@ -2,15 +2,15 @@
# include "output.h"
# include "output.h"
# include "log.h"
# include "log.h"
swayc_t * output_by_name ( const char * name ) {
swayc_t * output_by_name ( const char * name , const struct wlc_point * abs_pos ) {
if ( strcasecmp ( name , " left " ) = = 0 ) {
if ( strcasecmp ( name , " left " ) = = 0 ) {
return swayc_adjacent_output ( NULL , MOVE_LEFT );
return swayc_adjacent_output ( NULL , MOVE_LEFT , abs_pos , true );
} else if ( strcasecmp ( name , " right " ) = = 0 ) {
} else if ( strcasecmp ( name , " right " ) = = 0 ) {
return swayc_adjacent_output ( NULL , MOVE_RIGHT );
return swayc_adjacent_output ( NULL , MOVE_RIGHT , abs_pos , true );
} else if ( strcasecmp ( name , " up " ) = = 0 ) {
} else if ( strcasecmp ( name , " up " ) = = 0 ) {
return swayc_adjacent_output ( NULL , MOVE_UP );
return swayc_adjacent_output ( NULL , MOVE_UP , abs_pos , true );
} else if ( strcasecmp ( name , " down " ) = = 0 ) {
} else if ( strcasecmp ( name , " down " ) = = 0 ) {
return swayc_adjacent_output ( NULL , MOVE_DOWN );
return swayc_adjacent_output ( NULL , MOVE_DOWN , abs_pos , true );
} else {
} else {
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
swayc_t * c = root_container . children - > items [ i ] ;
swayc_t * c = root_container . children - > items [ i ] ;
@ -22,66 +22,126 @@ swayc_t *output_by_name(const char* name) {
return NULL ;
return NULL ;
}
}
swayc_t * swayc_adjacent_output ( swayc_t * output , enum movement_direction dir ) {
// Position is where on the edge (as absolute position) the adjacent output should be searched for.
// TODO: This implementation is naïve: We assume all outputs are
swayc_t * swayc_adjacent_output ( swayc_t * output , enum movement_direction dir ,
// perfectly aligned (ie. only a single output per edge which covers
const struct wlc_point * abs_pos , bool pick_closest ) {
// the whole edge).
if ( ! output ) {
if ( ! output ) {
output = swayc_active_output ( ) ;
output = swayc_active_output ( ) ;
}
}
// In order to find adjacent outputs we need to test that the outputs are
// aligned on one axis (decided by the direction given) and that the given
// position is within the edge of the adjacent output. If no such output
// exists we pick the adjacent output within the edge that is closest to
// the given position, if any.
swayc_t * adjacent = NULL ;
swayc_t * adjacent = NULL ;
char * dir_text = NULL ;
switch ( dir ) {
switch ( dir ) {
case MOVE_LEFT :
case MOVE_LEFT :
case MOVE_RIGHT : ;
double delta_y = 0 ;
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
swayc_t * c = root_container . children - > items [ i ] ;
swayc_t * c = root_container . children - > items [ i ] ;
if ( c = = output | | c - > type ! = C_OUTPUT ) {
if ( c = = output | | c - > type ! = C_OUTPUT ) {
continue ;
continue ;
}
}
if ( c - > y = = output - > y & & c - > x + c - > width = = output - > x ) {
bool x_aligned = dir = = MOVE_LEFT ?
sway_log ( L_DEBUG , " %s is left of current output %s " , c - > name , output - > name ) ;
c - > x + c - > width = = output - > x :
adjacent = c ;
c - > x = = output - > x + output - > width ;
break ;
if ( ! x_aligned ) {
}
}
break ;
case MOVE_RIGHT :
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
swayc_t * c = root_container . children - > items [ i ] ;
if ( c = = output | | c - > type ! = C_OUTPUT ) {
continue ;
continue ;
}
}
if ( c- > y = = output - > y & & output - > x + output - > width = = c - > x ) {
if ( abs_pos - > y > = c - > y & & abs_pos - > y < = c - > y + c - > height ) {
sway_log ( L_DEBUG , " %s is right of current output %s " , c - > name , output - > name ) ;
delta_y = 0 ;
adjacent = c ;
adjacent = c ;
break ;
break ;
} else if ( pick_closest ) {
// track closest adjacent output
double top_y = c - > y , bottom_y = c - > y + c - > height ;
if ( top_y > = output - > y & & top_y < = output - > y + output - > height ) {
double delta = top_y - abs_pos - > y ;
if ( delta < 0 ) delta = - delta ;
if ( delta < delta_y | | ! adjacent ) {
delta_y = delta ;
adjacent = c ;
}
}
// we check both points and pick the closest
if ( bottom_y > = output - > y & & bottom_y < = output - > y + output - > height ) {
double delta = bottom_y - abs_pos - > y ;
if ( delta < 0 ) delta = - delta ;
if ( delta < delta_y | | ! adjacent ) {
delta_y = delta ;
adjacent = c ;
}
}
}
}
}
}
dir_text = dir = = MOVE_LEFT ? " left of " : " right of " ;
if ( adjacent & & delta_y = = 0 ) {
sway_log ( L_DEBUG , " %s (%.0fx%.0f+%.0f+%.0f) is %s current output %s (y-position %i) " ,
adjacent - > name , adjacent - > width , adjacent - > height , adjacent - > x , adjacent - > y ,
dir_text , output - > name , abs_pos - > y ) ;
} else if ( adjacent ) {
// so we end up picking the closest adjacent output because
// there is no directly adjacent to the given position
sway_log ( L_DEBUG , " %s (%.0fx%.0f+%.0f+%.0f) is %s current output %s (y-position %i, delta: %.0f) " ,
adjacent - > name , adjacent - > width , adjacent - > height , adjacent - > x , adjacent - > y ,
dir_text , output - > name , abs_pos - > y , delta_y ) ;
}
break ;
break ;
case MOVE_UP :
case MOVE_UP :
case MOVE_DOWN : ;
double delta_x = 0 ;
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
swayc_t * c = root_container . children - > items [ i ] ;
swayc_t * c = root_container . children - > items [ i ] ;
if ( c = = output | | c - > type ! = C_OUTPUT ) {
if ( c = = output | | c - > type ! = C_OUTPUT ) {
continue ;
continue ;
}
}
if ( output - > x = = c - > x & & c - > y + c - > height = = output - > y ) {
bool y_aligned = dir = = MOVE_UP ?
sway_log ( L_DEBUG , " %s is above current output %s " , c - > name , output - > name ) ;
c - > y + c - > height = = output - > y :
adjacent = c ;
c - > y = = output - > y + output - > height ;
break ;
if ( ! y_aligned ) {
}
}
break ;
case MOVE_DOWN :
for ( int i = 0 ; i < root_container . children - > length ; + + i ) {
swayc_t * c = root_container . children - > items [ i ] ;
if ( c = = output | | c - > type ! = C_OUTPUT ) {
continue ;
continue ;
}
}
if ( output- > x = = c - > x & & output - > y + output - > height = = c - > y ) {
if ( abs_pos - > x > = c - > x & & abs_pos - > x < = c - > x + c - > width ) {
sway_log ( L_DEBUG , " %s is below current output %s " , c - > name , output - > name ) ;
delta_x = 0 ;
adjacent = c ;
adjacent = c ;
break ;
break ;
} else if ( pick_closest ) {
// track closest adjacent output
double left_x = c - > x , right_x = c - > x + c - > width ;
if ( left_x > = output - > x & & left_x < = output - > x + output - > width ) {
double delta = left_x - abs_pos - > x ;
if ( delta < 0 ) delta = - delta ;
if ( delta < delta_x | | ! adjacent ) {
delta_x = delta ;
adjacent = c ;
}
}
// we check both points and pick the closest
if ( right_x > = output - > x & & right_x < = output - > x + output - > width ) {
double delta = right_x - abs_pos - > x ;
if ( delta < 0 ) delta = - delta ;
if ( delta < delta_x | | ! adjacent ) {
delta_x = delta ;
adjacent = c ;
}
}
}
}
}
}
dir_text = dir = = MOVE_UP ? " above " : " below " ;
if ( adjacent & & delta_x = = 0 ) {
sway_log ( L_DEBUG , " %s (%.0fx%.0f+%.0f+%.0f) is %s current output %s (x-position %i) " ,
adjacent - > name , adjacent - > width , adjacent - > height , adjacent - > x , adjacent - > y ,
dir_text , output - > name , abs_pos - > x ) ;
} else if ( adjacent ) {
// so we end up picking the closest adjacent output because
// there is no directly adjacent to the given position
sway_log ( L_DEBUG , " %s (%.0fx%.0f+%.0f+%.0f) is %s current output %s (x-position %i, delta: %.0f) " ,
adjacent - > name , adjacent - > width , adjacent - > height , adjacent - > x , adjacent - > y ,
dir_text , output - > name , abs_pos - > x , delta_x ) ;
}
break ;
break ;
default :
default :
sway_abort ( " Function called with invalid argument. " ) ;
sway_abort ( " Function called with invalid argument. " ) ;
@ -89,3 +149,31 @@ swayc_t *swayc_adjacent_output(swayc_t *output, enum movement_direction dir) {
}
}
return adjacent ;
return adjacent ;
}
}
void get_absolute_position ( swayc_t * container , struct wlc_point * point ) {
if ( ! container | | ! point )
sway_abort ( " Need container and wlc_point (was %p, %p). " , container , point ) ;
if ( container - > type = = C_OUTPUT ) {
// Coordinates are already absolute.
point - > x = container - > x ;
point - > y = container - > y ;
} else {
swayc_t * output = swayc_parent_by_type ( container , C_OUTPUT ) ;
if ( container - > type = = C_WORKSPACE ) {
// Workspace coordinates are actually wrong/arbitrary, but should
// be same as output.
point - > x = output - > x ;
point - > y = output - > y ;
} else {
point - > x = output - > x + container - > x ;
point - > y = output - > y + container - > y ;
}
}
}
void get_absolute_center_position ( swayc_t * container , struct wlc_point * point ) {
get_absolute_position ( container , point ) ;
point - > x + = container - > width / 2 ;
point - > y + = container - > height / 2 ;
}