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blender-archive/source/blender/editors/interface/interface_align.c
Valentin 5ac4778056 Cleanup: convert gforge task ID's to phabricator format 
Cleanup old tracker task format to the new. e.g: [#34039] to T34039

Ref D8718
2020-09-30 20:11:06 +10:00

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/*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* The Original Code is Copyright (C) 2015 by Blender Foundation.
* All rights reserved.
*/
/** \file
* \ingroup edinterface
*/
#include "DNA_screen_types.h"
#include "DNA_userdef_types.h"
#include "BLI_listbase.h"
#include "BLI_math.h"
#include "BLI_rect.h"
#include "UI_interface.h"
#include "interface_intern.h"
#include "MEM_guardedalloc.h"
#ifdef USE_UIBUT_SPATIAL_ALIGN
/**
* This struct stores a (simplified) 2D representation of all buttons of a same align group,
* with their immediate neighbors (if found),
* and needed value to compute 'stitching' of aligned buttons.
*
* \note This simplistic struct cannot fully represent complex layouts where buttons share some
* 'align space' with several others (see schema below), we'd need linked list and more
* complex code to handle that. However, looks like we can do without that for now,
* which is rather lucky!
*
* <pre>
* +--------+-------+
* | BUT 1 | BUT 2 | BUT 3 has two 'top' neighbors...
* |----------------| => In practice, we only store one of BUT 1 or 2 (which ones is not
* | BUT 3 | really deterministic), and assume the other stores a ref to BUT 3.
* +----------------+
* </pre>
*
* This will probably not work in all possible cases,
* but not sure we want to support such exotic cases anyway.
*/
typedef struct ButAlign {
uiBut *but;
/* Neighbor buttons */
struct ButAlign *neighbors[4];
/* Pointers to coordinates (rctf values) of the button. */
float *borders[4];
/* Distances to the neighbors. */
float dists[4];
/* Flags, used to mark whether we should 'stitch'
* the corners of this button with its neighbors' ones. */
char flags[4];
} ButAlign;
/* Side-related enums and flags. */
enum {
/* Sides (used as indices, order is **crucial**,
* this allows us to factorize code in a loop over the four sides). */
LEFT = 0,
TOP = 1,
RIGHT = 2,
DOWN = 3,
TOTSIDES = 4,
/* Stitch flags, built from sides values. */
STITCH_LEFT = 1 << LEFT,
STITCH_TOP = 1 << TOP,
STITCH_RIGHT = 1 << RIGHT,
STITCH_DOWN = 1 << DOWN,
};
/* Mapping between 'our' sides and 'public' UI_BUT_ALIGN flags, order must match enum above. */
# define SIDE_TO_UI_BUT_ALIGN \
{ \
UI_BUT_ALIGN_LEFT, UI_BUT_ALIGN_TOP, UI_BUT_ALIGN_RIGHT, UI_BUT_ALIGN_DOWN \
}
/* Given one side, compute the three other ones */
# define SIDE1(_s) (((_s) + 1) % TOTSIDES)
# define OPPOSITE(_s) (((_s) + 2) % TOTSIDES)
# define SIDE2(_s) (((_s) + 3) % TOTSIDES)
/* 0: LEFT/RIGHT sides; 1 = TOP/DOWN sides. */
# define IS_COLUMN(_s) ((_s) % 2)
/* Stitch flag from side value. */
# define STITCH(_s) (1 << (_s))
/* Max distance between to buttons for them to be 'mergeable'. */
# define MAX_DELTA 0.45f * max_ii(UI_UNIT_Y, UI_UNIT_X)
bool ui_but_can_align(const uiBut *but)
{
const bool btype_can_align = !ELEM(but->type,
UI_BTYPE_LABEL,
UI_BTYPE_CHECKBOX,
UI_BTYPE_CHECKBOX_N,
UI_BTYPE_TAB,
UI_BTYPE_SEPR,
UI_BTYPE_SEPR_LINE,
UI_BTYPE_SEPR_SPACER);
return (btype_can_align && (BLI_rctf_size_x(&but->rect) > 0.0f) &&
(BLI_rctf_size_y(&but->rect) > 0.0f));
}
/**
* This function checks a pair of buttons (assumed in a same align group),
* and if they are neighbors, set needed data accordingly.
*
* \note It is designed to be called in total random order of buttons.
* Order-based optimizations are done by caller.
*/
static void block_align_proximity_compute(ButAlign *butal, ButAlign *butal_other)
{
/* That's the biggest gap between two borders to consider them 'alignable'. */
const float max_delta = MAX_DELTA;
float delta, delta_side_opp;
int side, side_opp;
const bool butal_can_align = ui_but_can_align(butal->but);
const bool butal_other_can_align = ui_but_can_align(butal_other->but);
const bool buts_share[2] = {
/* Sharing same line? */
!((*butal->borders[DOWN] >= *butal_other->borders[TOP]) ||
(*butal->borders[TOP] <= *butal_other->borders[DOWN])),
/* Sharing same column? */
!((*butal->borders[LEFT] >= *butal_other->borders[RIGHT]) ||
(*butal->borders[RIGHT] <= *butal_other->borders[LEFT])),
};
/* Early out in case buttons share no column or line, or if none can align... */
if (!(buts_share[0] || buts_share[1]) || !(butal_can_align || butal_other_can_align)) {
return;
}
for (side = 0; side < RIGHT; side++) {
/* We are only interested in buttons which share a same line
* (LEFT/RIGHT sides) or column (TOP/DOWN sides). */
if (buts_share[IS_COLUMN(side)]) {
side_opp = OPPOSITE(side);
/* We check both opposite sides at once, because with very small buttons,
* delta could be below max_delta for the wrong side
* (that is, in horizontal case, the total width of two buttons can be below max_delta).
* We rely on exact zero value here as an 'already processed' flag,
* so ensure we never actually set a zero value at this stage.
* FLT_MIN is zero-enough for UI position computing. ;) */
delta = max_ff(fabsf(*butal->borders[side] - *butal_other->borders[side_opp]), FLT_MIN);
delta_side_opp = max_ff(fabsf(*butal->borders[side_opp] - *butal_other->borders[side]),
FLT_MIN);
if (delta_side_opp < delta) {
SWAP(int, side, side_opp);
delta = delta_side_opp;
}
if (delta < max_delta) {
/* We are only interested in neighbors that are
* at least as close as already found ones. */
if (delta <= butal->dists[side]) {
{
/* We found an as close or closer neighbor.
* If both buttons are alignable, we set them as each other neighbors.
* Else, we have an unalignable one, we need to reset the others matching
* neighbor to NULL if its 'proximity distance'
* is really lower with current one.
*
* NOTE: We cannot only execute that piece of code in case we found a
* **closer** neighbor, due to the limited way we represent neighbors
* (buttons only know **one** neighbor on each side, when they can
* actually have several ones), it would prevent some buttons to be
* properly 'neighborly-initialized'. */
if (butal_can_align && butal_other_can_align) {
butal->neighbors[side] = butal_other;
butal_other->neighbors[side_opp] = butal;
}
else if (butal_can_align && (delta < butal->dists[side])) {
butal->neighbors[side] = NULL;
}
else if (butal_other_can_align && (delta < butal_other->dists[side_opp])) {
butal_other->neighbors[side_opp] = NULL;
}
butal->dists[side] = butal_other->dists[side_opp] = delta;
}
if (butal_can_align && butal_other_can_align) {
const int side_s1 = SIDE1(side);
const int side_s2 = SIDE2(side);
const int stitch = STITCH(side);
const int stitch_opp = STITCH(side_opp);
if (butal->neighbors[side] == NULL) {
butal->neighbors[side] = butal_other;
}
if (butal_other->neighbors[side_opp] == NULL) {
butal_other->neighbors[side_opp] = butal;
}
/* We have a pair of neighbors, we have to check whether we
* can stitch their matching corners.
* E.g. if butal_other is on the left of butal (that is, side == LEFT),
* if both TOP (side_s1) coordinates of buttons are close enough,
* we can stitch their upper matching corners,
* and same for DOWN (side_s2) side. */
delta = fabsf(*butal->borders[side_s1] - *butal_other->borders[side_s1]);
if (delta < max_delta) {
butal->flags[side_s1] |= stitch;
butal_other->flags[side_s1] |= stitch_opp;
}
delta = fabsf(*butal->borders[side_s2] - *butal_other->borders[side_s2]);
if (delta < max_delta) {
butal->flags[side_s2] |= stitch;
butal_other->flags[side_s2] |= stitch_opp;
}
}
}
/* We assume two buttons can only share one side at most - for until
* we have spherical UI. */
return;
}
}
}
}
/**
* This function takes care of case described in this schema:
*
* <pre>
* +-----------+-----------+
* | BUT 1 | BUT 2 |
* |-----------------------+
* | BUT 3 |
* +-----------+
* </pre>
*
* Here, BUT 3 RIGHT side would not get 'dragged' to align with BUT 1 RIGHT side,
* since BUT 3 has not RIGHT neighbor.
* So, this function, when called with BUT 1, will 'walk' the whole column in \a side_s1 direction
* (TOP or DOWN when called for RIGHT side), and force buttons like BUT 3 to align as needed,
* if BUT 1 and BUT 3 were detected as needing top-right corner stitching in
* #block_align_proximity_compute() step.
*
* \note To avoid doing this twice, some stitching flags are cleared to break the
* 'stitching connection' between neighbors.
*/
static void block_align_stitch_neighbors(ButAlign *butal,
const int side,
const int side_opp,
const int side_s1,
const int side_s2,
const int align,
const int align_opp,
const float co)
{
ButAlign *butal_neighbor;
const int stitch_s1 = STITCH(side_s1);
const int stitch_s2 = STITCH(side_s2);
/* We have to check stitching flags on both sides of the stitching,
* since we only clear one of them flags to break any future loop on same 'columns/side' case.
* Also, if butal is spanning over several rows or columns of neighbors,
* it may have both of its stitching flags
* set, but would not be the case of its immediate neighbor! */
while ((butal->flags[side] & stitch_s1) && (butal = butal->neighbors[side_s1]) &&
(butal->flags[side] & stitch_s2)) {
butal_neighbor = butal->neighbors[side];
/* If we actually do have a neighbor, we directly set its values accordingly,
* and clear its matching 'dist' to prevent it being set again later... */
if (butal_neighbor) {
butal->but->drawflag |= align;
butal_neighbor->but->drawflag |= align_opp;
*butal_neighbor->borders[side_opp] = co;
butal_neighbor->dists[side_opp] = 0.0f;
}
/* See definition of UI_BUT_ALIGN_STITCH_LEFT/TOP for reason of this... */
else if (side == LEFT) {
butal->but->drawflag |= UI_BUT_ALIGN_STITCH_LEFT;
}
else if (side == TOP) {
butal->but->drawflag |= UI_BUT_ALIGN_STITCH_TOP;
}
*butal->borders[side] = co;
butal->dists[side] = 0.0f;
/* Clearing one of the 'flags pair' here is enough to prevent this loop running on
* the same column, side and direction again. */
butal->flags[side] &= ~stitch_s2;
}
}
/**
* Helper to sort ButAlign items by:
* - Their align group.
* - Their vertical position.
* - Their horizontal position.
*/
static int ui_block_align_butal_cmp(const void *a, const void *b)
{
const ButAlign *butal = a;
const ButAlign *butal_other = b;
/* Sort by align group. */
if (butal->but->alignnr != butal_other->but->alignnr) {
return butal->but->alignnr - butal_other->but->alignnr;
}
/* Sort vertically.
* Note that Y of buttons is decreasing (first buttons have higher Y value than later ones). */
if (*butal->borders[TOP] != *butal_other->borders[TOP]) {
return (*butal_other->borders[TOP] > *butal->borders[TOP]) ? 1 : -1;
}
/* Sort horizontally. */
if (*butal->borders[LEFT] != *butal_other->borders[LEFT]) {
return (*butal->borders[LEFT] > *butal_other->borders[LEFT]) ? 1 : -1;
}
/* XXX We cannot actually assert here, since in some very compressed space cases,
* stupid UI code produces widgets which have the same TOP and LEFT positions...
* We do not care really,
* because this happens when UI is way too small to be usable anyway. */
/* BLI_assert(0); */
return 0;
}
static void ui_block_align_but_to_region(uiBut *but, const ARegion *region)
{
rctf *rect = &but->rect;
const float but_width = BLI_rctf_size_x(rect);
const float but_height = BLI_rctf_size_y(rect);
const float outline_px = U.pixelsize; /* This may have to be made more variable. */
switch (but->drawflag & UI_BUT_ALIGN) {
case UI_BUT_ALIGN_TOP:
rect->ymax = region->winy + outline_px;
rect->ymin = but->rect.ymax - but_height;
break;
case UI_BUT_ALIGN_DOWN:
rect->ymin = -outline_px;
rect->ymax = rect->ymin + but_height;
break;
case UI_BUT_ALIGN_LEFT:
rect->xmin = -outline_px;
rect->xmax = rect->xmin + but_width;
break;
case UI_BUT_ALIGN_RIGHT:
rect->xmax = region->winx + outline_px;
rect->xmin = rect->xmax - but_width;
break;
default:
/* Tabs may be shown in unaligned regions too, they just appear as regular buttons then. */
break;
}
}
/**
* Compute the alignment of all 'align groups' of buttons in given block.
*
* This is using an order-independent algorithm,
* i.e. alignment of buttons should be OK regardless of order in which
* they are added to the block.
*/
void ui_block_align_calc(uiBlock *block, const ARegion *region)
{
int num_buttons = 0;
const int sides_to_ui_but_align_flags[4] = SIDE_TO_UI_BUT_ALIGN;
ButAlign *butal_array;
ButAlign *butal, *butal_other;
int side;
/* First loop: we count number of buttons belonging to an align group,
* and clear their align flag.
* Tabs get some special treatment here, they get aligned to region border. */
LISTBASE_FOREACH (uiBut *, but, &block->buttons) {
/* special case: tabs need to be aligned to a region border, drawflag tells which one */
if (but->type == UI_BTYPE_TAB) {
ui_block_align_but_to_region(but, region);
}
else {
/* Clear old align flags. */
but->drawflag &= ~UI_BUT_ALIGN_ALL;
}
if (but->alignnr != 0) {
num_buttons++;
}
}
if (num_buttons < 2) {
/* No need to go further if we have nothing to align... */
return;
}
/* Note that this is typically less than ~20, and almost always under ~100.
* Even so, we can't ensure this value won't exceed available stack memory.
* Fallback to allocation instead of using #alloca, see: T78636. */
ButAlign butal_array_buf[256];
if (num_buttons <= ARRAY_SIZE(butal_array_buf)) {
butal_array = butal_array_buf;
}
else {
butal_array = MEM_mallocN(sizeof(*butal_array) * num_buttons, __func__);
}
memset(butal_array, 0, sizeof(*butal_array) * (size_t)num_buttons);
/* Second loop: we initialize our ButAlign data for each button. */
butal = butal_array;
LISTBASE_FOREACH (uiBut *, but, &block->buttons) {
if (but->alignnr != 0) {
butal->but = but;
butal->borders[LEFT] = &but->rect.xmin;
butal->borders[RIGHT] = &but->rect.xmax;
butal->borders[DOWN] = &but->rect.ymin;
butal->borders[TOP] = &but->rect.ymax;
copy_v4_fl(butal->dists, FLT_MAX);
butal++;
}
}
/* This will give us ButAlign items regrouped by align group, vertical and horizontal location.
* Note that, given how buttons are defined in UI code,
* butal_array shall already be "nearly sorted"... */
qsort(butal_array, (size_t)num_buttons, sizeof(*butal_array), ui_block_align_butal_cmp);
/* Third loop: for each pair of buttons in the same align group,
* we compute their potential proximity. Note that each pair is checked only once, and that we
* break early in case we know all remaining pairs will always be too far away. */
int i;
for (i = 0, butal = butal_array; i < num_buttons; i++, butal++) {
const short alignnr = butal->but->alignnr;
int j;
for (j = i + 1, butal_other = &butal_array[i + 1]; j < num_buttons; j++, butal_other++) {
const float max_delta = MAX_DELTA;
/* Since they are sorted, buttons after current butal can only be of same or higher
* group, and once they are not of same group, we know we can break this sub-loop and
* start checking with next butal. */
if (butal_other->but->alignnr != alignnr) {
break;
}
/* Since they are sorted vertically first, buttons after current butal can only be at
* same or lower height, and once they are lower than a given threshold, we know we can
* break this sub-loop and start checking with next butal. */
if ((*butal->borders[DOWN] - *butal_other->borders[TOP]) > max_delta) {
break;
}
block_align_proximity_compute(butal, butal_other);
}
}
/* Fourth loop: we have all our 'aligned' buttons as a 'map' in butal_array. We need to:
* - update their relevant coordinates to stitch them.
* - assign them valid flags.
*/
for (i = 0; i < num_buttons; i++) {
butal = &butal_array[i];
for (side = 0; side < TOTSIDES; side++) {
butal_other = butal->neighbors[side];
if (butal_other) {
const int side_opp = OPPOSITE(side);
const int side_s1 = SIDE1(side);
const int side_s2 = SIDE2(side);
const int align = sides_to_ui_but_align_flags[side];
const int align_opp = sides_to_ui_but_align_flags[side_opp];
float co;
butal->but->drawflag |= align;
butal_other->but->drawflag |= align_opp;
if (!IS_EQF(butal->dists[side], 0.0f)) {
float *delta = &butal->dists[side];
if (*butal->borders[side] < *butal_other->borders[side_opp]) {
*delta *= 0.5f;
}
else {
*delta *= -0.5f;
}
co = (*butal->borders[side] += *delta);
if (!IS_EQF(butal_other->dists[side_opp], 0.0f)) {
BLI_assert(butal_other->dists[side_opp] * 0.5f == fabsf(*delta));
*butal_other->borders[side_opp] = co;
butal_other->dists[side_opp] = 0.0f;
}
*delta = 0.0f;
}
else {
co = *butal->borders[side];
}
block_align_stitch_neighbors(
butal, side, side_opp, side_s1, side_s2, align, align_opp, co);
block_align_stitch_neighbors(
butal, side, side_opp, side_s2, side_s1, align, align_opp, co);
}
}
}
if (butal_array_buf != butal_array) {
MEM_freeN(butal_array);
}
}
# undef SIDE_TO_UI_BUT_ALIGN
# undef SIDE1
# undef OPPOSITE
# undef SIDE2
# undef IS_COLUMN
# undef STITCH
# undef MAX_DELTA
#else /* !USE_UIBUT_SPATIAL_ALIGN */
bool ui_but_can_align(const uiBut *but)
{
return !ELEM(but->type,
UI_BTYPE_LABEL,
UI_BTYPE_CHECKBOX,
UI_BTYPE_CHECKBOX_N,
UI_BTYPE_SEPR,
UI_BTYPE_SEPR_LINE,
UI_BTYPE_SEPR_SPACER);
}
static bool buts_are_horiz(uiBut *but1, uiBut *but2)
{
float dx, dy;
/* simple case which can fail if buttons shift apart
* with proportional layouts, see: T38602. */
if ((but1->rect.ymin == but2->rect.ymin) && (but1->rect.xmin != but2->rect.xmin)) {
return true;
}
dx = fabsf(but1->rect.xmax - but2->rect.xmin);
dy = fabsf(but1->rect.ymin - but2->rect.ymax);
return (dx <= dy);
}
static void ui_block_align_calc_but(uiBut *first, short nr)
{
uiBut *prev, *but = NULL, *next;
int flag = 0, cols = 0, rows = 0;
/* auto align */
for (but = first; but && but->alignnr == nr; but = but->next) {
if (but->next && but->next->alignnr == nr) {
if (buts_are_horiz(but, but->next)) {
cols++;
}
else {
rows++;
}
}
}
/* rows == 0: 1 row, cols == 0: 1 column */
/* note; how it uses 'flag' in loop below (either set it, or OR it) is confusing */
for (but = first, prev = NULL; but && but->alignnr == nr; prev = but, but = but->next) {
next = but->next;
if (next && next->alignnr != nr) {
next = NULL;
}
/* clear old flag */
but->drawflag &= ~UI_BUT_ALIGN;
if (flag == 0) { /* first case */
if (next) {
if (buts_are_horiz(but, next)) {
if (rows == 0) {
flag = UI_BUT_ALIGN_RIGHT;
}
else {
flag = UI_BUT_ALIGN_DOWN | UI_BUT_ALIGN_RIGHT;
}
}
else {
flag = UI_BUT_ALIGN_DOWN;
}
}
}
else if (next == NULL) { /* last case */
if (prev) {
if (buts_are_horiz(prev, but)) {
if (rows == 0) {
flag = UI_BUT_ALIGN_LEFT;
}
else {
flag = UI_BUT_ALIGN_TOP | UI_BUT_ALIGN_LEFT;
}
}
else {
flag = UI_BUT_ALIGN_TOP;
}
}
}
else if (buts_are_horiz(but, next)) {
/* check if this is already second row */
if (prev && buts_are_horiz(prev, but) == 0) {
flag &= ~UI_BUT_ALIGN_LEFT;
flag |= UI_BUT_ALIGN_TOP;
/* exception case: bottom row */
if (rows > 0) {
uiBut *bt = but;
while (bt && bt->alignnr == nr) {
if (bt->next && bt->next->alignnr == nr && buts_are_horiz(bt, bt->next) == 0) {
break;
}
bt = bt->next;
}
if (bt == NULL || bt->alignnr != nr) {
flag = UI_BUT_ALIGN_TOP | UI_BUT_ALIGN_RIGHT;
}
}
}
else {
flag |= UI_BUT_ALIGN_LEFT;
}
}
else {
if (cols == 0) {
flag |= UI_BUT_ALIGN_TOP;
}
else { /* next button switches to new row */
if (prev && buts_are_horiz(prev, but)) {
flag |= UI_BUT_ALIGN_LEFT;
}
else {
flag &= ~UI_BUT_ALIGN_LEFT;
flag |= UI_BUT_ALIGN_TOP;
}
if ((flag & UI_BUT_ALIGN_TOP) == 0) { /* still top row */
if (prev) {
if (next && buts_are_horiz(but, next)) {
flag = UI_BUT_ALIGN_DOWN | UI_BUT_ALIGN_LEFT | UI_BUT_ALIGN_RIGHT;
}
else {
/* last button in top row */
flag = UI_BUT_ALIGN_DOWN | UI_BUT_ALIGN_LEFT;
}
}
else {
flag |= UI_BUT_ALIGN_DOWN;
}
}
else {
flag |= UI_BUT_ALIGN_TOP;
}
}
}
but->drawflag |= flag;
/* merge coordinates */
if (prev) {
/* simple cases */
if (rows == 0) {
but->rect.xmin = (prev->rect.xmax + but->rect.xmin) / 2.0f;
prev->rect.xmax = but->rect.xmin;
}
else if (cols == 0) {
but->rect.ymax = (prev->rect.ymin + but->rect.ymax) / 2.0f;
prev->rect.ymin = but->rect.ymax;
}
else {
if (buts_are_horiz(prev, but)) {
but->rect.xmin = (prev->rect.xmax + but->rect.xmin) / 2.0f;
prev->rect.xmax = but->rect.xmin;
/* copy height too */
but->rect.ymax = prev->rect.ymax;
}
else if (prev->prev && buts_are_horiz(prev->prev, prev) == 0) {
/* the previous button is a single one in its row */
but->rect.ymax = (prev->rect.ymin + but->rect.ymax) / 2.0f;
prev->rect.ymin = but->rect.ymax;
but->rect.xmin = prev->rect.xmin;
if (next && buts_are_horiz(but, next) == 0) {
but->rect.xmax = prev->rect.xmax;
}
}
else {
/* the previous button is not a single one in its row */
but->rect.ymax = prev->rect.ymin;
}
}
}
}
}
void ui_block_align_calc(uiBlock *block, const struct ARegion *UNUSED(region))
{
short nr;
/* align buttons with same align nr */
LISTBASE_FOREACH (uiBut *, but, &block->buttons) {
if (but->alignnr) {
nr = but->alignnr;
ui_block_align_calc_but(but, nr);
/* skip with same number */
for (; but && but->alignnr == nr; but = but->next) {
/* pass */
}
if (!but) {
break;
}
}
else {
but = but->next;
}
}
}
#endif /* !USE_UIBUT_SPATIAL_ALIGN */
int ui_but_align_opposite_to_area_align_get(const ARegion *region)
{
const ARegion *align_region = (region->alignment & RGN_SPLIT_PREV && region->prev) ?
region->prev :
region;
switch (RGN_ALIGN_ENUM_FROM_MASK(align_region->alignment)) {
case RGN_ALIGN_TOP:
return UI_BUT_ALIGN_DOWN;
case RGN_ALIGN_BOTTOM:
return UI_BUT_ALIGN_TOP;
case RGN_ALIGN_LEFT:
return UI_BUT_ALIGN_RIGHT;
case RGN_ALIGN_RIGHT:
return UI_BUT_ALIGN_LEFT;
}
return 0;
}
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