@ -130,177 +130,108 @@ static bool is_horizontal(uint32_t axis) {
return axis & ( WLR_EDGE_LEFT | WLR_EDGE_RIGHT ) ;
return axis & ( WLR_EDGE_LEFT | WLR_EDGE_RIGHT ) ;
}
}
static int parallel_coord ( struct sway_container * c , uint32_t axis ) {
struct sway_container * container_find_resize_parent ( struct sway_container * con ,
return is_horizontal ( axis ) ? c - > x : c - > y ;
uint32_t axis ) {
}
enum sway_container_layout parallel_layout =
is_horizontal ( axis ) ? L_HORIZ : L_VERT ;
static int parallel_size ( struct sway_container * c , uint32_t axis ) {
bool allow_first = axis ! = WLR_EDGE_TOP & & axis ! = WLR_EDGE_LEFT ;
return is_horizontal ( axis ) ? c - > width : c - > height ;
bool allow_last = axis ! = WLR_EDGE_RIGHT & & axis ! = WLR_EDGE_BOTTOM ;
}
static void container_recursive_resize ( struct sway_container * container ,
while ( con ) {
double amount , enum wlr_edges edge ) {
list_t * siblings = container_get_siblings ( con ) ;
bool layout_match = true ;
int index = container_sibling_index ( con ) ;
wlr_log ( WLR_DEBUG , " Resizing %p with amount: %f " , container , amount ) ;
if ( container_parent_layout ( con ) = = parallel_layout & &
if ( edge & ( WLR_EDGE_LEFT | WLR_EDGE_RIGHT ) ) {
siblings - > length > 1 & & ( allow_first | | index > 0 ) & &
container - > width + = amount ;
( allow_last | | index < siblings - > length - 1 ) ) {
layout_match = container - > layout = = L_HORIZ ;
return con ;
} else if ( edge & ( WLR_EDGE_TOP | WLR_EDGE_BOTTOM ) ) {
container - > height + = amount ;
layout_match = container - > layout = = L_VERT ;
}
if ( container - > children ) {
for ( int i = 0 ; i < container - > children - > length ; i + + ) {
struct sway_container * child = container - > children - > items [ i ] ;
double amt = layout_match ?
amount / container - > children - > length : amount ;
container_recursive_resize ( child , amt , edge ) ;
}
}
con = con - > parent ;
}
}
return NULL ;
}
}
static void resize_tiled ( struct sway_container * parent , int amount ,
void container_resize_tiled ( struct sway_container * con ,
uint32_t axis ) {
uint32_t axis , int amount ) {
struct sway_container * focused = parent ;
if ( ! con ) {
if ( ! parent ) {
return ;
return ;
}
}
enum sway_container_layout parallel_layout =
con = container_find_resize_parent ( con , axis ) ;
is_horizontal ( axis ) ? L_HORIZ : L_VERT ;
if ( ! con ) {
int minor_weight = 0 ;
int major_weight = 0 ;
while ( parent ) {
list_t * siblings = container_get_siblings ( parent ) ;
if ( container_parent_layout ( parent ) = = parallel_layout ) {
for ( int i = 0 ; i < siblings - > length ; i + + ) {
struct sway_container * sibling = siblings - > items [ i ] ;
int sibling_pos = parallel_coord ( sibling , axis ) ;
int focused_pos = parallel_coord ( focused , axis ) ;
int parent_pos = parallel_coord ( parent , axis ) ;
if ( sibling_pos ! = focused_pos ) {
if ( sibling_pos < parent_pos ) {
minor_weight + + ;
} else if ( sibling_pos > parent_pos ) {
major_weight + + ;
}
}
}
if ( major_weight | | minor_weight ) {
break ;
}
}
parent = parent - > parent ;
}
if ( ! parent ) {
// Can't resize in this direction
// Can't resize in this direction
return ;
return ;
}
}
// Implement up/down/left/right direction by zeroing one of the weights
// For HORIZONTAL or VERTICAL, we are growing in two directions so select
if ( axis = = WLR_EDGE_TOP | | axis = = WLR_EDGE_LEFT ) {
// both adjacent siblings. For RIGHT or DOWN, just select the next sibling.
major_weight = 0 ;
// For LEFT or UP, convert it to a RIGHT or DOWN resize and reassign con to
} else if ( axis = = WLR_EDGE_RIGHT | | axis = = WLR_EDGE_BOTTOM ) {
// the previous sibling.
minor_weight = 0 ;
struct sway_container * prev = NULL ;
}
struct sway_container * next = NULL ;
list_t * siblings = container_get_siblings ( con ) ;
bool horizontal = is_horizontal ( axis ) ;
int index = container_sibling_index ( con ) ;
int min_sane = horizontal ? MIN_SANE_W : MIN_SANE_H ;
if ( axis = = AXIS_HORIZONTAL | | axis = = AXIS_VERTICAL ) {
//TODO: Ensure rounding is done in such a way that there are NO pixel leaks
prev = siblings - > items [ index - 1 ] ;
// ^ ?????
next = siblings - > items [ index + 1 ] ;
list_t * siblings = container_get_siblings ( parent ) ;
} else if ( axis = = WLR_EDGE_TOP | | axis = = WLR_EDGE_LEFT ) {
if ( ! sway_assert ( index > 0 , " Didn't expect first child " ) ) {
for ( int i = 0 ; i < siblings - > length ; i + + ) {
return ;
struct sway_container * sibling = siblings - > items [ i ] ;
int sibling_pos = parallel_coord ( sibling , axis ) ;
int focused_pos = parallel_coord ( focused , axis ) ;
int parent_pos = parallel_coord ( parent , axis ) ;
int sibling_size = parallel_size ( sibling , axis ) ;
int parent_size = parallel_size ( parent , axis ) ;
if ( sibling_pos ! = focused_pos ) {
if ( sibling_pos < parent_pos & & minor_weight ) {
double pixels = - amount / minor_weight ;
if ( major_weight & & ( sibling_size + pixels / 2 ) < min_sane ) {
return ; // Too small
} else if ( ! major_weight & & sibling_size + pixels < min_sane ) {
return ; // Too small
}
} else if ( sibling_pos > parent_pos & & major_weight ) {
double pixels = - amount / major_weight ;
if ( minor_weight & & ( sibling_size + pixels / 2 ) < min_sane ) {
return ; // Too small
} else if ( ! minor_weight & & sibling_size + pixels < min_sane ) {
return ; // Too small
}
}
}
next = con ;
con = siblings - > items [ index - 1 ] ;
amount = - amount ;
} else {
} else {
double pixels = amount ;
if ( ! sway_assert ( index < siblings - > length - 1 ,
if ( parent_size + pixels < min_sane ) {
" Didn't expect last child " ) ) {
return ; // Too small
return ;
}
}
}
next = siblings - > items [ index + 1 ] ;
}
}
enum wlr_edges minor_edge = horizontal ? WLR_EDGE_LEFT : WLR_EDGE_TOP ;
// Apply new dimensions
enum wlr_edges major_edge = horizontal ? WLR_EDGE_RIGHT : WLR_EDGE_BOTTOM ;
int sibling_amount = prev ? amount / 2 : amount ;
for ( int i = 0 ; i < siblings - > length ; i + + ) {
struct sway_container * sibling = siblings - > items [ i ] ;
int sibling_pos = parallel_coord ( sibling , axis ) ;
if ( is_horizontal ( axis ) ) {
int focused_pos = parallel_coord ( focused , axis ) ;
if ( con - > width + amount < MIN_SANE_W ) {
int parent_pos = parallel_coord ( parent , axis ) ;
return ;
if ( sibling_pos ! = focused_pos ) {
if ( sibling_pos < parent_pos & & minor_weight ) {
double pixels = - 1 * amount ;
pixels / = minor_weight ;
if ( major_weight ) {
container_recursive_resize ( sibling , pixels / 2 , major_edge ) ;
} else {
container_recursive_resize ( sibling , pixels , major_edge ) ;
}
}
} else if ( sibling_pos > parent_pos & & major_weight ) {
if ( next - > width - sibling_amount < MIN_SANE_W ) {
double pixels = - 1 * amount ;
return ;
pixels / = major_weight ;
if ( minor_weight ) {
container_recursive_resize ( sibling , pixels / 2 , minor_edge ) ;
} else {
container_recursive_resize ( sibling , pixels , minor_edge ) ;
}
}
if ( prev & & prev - > width - sibling_amount < MIN_SANE_W ) {
return ;
}
con - > width + = amount ;
next - > width - = sibling_amount ;
if ( prev ) {
prev - > width - = sibling_amount ;
}
}
} else {
} else {
if ( major_weight ! = 0 & & minor_weight ! = 0 ) {
if ( con - > height + amount < MIN_SANE_H ) {
double pixels = amount ;
return ;
pixels / = 2 ;
container_recursive_resize ( parent , pixels , minor_edge ) ;
container_recursive_resize ( parent , pixels , major_edge ) ;
} else if ( major_weight ) {
container_recursive_resize ( parent , amount , major_edge ) ;
} else if ( minor_weight ) {
container_recursive_resize ( parent , amount , minor_edge ) ;
}
}
if ( next - > height - sibling_amount < MIN_SANE_H ) {
return ;
}
if ( prev & & prev - > height - sibling_amount < MIN_SANE_H ) {
return ;
}
con - > height + = amount ;
next - > height - = sibling_amount ;
if ( prev ) {
prev - > height - = sibling_amount ;
}
}
}
}
if ( parent - > parent ) {
if ( con - > parent ) {
arrange_container ( parent - > parent ) ;
arrange_container ( con - > parent ) ;
} else {
} else {
arrange_workspace ( parent - > workspace ) ;
arrange_workspace ( con - > workspace ) ;
}
}
}
}
void container_resize_tiled ( struct sway_container * parent ,
enum wlr_edges edge , int amount ) {
resize_tiled ( parent , amount , edge ) ;
}
/**
/**
* Implement ` resize < grow | shrink > ` for a floating container .
* Implement ` resize < grow | shrink > ` for a floating container .
*/
*/
@ -379,7 +310,7 @@ static struct cmd_results *resize_adjust_tiled(uint32_t axis,
double old_width = current - > width ;
double old_width = current - > width ;
double old_height = current - > height ;
double old_height = current - > height ;
resize_tiled( current , a mount- > amount , axis ) ;
container_ resize_tiled( current , a xis, a mount- > amount ) ;
if ( current - > width = = old_width & & current - > height = = old_height ) {
if ( current - > width = = old_width & & current - > height = = old_height ) {
return cmd_results_new ( CMD_INVALID , " Cannot resize any further " ) ;
return cmd_results_new ( CMD_INVALID , " Cannot resize any further " ) ;
}
}
@ -407,7 +338,8 @@ static struct cmd_results *resize_set_tiled(struct sway_container *con,
width - > unit = RESIZE_UNIT_PX ;
width - > unit = RESIZE_UNIT_PX ;
}
}
if ( width - > unit = = RESIZE_UNIT_PX ) {
if ( width - > unit = = RESIZE_UNIT_PX ) {
resize_tiled ( con , width - > amount - con - > width , AXIS_HORIZONTAL ) ;
container_resize_tiled ( con , AXIS_HORIZONTAL ,
width - > amount - con - > width ) ;
}
}
}
}
@ -427,7 +359,8 @@ static struct cmd_results *resize_set_tiled(struct sway_container *con,
height - > unit = RESIZE_UNIT_PX ;
height - > unit = RESIZE_UNIT_PX ;
}
}
if ( height - > unit = = RESIZE_UNIT_PX ) {
if ( height - > unit = = RESIZE_UNIT_PX ) {
resize_tiled ( con , height - > amount - con - > height , AXIS_VERTICAL ) ;
container_resize_tiled ( con , AXIS_VERTICAL ,
height - > amount - con - > height ) ;
}
}
}
}