mirror of
https://github.com/hyprwm/wlroots-hyprland.git
synced 2024-11-02 20:05:58 +01:00
f22a5d1704
The Wayland protocol specifies output transform rotations to be counterclockwise and applied to the surface. Previously, wlroots copied Weston and incorrectly made rotations act clockwise on surfaces. This commit fixes that. This change will break compositors which expect transform rotations to be clockwise, and the rare applications that make use of surface transforms.
250 lines
7.4 KiB
C
250 lines
7.4 KiB
C
#include <assert.h>
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#include <math.h>
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#include <limits.h>
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#include <stdlib.h>
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#include <wlr/types/wlr_box.h>
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#include <wlr/util/region.h>
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void wlr_region_scale(pixman_region32_t *dst, pixman_region32_t *src,
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float scale) {
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if (scale == 1) {
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pixman_region32_copy(dst, src);
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return;
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}
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int nrects;
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pixman_box32_t *src_rects = pixman_region32_rectangles(src, &nrects);
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pixman_box32_t *dst_rects = malloc(nrects * sizeof(pixman_box32_t));
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if (dst_rects == NULL) {
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return;
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}
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for (int i = 0; i < nrects; ++i) {
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dst_rects[i].x1 = floor(src_rects[i].x1 * scale);
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dst_rects[i].x2 = ceil(src_rects[i].x2 * scale);
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dst_rects[i].y1 = floor(src_rects[i].y1 * scale);
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dst_rects[i].y2 = ceil(src_rects[i].y2 * scale);
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}
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pixman_region32_fini(dst);
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pixman_region32_init_rects(dst, dst_rects, nrects);
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free(dst_rects);
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}
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void wlr_region_transform(pixman_region32_t *dst, pixman_region32_t *src,
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enum wl_output_transform transform, int width, int height) {
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if (transform == WL_OUTPUT_TRANSFORM_NORMAL) {
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pixman_region32_copy(dst, src);
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return;
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}
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int nrects;
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pixman_box32_t *src_rects = pixman_region32_rectangles(src, &nrects);
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pixman_box32_t *dst_rects = malloc(nrects * sizeof(pixman_box32_t));
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if (dst_rects == NULL) {
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return;
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}
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for (int i = 0; i < nrects; ++i) {
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switch (transform) {
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case WL_OUTPUT_TRANSFORM_NORMAL:
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dst_rects[i].x1 = src_rects[i].x1;
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dst_rects[i].y1 = src_rects[i].y1;
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dst_rects[i].x2 = src_rects[i].x2;
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dst_rects[i].y2 = src_rects[i].y2;
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break;
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case WL_OUTPUT_TRANSFORM_90:
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dst_rects[i].x1 = height - src_rects[i].y2;
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dst_rects[i].y1 = src_rects[i].x1;
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dst_rects[i].x2 = height - src_rects[i].y1;
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dst_rects[i].y2 = src_rects[i].x2;
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break;
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case WL_OUTPUT_TRANSFORM_180:
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dst_rects[i].x1 = width - src_rects[i].x2;
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dst_rects[i].y1 = height - src_rects[i].y2;
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dst_rects[i].x2 = width - src_rects[i].x1;
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dst_rects[i].y2 = height - src_rects[i].y1;
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break;
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case WL_OUTPUT_TRANSFORM_270:
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dst_rects[i].x1 = src_rects[i].y1;
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dst_rects[i].y1 = width - src_rects[i].x2;
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dst_rects[i].x2 = src_rects[i].y2;
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dst_rects[i].y2 = width - src_rects[i].x1;
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break;
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case WL_OUTPUT_TRANSFORM_FLIPPED:
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dst_rects[i].x1 = width - src_rects[i].x2;
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dst_rects[i].y1 = src_rects[i].y1;
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dst_rects[i].x2 = width - src_rects[i].x1;
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dst_rects[i].y2 = src_rects[i].y2;
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break;
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case WL_OUTPUT_TRANSFORM_FLIPPED_90:
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dst_rects[i].x1 = src_rects[i].y1;
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dst_rects[i].y1 = src_rects[i].x1;
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dst_rects[i].x2 = src_rects[i].y2;
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dst_rects[i].y2 = src_rects[i].x2;
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break;
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case WL_OUTPUT_TRANSFORM_FLIPPED_180:
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dst_rects[i].x1 = src_rects[i].x1;
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dst_rects[i].y1 = height - src_rects[i].y2;
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dst_rects[i].x2 = src_rects[i].x2;
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dst_rects[i].y2 = height - src_rects[i].y1;
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break;
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case WL_OUTPUT_TRANSFORM_FLIPPED_270:
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dst_rects[i].x1 = height - src_rects[i].y2;
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dst_rects[i].y1 = width - src_rects[i].x2;
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dst_rects[i].x2 = height - src_rects[i].y1;
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dst_rects[i].y2 = width - src_rects[i].x1;
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break;
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}
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}
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pixman_region32_fini(dst);
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pixman_region32_init_rects(dst, dst_rects, nrects);
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free(dst_rects);
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}
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void wlr_region_expand(pixman_region32_t *dst, pixman_region32_t *src,
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int distance) {
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if (distance == 0) {
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pixman_region32_copy(dst, src);
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return;
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}
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int nrects;
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pixman_box32_t *src_rects = pixman_region32_rectangles(src, &nrects);
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pixman_box32_t *dst_rects = malloc(nrects * sizeof(pixman_box32_t));
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if (dst_rects == NULL) {
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return;
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}
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for (int i = 0; i < nrects; ++i) {
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dst_rects[i].x1 = src_rects[i].x1 - distance;
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dst_rects[i].x2 = src_rects[i].x2 + distance;
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dst_rects[i].y1 = src_rects[i].y1 - distance;
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dst_rects[i].y2 = src_rects[i].y2 + distance;
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}
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pixman_region32_fini(dst);
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pixman_region32_init_rects(dst, dst_rects, nrects);
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free(dst_rects);
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}
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void wlr_region_rotated_bounds(pixman_region32_t *dst, pixman_region32_t *src,
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float rotation, int ox, int oy) {
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if (rotation == 0) {
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pixman_region32_copy(dst, src);
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return;
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}
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int nrects;
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pixman_box32_t *src_rects = pixman_region32_rectangles(src, &nrects);
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pixman_box32_t *dst_rects = malloc(nrects * sizeof(pixman_box32_t));
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if (dst_rects == NULL) {
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return;
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}
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for (int i = 0; i < nrects; ++i) {
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double x1 = src_rects[i].x1 - ox;
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double y1 = src_rects[i].y1 - oy;
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double x2 = src_rects[i].x2 - ox;
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double y2 = src_rects[i].y2 - oy;
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double rx1 = x1 * cos(rotation) - y1 * sin(rotation);
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double ry1 = x1 * sin(rotation) + y1 * cos(rotation);
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double rx2 = x2 * cos(rotation) - y1 * sin(rotation);
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double ry2 = x2 * sin(rotation) + y1 * cos(rotation);
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double rx3 = x2 * cos(rotation) - y2 * sin(rotation);
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double ry3 = x2 * sin(rotation) + y2 * cos(rotation);
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double rx4 = x1 * cos(rotation) - y2 * sin(rotation);
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double ry4 = x1 * sin(rotation) + y2 * cos(rotation);
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x1 = fmin(fmin(rx1, rx2), fmin(rx3, rx4));
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y1 = fmin(fmin(ry1, ry2), fmin(ry3, ry4));
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x2 = fmax(fmax(rx1, rx2), fmax(rx3, rx4));
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y2 = fmax(fmax(ry1, ry2), fmax(ry3, ry4));
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dst_rects[i].x1 = floor(ox + x1);
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dst_rects[i].x2 = ceil(ox + x2);
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dst_rects[i].y1 = floor(oy + y1);
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dst_rects[i].y2 = ceil(oy + y2);
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}
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pixman_region32_fini(dst);
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pixman_region32_init_rects(dst, dst_rects, nrects);
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free(dst_rects);
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}
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static void region_confine(pixman_region32_t *region, double x1, double y1, double x2,
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double y2, double *x2_out, double *y2_out, pixman_box32_t box) {
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double x_clamped = fmax(fmin(x2, box.x2 - 1), box.x1);
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double y_clamped = fmax(fmin(y2, box.y2 - 1), box.y1);
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// If the target coordinates are above box.{x,y}2 - 1, but less than
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// box.{x,y}2, then they are still within the box.
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if (floor(x_clamped) == floor(x2) && floor(y_clamped) == floor(y2)) {
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*x2_out = x2;
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*y2_out = y2;
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return;
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}
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double dx = x2 - x1;
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double dy = y2 - y1;
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// We use fabs to avoid negative zeroes and thus avoid a bug
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// with negative infinity.
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double delta = fmin(fabs(x_clamped - x1) / fabs(dx), fabs(y_clamped - y1) / fabs(dy));
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// We clamp it again due to precision errors.
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double x = fmax(fmin(delta * dx + x1, box.x2 - 1), box.x1);
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double y = fmax(fmin(delta * dy + y1, box.y2 - 1), box.y1);
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// Go one unit past the boundary to find an adjacent box.
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int x_ext = floor(x) + (dx == 0 ? 0 : dx > 0 ? 1 : -1);
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int y_ext = floor(y) + (dy == 0 ? 0 : dy > 0 ? 1 : -1);
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if (pixman_region32_contains_point(region, x_ext, y_ext, &box)) {
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return region_confine(region, x1, y1, x2, y2, x2_out, y2_out, box);
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} else if (dx == 0 || dy == 0) {
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*x2_out = x;
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*y2_out = y;
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} else {
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bool bordering_x = x == box.x1 || x == box.x2 - 1;
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bool bordering_y = y == box.y1 || y == box.y2 - 1;
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if (bordering_x == bordering_y) {
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double x2_potential, y2_potential;
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double tmp1, tmp2;
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region_confine(region, x, y, x, y2, &tmp1, &y2_potential, box);
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region_confine(region, x, y, x2, y, &x2_potential, &tmp2, box);
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if (fabs(x2_potential - x) > fabs(y2_potential - y)) {
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*x2_out = x2_potential;
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*y2_out = y;
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} else {
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*x2_out = x;
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*y2_out = y2_potential;
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}
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} else if (bordering_x) {
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return region_confine(region, x, y, x, y2, x2_out, y2_out, box);
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} else if (bordering_y) {
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return region_confine(region, x, y, x2, y, x2_out, y2_out, box);
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}
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}
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}
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bool wlr_region_confine(pixman_region32_t *region, double x1, double y1, double x2,
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double y2, double *x2_out, double *y2_out) {
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pixman_box32_t box;
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if (pixman_region32_contains_point(region, floor(x1), floor(y1), &box)) {
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region_confine(region, x1, y1, x2, y2, x2_out, y2_out, box);
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return true;
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} else {
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return false;
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}
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}
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