/* SPDX-License-Identifier: GPL-2.0-or-later * Copyright 2001-2002 NaN Holding BV. All rights reserved. */ /** \file * \ingroup bli * * A minimalist lib for functions doing stuff with rectangle structs. */ #include #include #include #include #include #include "BLI_math_base.h" #include "BLI_rect.h" #include "BLI_utildefines.h" #include "DNA_vec_types.h" /* avoid including BLI_math */ static void unit_m4(float m[4][4]); bool BLI_rcti_is_empty(const rcti *rect) { return ((rect->xmax <= rect->xmin) || (rect->ymax <= rect->ymin)); } bool BLI_rctf_is_empty(const rctf *rect) { return ((rect->xmax <= rect->xmin) || (rect->ymax <= rect->ymin)); } bool BLI_rcti_isect_x(const rcti *rect, const int x) { if (x < rect->xmin) { return false; } if (x > rect->xmax) { return false; } return true; } bool BLI_rcti_isect_y(const rcti *rect, const int y) { if (y < rect->ymin) { return false; } if (y > rect->ymax) { return false; } return true; } bool BLI_rcti_isect_pt(const rcti *rect, const int x, const int y) { if (x < rect->xmin) { return false; } if (x > rect->xmax) { return false; } if (y < rect->ymin) { return false; } if (y > rect->ymax) { return false; } return true; } bool BLI_rcti_isect_pt_v(const rcti *rect, const int xy[2]) { if (xy[0] < rect->xmin) { return false; } if (xy[0] > rect->xmax) { return false; } if (xy[1] < rect->ymin) { return false; } if (xy[1] > rect->ymax) { return false; } return true; } bool BLI_rctf_isect_x(const rctf *rect, const float x) { if (x < rect->xmin) { return false; } if (x > rect->xmax) { return false; } return true; } bool BLI_rctf_isect_y(const rctf *rect, const float y) { if (y < rect->ymin) { return false; } if (y > rect->ymax) { return false; } return true; } bool BLI_rctf_isect_pt(const rctf *rect, const float x, const float y) { if (x < rect->xmin) { return false; } if (x > rect->xmax) { return false; } if (y < rect->ymin) { return false; } if (y > rect->ymax) { return false; } return true; } bool BLI_rctf_isect_pt_v(const rctf *rect, const float xy[2]) { if (xy[0] < rect->xmin) { return false; } if (xy[0] > rect->xmax) { return false; } if (xy[1] < rect->ymin) { return false; } if (xy[1] > rect->ymax) { return false; } return true; } int BLI_rcti_length_x(const rcti *rect, const int x) { if (x < rect->xmin) { return rect->xmin - x; } if (x > rect->xmax) { return x - rect->xmax; } return 0; } int BLI_rcti_length_y(const rcti *rect, const int y) { if (y < rect->ymin) { return rect->ymin - y; } if (y > rect->ymax) { return y - rect->ymax; } return 0; } float BLI_rctf_length_x(const rctf *rect, const float x) { if (x < rect->xmin) { return rect->xmin - x; } if (x > rect->xmax) { return x - rect->xmax; } return 0.0f; } float BLI_rctf_length_y(const rctf *rect, const float y) { if (y < rect->ymin) { return rect->ymin - y; } if (y > rect->ymax) { return y - rect->ymax; } return 0.0f; } bool BLI_rctf_inside_rctf(const rctf *rct_a, const rctf *rct_b) { return ((rct_a->xmin <= rct_b->xmin) && (rct_a->xmax >= rct_b->xmax) && (rct_a->ymin <= rct_b->ymin) && (rct_a->ymax >= rct_b->ymax)); } bool BLI_rcti_inside_rcti(const rcti *rct_a, const rcti *rct_b) { return ((rct_a->xmin <= rct_b->xmin) && (rct_a->xmax >= rct_b->xmax) && (rct_a->ymin <= rct_b->ymin) && (rct_a->ymax >= rct_b->ymax)); } /* based closely on 'isect_seg_seg_v2_int', * but in modified so corner cases are treated as intersections */ static int isect_segments_i(const int v1[2], const int v2[2], const int v3[2], const int v4[2]) { const double div = (double)((v2[0] - v1[0]) * (v4[1] - v3[1]) - (v2[1] - v1[1]) * (v4[0] - v3[0])); if (div == 0.0) { return 1; /* co-linear */ } const double lambda = (double)((v1[1] - v3[1]) * (v4[0] - v3[0]) - (v1[0] - v3[0]) * (v4[1] - v3[1])) / div; const double mu = (double)((v1[1] - v3[1]) * (v2[0] - v1[0]) - (v1[0] - v3[0]) * (v2[1] - v1[1])) / div; return (lambda >= 0.0 && lambda <= 1.0 && mu >= 0.0 && mu <= 1.0); } static int isect_segments_fl(const float v1[2], const float v2[2], const float v3[2], const float v4[2]) { const double div = (double)((v2[0] - v1[0]) * (v4[1] - v3[1]) - (v2[1] - v1[1]) * (v4[0] - v3[0])); if (div == 0.0) { return 1; /* co-linear */ } const double lambda = (double)((v1[1] - v3[1]) * (v4[0] - v3[0]) - (v1[0] - v3[0]) * (v4[1] - v3[1])) / div; const double mu = (double)((v1[1] - v3[1]) * (v2[0] - v1[0]) - (v1[0] - v3[0]) * (v2[1] - v1[1])) / div; return (lambda >= 0.0 && lambda <= 1.0 && mu >= 0.0 && mu <= 1.0); } bool BLI_rcti_isect_segment(const rcti *rect, const int s1[2], const int s2[2]) { /* first do outside-bounds check for both points of the segment */ if (s1[0] < rect->xmin && s2[0] < rect->xmin) { return false; } if (s1[0] > rect->xmax && s2[0] > rect->xmax) { return false; } if (s1[1] < rect->ymin && s2[1] < rect->ymin) { return false; } if (s1[1] > rect->ymax && s2[1] > rect->ymax) { return false; } /* if either points intersect then we definitely intersect */ if (BLI_rcti_isect_pt_v(rect, s1) || BLI_rcti_isect_pt_v(rect, s2)) { return true; } /* both points are outside but may intersect the rect */ int tvec1[2]; int tvec2[2]; /* diagonal: [/] */ tvec1[0] = rect->xmin; tvec1[1] = rect->ymin; tvec2[0] = rect->xmax; tvec2[1] = rect->ymax; if (isect_segments_i(s1, s2, tvec1, tvec2)) { return true; } /* diagonal: [\] */ tvec1[0] = rect->xmin; tvec1[1] = rect->ymax; tvec2[0] = rect->xmax; tvec2[1] = rect->ymin; if (isect_segments_i(s1, s2, tvec1, tvec2)) { return true; } /* no intersection */ return false; } bool BLI_rctf_isect_segment(const rctf *rect, const float s1[2], const float s2[2]) { /* first do outside-bounds check for both points of the segment */ if (s1[0] < rect->xmin && s2[0] < rect->xmin) { return false; } if (s1[0] > rect->xmax && s2[0] > rect->xmax) { return false; } if (s1[1] < rect->ymin && s2[1] < rect->ymin) { return false; } if (s1[1] > rect->ymax && s2[1] > rect->ymax) { return false; } /* if either points intersect then we definitely intersect */ if (BLI_rctf_isect_pt_v(rect, s1) || BLI_rctf_isect_pt_v(rect, s2)) { return true; } /* both points are outside but may intersect the rect */ float tvec1[2]; float tvec2[2]; /* diagonal: [/] */ tvec1[0] = rect->xmin; tvec1[1] = rect->ymin; tvec2[0] = rect->xmax; tvec2[1] = rect->ymax; if (isect_segments_fl(s1, s2, tvec1, tvec2)) { return true; } /* diagonal: [\] */ tvec1[0] = rect->xmin; tvec1[1] = rect->ymax; tvec2[0] = rect->xmax; tvec2[1] = rect->ymin; if (isect_segments_fl(s1, s2, tvec1, tvec2)) { return true; } /* no intersection */ return false; } bool BLI_rcti_isect_circle(const rcti *rect, const float xy[2], const float radius) { float dx, dy; if (xy[0] >= rect->xmin && xy[0] <= rect->xmax) { dx = 0; } else { dx = (xy[0] < rect->xmin) ? (rect->xmin - xy[0]) : (xy[0] - rect->xmax); } if (xy[1] >= rect->ymin && xy[1] <= rect->ymax) { dy = 0; } else { dy = (xy[1] < rect->ymin) ? (rect->ymin - xy[1]) : (xy[1] - rect->ymax); } return dx * dx + dy * dy <= radius * radius; } bool BLI_rctf_isect_circle(const rctf *rect, const float xy[2], const float radius) { float dx, dy; if (xy[0] >= rect->xmin && xy[0] <= rect->xmax) { dx = 0; } else { dx = (xy[0] < rect->xmin) ? (rect->xmin - xy[0]) : (xy[0] - rect->xmax); } if (xy[1] >= rect->ymin && xy[1] <= rect->ymax) { dy = 0; } else { dy = (xy[1] < rect->ymin) ? (rect->ymin - xy[1]) : (xy[1] - rect->ymax); } return dx * dx + dy * dy <= radius * radius; } void BLI_rctf_union(rctf *rct_a, const rctf *rct_b) { if (rct_a->xmin > rct_b->xmin) { rct_a->xmin = rct_b->xmin; } if (rct_a->xmax < rct_b->xmax) { rct_a->xmax = rct_b->xmax; } if (rct_a->ymin > rct_b->ymin) { rct_a->ymin = rct_b->ymin; } if (rct_a->ymax < rct_b->ymax) { rct_a->ymax = rct_b->ymax; } } void BLI_rcti_union(rcti *rct_a, const rcti *rct_b) { if (rct_a->xmin > rct_b->xmin) { rct_a->xmin = rct_b->xmin; } if (rct_a->xmax < rct_b->xmax) { rct_a->xmax = rct_b->xmax; } if (rct_a->ymin > rct_b->ymin) { rct_a->ymin = rct_b->ymin; } if (rct_a->ymax < rct_b->ymax) { rct_a->ymax = rct_b->ymax; } } void BLI_rctf_init(rctf *rect, float xmin, float xmax, float ymin, float ymax) { rect->xmin = xmin; rect->xmax = xmax; rect->ymin = ymin; rect->ymax = ymax; BLI_rctf_sanitize(rect); } void BLI_rcti_init(rcti *rect, int xmin, int xmax, int ymin, int ymax) { rect->xmin = xmin; rect->xmax = xmax; rect->ymin = ymin; rect->ymax = ymax; BLI_rcti_sanitize(rect); } bool BLI_rctf_is_valid(const rctf *rect) { return (rect->xmin <= rect->xmax) && (rect->ymin <= rect->ymax); } bool BLI_rcti_is_valid(const rcti *rect) { return (rect->xmin <= rect->xmax) && (rect->ymin <= rect->ymax); } void BLI_rctf_sanitize(rctf *rect) { if (rect->xmin > rect->xmax) { SWAP(float, rect->xmin, rect->xmax); } if (rect->ymin > rect->ymax) { SWAP(float, rect->ymin, rect->ymax); } BLI_assert(BLI_rctf_is_valid(rect)); } void BLI_rcti_sanitize(rcti *rect) { if (rect->xmin > rect->xmax) { SWAP(int, rect->xmin, rect->xmax); } if (rect->ymin > rect->ymax) { SWAP(int, rect->ymin, rect->ymax); } BLI_assert(BLI_rcti_is_valid(rect)); } void BLI_rctf_init_pt_radius(rctf *rect, const float xy[2], float size) { rect->xmin = xy[0] - size; rect->xmax = xy[0] + size; rect->ymin = xy[1] - size; rect->ymax = xy[1] + size; } void BLI_rcti_init_pt_radius(rcti *rect, const int xy[2], int size) { rect->xmin = xy[0] - size; rect->xmax = xy[0] + size; rect->ymin = xy[1] - size; rect->ymax = xy[1] + size; } void BLI_rcti_init_minmax(rcti *rect) { rect->xmin = rect->ymin = INT_MAX; rect->xmax = rect->ymax = INT_MIN; } void BLI_rctf_init_minmax(rctf *rect) { rect->xmin = rect->ymin = FLT_MAX; rect->xmax = rect->ymax = -FLT_MAX; } void BLI_rcti_do_minmax_v(rcti *rect, const int xy[2]) { if (xy[0] < rect->xmin) { rect->xmin = xy[0]; } if (xy[0] > rect->xmax) { rect->xmax = xy[0]; } if (xy[1] < rect->ymin) { rect->ymin = xy[1]; } if (xy[1] > rect->ymax) { rect->ymax = xy[1]; } } void BLI_rcti_do_minmax_rcti(rcti *rect, const rcti *other) { rect->xmin = min_ii(rect->xmin, other->xmin); rect->xmax = max_ii(rect->xmax, other->xmax); rect->ymin = min_ii(rect->ymin, other->ymin); rect->ymax = max_ii(rect->ymax, other->ymax); } void BLI_rctf_do_minmax_v(rctf *rect, const float xy[2]) { if (xy[0] < rect->xmin) { rect->xmin = xy[0]; } if (xy[0] > rect->xmax) { rect->xmax = xy[0]; } if (xy[1] < rect->ymin) { rect->ymin = xy[1]; } if (xy[1] > rect->ymax) { rect->ymax = xy[1]; } } void BLI_rctf_transform_pt_v(const rctf *dst, const rctf *src, float xy_dst[2], const float xy_src[2]) { xy_dst[0] = ((xy_src[0] - src->xmin) / (src->xmax - src->xmin)); xy_dst[0] = dst->xmin + ((dst->xmax - dst->xmin) * xy_dst[0]); xy_dst[1] = ((xy_src[1] - src->ymin) / (src->ymax - src->ymin)); xy_dst[1] = dst->ymin + ((dst->ymax - dst->ymin) * xy_dst[1]); } void BLI_rctf_transform_calc_m4_pivot_min_ex( const rctf *dst, const rctf *src, float matrix[4][4], uint x, uint y) { BLI_assert(x < 3 && y < 3); unit_m4(matrix); matrix[x][x] = BLI_rctf_size_x(src) / BLI_rctf_size_x(dst); matrix[y][y] = BLI_rctf_size_y(src) / BLI_rctf_size_y(dst); matrix[3][x] = (src->xmin - dst->xmin) * matrix[x][x]; matrix[3][y] = (src->ymin - dst->ymin) * matrix[y][y]; } void BLI_rctf_transform_calc_m4_pivot_min(const rctf *dst, const rctf *src, float matrix[4][4]) { BLI_rctf_transform_calc_m4_pivot_min_ex(dst, src, matrix, 0, 1); } void BLI_rcti_translate(rcti *rect, int x, int y) { rect->xmin += x; rect->ymin += y; rect->xmax += x; rect->ymax += y; } void BLI_rctf_translate(rctf *rect, float x, float y) { rect->xmin += x; rect->ymin += y; rect->xmax += x; rect->ymax += y; } void BLI_rcti_recenter(rcti *rect, int x, int y) { const int dx = x - BLI_rcti_cent_x(rect); const int dy = y - BLI_rcti_cent_y(rect); BLI_rcti_translate(rect, dx, dy); } void BLI_rctf_recenter(rctf *rect, float x, float y) { const float dx = x - BLI_rctf_cent_x(rect); const float dy = y - BLI_rctf_cent_y(rect); BLI_rctf_translate(rect, dx, dy); } void BLI_rcti_resize_x(rcti *rect, int x) { rect->xmin = BLI_rcti_cent_x(rect) - (x / 2); rect->xmax = rect->xmin + x; } void BLI_rcti_resize_y(rcti *rect, int y) { rect->ymin = BLI_rcti_cent_y(rect) - (y / 2); rect->ymax = rect->ymin + y; } void BLI_rcti_resize(rcti *rect, int x, int y) { rect->xmin = BLI_rcti_cent_x(rect) - (x / 2); rect->ymin = BLI_rcti_cent_y(rect) - (y / 2); rect->xmax = rect->xmin + x; rect->ymax = rect->ymin + y; } void BLI_rcti_pad(rcti *rect, int pad_x, int pad_y) { rect->xmin -= pad_x; rect->ymin -= pad_y; rect->xmax += pad_x; rect->ymax += pad_y; } void BLI_rctf_pad(rctf *rect, float pad_x, float pad_y) { rect->xmin -= pad_x; rect->ymin -= pad_y; rect->xmax += pad_x; rect->ymax += pad_y; } void BLI_rctf_resize_x(rctf *rect, float x) { rect->xmin = BLI_rctf_cent_x(rect) - (x * 0.5f); rect->xmax = rect->xmin + x; } void BLI_rctf_resize_y(rctf *rect, float y) { rect->ymin = BLI_rctf_cent_y(rect) - (y * 0.5f); rect->ymax = rect->ymin + y; } void BLI_rctf_resize(rctf *rect, float x, float y) { rect->xmin = BLI_rctf_cent_x(rect) - (x * 0.5f); rect->ymin = BLI_rctf_cent_y(rect) - (y * 0.5f); rect->xmax = rect->xmin + x; rect->ymax = rect->ymin + y; } void BLI_rcti_scale(rcti *rect, const float scale) { const int cent_x = BLI_rcti_cent_x(rect); const int cent_y = BLI_rcti_cent_y(rect); const int size_x_half = BLI_rcti_size_x(rect) * (scale * 0.5f); const int size_y_half = BLI_rcti_size_y(rect) * (scale * 0.5f); rect->xmin = cent_x - size_x_half; rect->ymin = cent_y - size_y_half; rect->xmax = cent_x + size_x_half; rect->ymax = cent_y + size_y_half; } void BLI_rctf_scale(rctf *rect, const float scale) { const float cent_x = BLI_rctf_cent_x(rect); const float cent_y = BLI_rctf_cent_y(rect); const float size_x_half = BLI_rctf_size_x(rect) * (scale * 0.5f); const float size_y_half = BLI_rctf_size_y(rect) * (scale * 0.5f); rect->xmin = cent_x - size_x_half; rect->ymin = cent_y - size_y_half; rect->xmax = cent_x + size_x_half; rect->ymax = cent_y + size_y_half; } void BLI_rctf_pad_y(rctf *rect, const float boundary_size, const float pad_min, const float pad_max) { BLI_assert(pad_max >= 0.0f); BLI_assert(pad_min >= 0.0f); BLI_assert(boundary_size > 0.0f); float total_pad = pad_max + pad_min; if (total_pad == 0.0f) { return; } float total_extend = BLI_rctf_size_y(rect) * total_pad / (boundary_size - total_pad); rect->ymax += total_extend * (pad_max / total_pad); rect->ymin -= total_extend * (pad_min / total_pad); } void BLI_rctf_interp(rctf *rect, const rctf *rect_a, const rctf *rect_b, const float fac) { const float ifac = 1.0f - fac; rect->xmin = (rect_a->xmin * ifac) + (rect_b->xmin * fac); rect->xmax = (rect_a->xmax * ifac) + (rect_b->xmax * fac); rect->ymin = (rect_a->ymin * ifac) + (rect_b->ymin * fac); rect->ymax = (rect_a->ymax * ifac) + (rect_b->ymax * fac); } /* BLI_rcti_interp() not needed yet */ bool BLI_rctf_clamp_pt_v(const rctf *rect, float xy[2]) { bool changed = false; if (xy[0] < rect->xmin) { xy[0] = rect->xmin; changed = true; } if (xy[0] > rect->xmax) { xy[0] = rect->xmax; changed = true; } if (xy[1] < rect->ymin) { xy[1] = rect->ymin; changed = true; } if (xy[1] > rect->ymax) { xy[1] = rect->ymax; changed = true; } return changed; } bool BLI_rcti_clamp_pt_v(const rcti *rect, int xy[2]) { bool changed = false; if (xy[0] < rect->xmin) { xy[0] = rect->xmin; changed = true; } if (xy[0] > rect->xmax) { xy[0] = rect->xmax; changed = true; } if (xy[1] < rect->ymin) { xy[1] = rect->ymin; changed = true; } if (xy[1] > rect->ymax) { xy[1] = rect->ymax; changed = true; } return changed; } bool BLI_rctf_clamp(rctf *rect, const rctf *rect_bounds, float r_xy[2]) { bool changed = false; r_xy[0] = 0.0f; r_xy[1] = 0.0f; if (rect->xmax > rect_bounds->xmax) { float ofs = rect_bounds->xmax - rect->xmax; rect->xmin += ofs; rect->xmax += ofs; r_xy[0] += ofs; changed = true; } if (rect->xmin < rect_bounds->xmin) { float ofs = rect_bounds->xmin - rect->xmin; rect->xmin += ofs; rect->xmax += ofs; r_xy[0] += ofs; changed = true; } if (rect->ymin < rect_bounds->ymin) { float ofs = rect_bounds->ymin - rect->ymin; rect->ymin += ofs; rect->ymax += ofs; r_xy[1] += ofs; changed = true; } if (rect->ymax > rect_bounds->ymax) { float ofs = rect_bounds->ymax - rect->ymax; rect->ymin += ofs; rect->ymax += ofs; r_xy[1] += ofs; changed = true; } return changed; } bool BLI_rcti_clamp(rcti *rect, const rcti *rect_bounds, int r_xy[2]) { bool changed = false; r_xy[0] = 0; r_xy[1] = 0; if (rect->xmax > rect_bounds->xmax) { int ofs = rect_bounds->xmax - rect->xmax; rect->xmin += ofs; rect->xmax += ofs; r_xy[0] += ofs; changed = true; } if (rect->xmin < rect_bounds->xmin) { int ofs = rect_bounds->xmin - rect->xmin; rect->xmin += ofs; rect->xmax += ofs; r_xy[0] += ofs; changed = true; } if (rect->ymin < rect_bounds->ymin) { int ofs = rect_bounds->ymin - rect->ymin; rect->ymin += ofs; rect->ymax += ofs; r_xy[1] += ofs; changed = true; } if (rect->ymax > rect_bounds->ymax) { int ofs = rect_bounds->ymax - rect->ymax; rect->ymin += ofs; rect->ymax += ofs; r_xy[1] += ofs; changed = true; } return changed; } bool BLI_rctf_compare(const rctf *rect_a, const rctf *rect_b, const float limit) { if (fabsf(rect_a->xmin - rect_b->xmin) < limit) { if (fabsf(rect_a->xmax - rect_b->xmax) < limit) { if (fabsf(rect_a->ymin - rect_b->ymin) < limit) { if (fabsf(rect_a->ymax - rect_b->ymax) < limit) { return true; } } } } return false; } bool BLI_rcti_compare(const rcti *rect_a, const rcti *rect_b) { if (rect_a->xmin == rect_b->xmin) { if (rect_a->xmax == rect_b->xmax) { if (rect_a->ymin == rect_b->ymin) { if (rect_a->ymax == rect_b->ymax) { return true; } } } } return false; } bool BLI_rctf_isect(const rctf *src1, const rctf *src2, rctf *dest) { float xmin, xmax; float ymin, ymax; xmin = (src1->xmin) > (src2->xmin) ? (src1->xmin) : (src2->xmin); xmax = (src1->xmax) < (src2->xmax) ? (src1->xmax) : (src2->xmax); ymin = (src1->ymin) > (src2->ymin) ? (src1->ymin) : (src2->ymin); ymax = (src1->ymax) < (src2->ymax) ? (src1->ymax) : (src2->ymax); if (xmax >= xmin && ymax >= ymin) { if (dest) { dest->xmin = xmin; dest->xmax = xmax; dest->ymin = ymin; dest->ymax = ymax; } return true; } if (dest) { dest->xmin = 0; dest->xmax = 0; dest->ymin = 0; dest->ymax = 0; } return false; } bool BLI_rcti_isect(const rcti *src1, const rcti *src2, rcti *dest) { int xmin, xmax; int ymin, ymax; xmin = (src1->xmin) > (src2->xmin) ? (src1->xmin) : (src2->xmin); xmax = (src1->xmax) < (src2->xmax) ? (src1->xmax) : (src2->xmax); ymin = (src1->ymin) > (src2->ymin) ? (src1->ymin) : (src2->ymin); ymax = (src1->ymax) < (src2->ymax) ? (src1->ymax) : (src2->ymax); if (xmax >= xmin && ymax >= ymin) { if (dest) { dest->xmin = xmin; dest->xmax = xmax; dest->ymin = ymin; dest->ymax = ymax; } return true; } if (dest) { dest->xmin = 0; dest->xmax = 0; dest->ymin = 0; dest->ymax = 0; } return false; } bool BLI_rctf_isect_rect_x(const rctf *src1, const rctf *src2, float range_x[2]) { const float xmin = (src1->xmin) > (src2->xmin) ? (src1->xmin) : (src2->xmin); const float xmax = (src1->xmax) < (src2->xmax) ? (src1->xmax) : (src2->xmax); if (xmax >= xmin) { if (range_x) { range_x[0] = xmin; range_x[1] = xmax; } return true; } if (range_x) { range_x[0] = 0; range_x[1] = 0; } return false; } bool BLI_rctf_isect_rect_y(const rctf *src1, const rctf *src2, float range_y[2]) { const float ymin = (src1->ymin) > (src2->ymin) ? (src1->ymin) : (src2->ymin); const float ymax = (src1->ymax) < (src2->ymax) ? (src1->ymax) : (src2->ymax); if (ymax >= ymin) { if (range_y) { range_y[0] = ymin; range_y[1] = ymax; } return true; } if (range_y) { range_y[0] = 0; range_y[1] = 0; } return false; } bool BLI_rcti_isect_rect_x(const rcti *src1, const rcti *src2, int range_x[2]) { const int xmin = (src1->xmin) > (src2->xmin) ? (src1->xmin) : (src2->xmin); const int xmax = (src1->xmax) < (src2->xmax) ? (src1->xmax) : (src2->xmax); if (xmax >= xmin) { if (range_x) { range_x[0] = xmin; range_x[1] = xmax; } return true; } if (range_x) { range_x[0] = 0; range_x[1] = 0; } return false; } bool BLI_rcti_isect_rect_y(const rcti *src1, const rcti *src2, int range_y[2]) { const int ymin = (src1->ymin) > (src2->ymin) ? (src1->ymin) : (src2->ymin); const int ymax = (src1->ymax) < (src2->ymax) ? (src1->ymax) : (src2->ymax); if (ymax >= ymin) { if (range_y) { range_y[0] = ymin; range_y[1] = ymax; } return true; } if (range_y) { range_y[0] = 0; range_y[1] = 0; } return false; } void BLI_rcti_rctf_copy(rcti *dst, const rctf *src) { dst->xmin = floorf(src->xmin + 0.5f); dst->xmax = dst->xmin + floorf(BLI_rctf_size_x(src) + 0.5f); dst->ymin = floorf(src->ymin + 0.5f); dst->ymax = dst->ymin + floorf(BLI_rctf_size_y(src) + 0.5f); } void BLI_rcti_rctf_copy_floor(rcti *dst, const rctf *src) { dst->xmin = floorf(src->xmin); dst->xmax = floorf(src->xmax); dst->ymin = floorf(src->ymin); dst->ymax = floorf(src->ymax); } void BLI_rcti_rctf_copy_round(rcti *dst, const rctf *src) { dst->xmin = floorf(src->xmin + 0.5f); dst->xmax = floorf(src->xmax + 0.5f); dst->ymin = floorf(src->ymin + 0.5f); dst->ymax = floorf(src->ymax + 0.5f); } void BLI_rctf_rcti_copy(rctf *dst, const rcti *src) { dst->xmin = src->xmin; dst->xmax = src->xmax; dst->ymin = src->ymin; dst->ymax = src->ymax; } void print_rctf(const char *str, const rctf *rect) { printf("%s: xmin %.8f, xmax %.8f, ymin %.8f, ymax %.8f (%.12fx%.12f)\n", str, rect->xmin, rect->xmax, rect->ymin, rect->ymax, BLI_rctf_size_x(rect), BLI_rctf_size_y(rect)); } void print_rcti(const char *str, const rcti *rect) { printf("%s: xmin %d, xmax %d, ymin %d, ymax %d (%dx%d)\n", str, rect->xmin, rect->xmax, rect->ymin, rect->ymax, BLI_rcti_size_x(rect), BLI_rcti_size_y(rect)); } /* Comprehensive math (float only) */ /* -------------------------------------------------------------------- */ /** \name Rect math functions * \{ */ #define ROTATE_SINCOS(r_vec, mat2, vec) \ { \ (r_vec)[0] = (mat2)[1] * (vec)[0] + (+(mat2)[0]) * (vec)[1]; \ (r_vec)[1] = (mat2)[0] * (vec)[0] + (-(mat2)[1]) * (vec)[1]; \ } \ ((void)0) void BLI_rctf_rotate_expand(rctf *dst, const rctf *src, const float angle) { const float mat2[2] = {sinf(angle), cosf(angle)}; const float cent[2] = {BLI_rctf_cent_x(src), BLI_rctf_cent_y(src)}; float corner[2], corner_rot[2], corder_max[2]; /* x is same for both corners */ corner[0] = src->xmax - cent[0]; corner[1] = src->ymax - cent[1]; ROTATE_SINCOS(corner_rot, mat2, corner); corder_max[0] = fabsf(corner_rot[0]); corder_max[1] = fabsf(corner_rot[1]); corner[1] *= -1; ROTATE_SINCOS(corner_rot, mat2, corner); corder_max[0] = MAX2(corder_max[0], fabsf(corner_rot[0])); corder_max[1] = MAX2(corder_max[1], fabsf(corner_rot[1])); dst->xmin = cent[0] - corder_max[0]; dst->xmax = cent[0] + corder_max[0]; dst->ymin = cent[1] - corder_max[1]; dst->ymax = cent[1] + corder_max[1]; } #undef ROTATE_SINCOS /** \} */ static void unit_m4(float m[4][4]) { m[0][0] = m[1][1] = m[2][2] = m[3][3] = 1.0f; m[0][1] = m[0][2] = m[0][3] = 0.0f; m[1][0] = m[1][2] = m[1][3] = 0.0f; m[2][0] = m[2][1] = m[2][3] = 0.0f; m[3][0] = m[3][1] = m[3][2] = 0.0f; }