
vertices . emplace_back ( bb_min . x , bb_max . y , bb_max . z ) ;
coordf_t max_x = 0.0 ;
coordf_t max_y = 0.0 ;
// margin factor to give some empty space around the bbox
coordf_t margin_factor = 1.25 ;
for ( const Pointf3 v : vertices )
{
// project vertex on the plane perpendicular to camera forward axis
Pointf3 pos ( v . x - bb_center . x , v . y - bb_center . y , v . z - bb_center . z ) ;
Pointf3 proj_on_plane = pos - dot ( pos , forward ) * forward ;
// calculates vertex coordinate along camera xy axes
coordf_t x_on_plane = dot ( proj_on_plane , right ) ;
coordf_t y_on_plane = dot ( proj_on_plane , up ) ;
max_x = std : : max ( max_x , margin_factor * std : : abs ( x_on_plane ) ) ;
max_y = std : : max ( max_y , margin_factor * std : : abs ( y_on_plane ) ) ;
}
if ( ( max_x = = 0.0 ) | | ( max_y = = 0.0 ) )
return - 1.0f ;
max_x * = 2.0 ;
max_y * = 2.0 ;
std : : pair < int , int > cvs_size = _get_canvas_size ( ) ;
return ( float ) std : : min ( ( coordf_t ) cvs_size . first / max_x , ( coordf_t ) cvs_size . second / max_y ) ;
}
void GLCanvas3D : : _deregister_callbacks ( )
{
m_on_viewport_changed_callback . deregister_callback ( ) ;
}
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} // namespace GUI
} // namespace Slic3r
