/* * Copyright 2015 Henri Verbeet for CodeWeavers * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include "d2d1_private.h" #include WINE_DEFAULT_DEBUG_CHANNEL(d2d); #define D2D_FIGURE_FLAG_CLOSED 0x00000001u #define D2D_FIGURE_FLAG_HOLLOW 0x00000002u #define D2D_CDT_EDGE_FLAG_FREED 0x80000000u #define D2D_CDT_EDGE_FLAG_VISITED(r) (1u << (r)) #define D2D_FP_EPS (1.0f / (1 << FLT_MANT_DIG)) static const D2D1_MATRIX_3X2_F identity = {{{ 1.0f, 0.0f, 0.0f, 1.0f, 0.0f, 0.0f, }}}; enum d2d_cdt_edge_next { D2D_EDGE_NEXT_ORIGIN = 0, D2D_EDGE_NEXT_ROT = 1, D2D_EDGE_NEXT_SYM = 2, D2D_EDGE_NEXT_TOR = 3, }; enum d2d_vertex_type { D2D_VERTEX_TYPE_NONE, D2D_VERTEX_TYPE_LINE, D2D_VERTEX_TYPE_BEZIER, D2D_VERTEX_TYPE_SPLIT_BEZIER, }; struct d2d_segment_idx { size_t figure_idx; size_t vertex_idx; size_t control_idx; }; struct d2d_figure { D2D1_POINT_2F *vertices; size_t vertices_size; enum d2d_vertex_type *vertex_types; size_t vertex_types_size; size_t vertex_count; D2D1_POINT_2F *bezier_controls; size_t bezier_controls_size; size_t bezier_control_count; D2D1_POINT_2F *original_bezier_controls; size_t original_bezier_controls_size; size_t original_bezier_control_count; D2D1_RECT_F bounds; unsigned int flags; }; struct d2d_cdt_edge_ref { size_t idx; enum d2d_cdt_edge_next r; }; struct d2d_cdt_edge { struct d2d_cdt_edge_ref next[4]; size_t vertex[2]; unsigned int flags; }; struct d2d_cdt { struct d2d_cdt_edge *edges; size_t edges_size; size_t edge_count; size_t free_edge; const D2D1_POINT_2F *vertices; }; struct d2d_geometry_intersection { size_t figure_idx; size_t vertex_idx; size_t control_idx; float t; D2D1_POINT_2F p; }; struct d2d_geometry_intersections { struct d2d_geometry_intersection *intersections; size_t intersections_size; size_t intersection_count; }; struct d2d_fp_two_vec2 { float x[2]; float y[2]; }; struct d2d_fp_fin { float *now, *other; size_t length; }; static void d2d_curve_vertex_set(struct d2d_curve_vertex *b, const D2D1_POINT_2F *p, float u, float v, float sign) { b->position = *p; b->texcoord.u = u; b->texcoord.v = v; b->texcoord.sign = sign; } static void d2d_face_set(struct d2d_face *f, UINT16 v0, UINT16 v1, UINT16 v2) { f->v[0] = v0; f->v[1] = v1; f->v[2] = v2; } static void d2d_outline_vertex_set(struct d2d_outline_vertex *v, float x, float y, float prev_x, float prev_y, float next_x, float next_y) { d2d_point_set(&v->position, x, y); d2d_point_set(&v->prev, prev_x, prev_y); d2d_point_set(&v->next, next_x, next_y); } static void d2d_curve_outline_vertex_set(struct d2d_curve_outline_vertex *a, const D2D1_POINT_2F *position, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2, float prev_x, float prev_y, float next_x, float next_y) { a->position = *position; a->p0 = *p0; a->p1 = *p1; a->p2 = *p2; d2d_point_set(&a->prev, prev_x, prev_y); d2d_point_set(&a->next, next_x, next_y); } static void d2d_fp_two_sum(float *out, float a, float b) { float a_virt, a_round, b_virt, b_round; out[1] = a + b; b_virt = out[1] - a; a_virt = out[1] - b_virt; b_round = b - b_virt; a_round = a - a_virt; out[0] = a_round + b_round; } static void d2d_fp_fast_two_sum(float *out, float a, float b) { float b_virt; out[1] = a + b; b_virt = out[1] - a; out[0] = b - b_virt; } static void d2d_fp_two_two_sum(float *out, const float *a, const float *b) { float sum[2]; d2d_fp_two_sum(out, a[0], b[0]); d2d_fp_two_sum(sum, a[1], out[1]); d2d_fp_two_sum(&out[1], sum[0], b[1]); d2d_fp_two_sum(&out[2], sum[1], out[2]); } static void d2d_fp_two_diff_tail(float *out, float a, float b, float x) { float a_virt, a_round, b_virt, b_round; b_virt = a - x; a_virt = x + b_virt; b_round = b_virt - b; a_round = a - a_virt; *out = a_round + b_round; } static void d2d_fp_two_two_diff(float *out, const float *a, const float *b) { float sum[2], diff; diff = a[0] - b[0]; d2d_fp_two_diff_tail(out, a[0], b[0], diff); d2d_fp_two_sum(sum, a[1], diff); diff = sum[0] - b[1]; d2d_fp_two_diff_tail(&out[1], sum[0], b[1], diff); d2d_fp_two_sum(&out[2], sum[1], diff); } static void d2d_fp_split(float *out, float a) { float a_big, c; c = a * ((1 << (FLT_MANT_DIG / 2)) + 1.0f); a_big = c - a; out[1] = c - a_big; out[0] = a - out[1]; } static void d2d_fp_two_product_presplit(float *out, float a, float b, const float *b_split) { float a_split[2], err1, err2, err3; out[1] = a * b; d2d_fp_split(a_split, a); err1 = out[1] - (a_split[1] * b_split[1]); err2 = err1 - (a_split[0] * b_split[1]); err3 = err2 - (a_split[1] * b_split[0]); out[0] = (a_split[0] * b_split[0]) - err3; } static void d2d_fp_two_product(float *out, float a, float b) { float b_split[2]; d2d_fp_split(b_split, b); d2d_fp_two_product_presplit(out, a, b, b_split); } static void d2d_fp_square(float *out, float a) { float a_split[2], err1, err2; out[1] = a * a; d2d_fp_split(a_split, a); err1 = out[1] - (a_split[1] * a_split[1]); err2 = err1 - ((a_split[1] + a_split[1]) * a_split[0]); out[0] = (a_split[0] * a_split[0]) - err2; } static float d2d_fp_estimate(float *a, size_t len) { float out = a[0]; size_t idx = 1; while (idx < len) out += a[idx++]; return out; } static void d2d_fp_fast_expansion_sum_zeroelim(float *out, size_t *out_len, const float *a, size_t a_len, const float *b, size_t b_len) { float sum[2], q, a_curr, b_curr; size_t a_idx, b_idx, out_idx; a_curr = a[0]; b_curr = b[0]; a_idx = b_idx = 0; if ((b_curr > a_curr) == (b_curr > -a_curr)) { q = a_curr; a_curr = a[++a_idx]; } else { q = b_curr; b_curr = b[++b_idx]; } out_idx = 0; if (a_idx < a_len && b_idx < b_len) { if ((b_curr > a_curr) == (b_curr > -a_curr)) { d2d_fp_fast_two_sum(sum, a_curr, q); a_curr = a[++a_idx]; } else { d2d_fp_fast_two_sum(sum, b_curr, q); b_curr = b[++b_idx]; } if (sum[0] != 0.0f) out[out_idx++] = sum[0]; q = sum[1]; while (a_idx < a_len && b_idx < b_len) { if ((b_curr > a_curr) == (b_curr > -a_curr)) { d2d_fp_two_sum(sum, q, a_curr); a_curr = a[++a_idx]; } else { d2d_fp_two_sum(sum, q, b_curr); b_curr = b[++b_idx]; } if (sum[0] != 0.0f) out[out_idx++] = sum[0]; q = sum[1]; } } while (a_idx < a_len) { d2d_fp_two_sum(sum, q, a_curr); a_curr = a[++a_idx]; if (sum[0] != 0.0f) out[out_idx++] = sum[0]; q = sum[1]; } while (b_idx < b_len) { d2d_fp_two_sum(sum, q, b_curr); b_curr = b[++b_idx]; if (sum[0] != 0.0f) out[out_idx++] = sum[0]; q = sum[1]; } if (q != 0.0f || !out_idx) out[out_idx++] = q; *out_len = out_idx; } static void d2d_fp_scale_expansion_zeroelim(float *out, size_t *out_len, const float *a, size_t a_len, float b) { float product[2], sum[2], b_split[2], q[2], a_curr; size_t a_idx, out_idx; d2d_fp_split(b_split, b); d2d_fp_two_product_presplit(q, a[0], b, b_split); out_idx = 0; if (q[0] != 0.0f) out[out_idx++] = q[0]; for (a_idx = 1; a_idx < a_len; ++a_idx) { a_curr = a[a_idx]; d2d_fp_two_product_presplit(product, a_curr, b, b_split); d2d_fp_two_sum(sum, q[1], product[0]); if (sum[0] != 0.0f) out[out_idx++] = sum[0]; d2d_fp_fast_two_sum(q, product[1], sum[1]); if (q[0] != 0.0f) out[out_idx++] = q[0]; } if (q[1] != 0.0f || !out_idx) out[out_idx++] = q[1]; *out_len = out_idx; } static void d2d_point_subtract(D2D1_POINT_2F *out, const D2D1_POINT_2F *a, const D2D1_POINT_2F *b) { out->x = a->x - b->x; out->y = a->y - b->y; } static void d2d_point_scale(D2D1_POINT_2F *p, float scale) { p->x *= scale; p->y *= scale; } static void d2d_point_lerp(D2D1_POINT_2F *out, const D2D1_POINT_2F *a, const D2D1_POINT_2F *b, float t) { out->x = a->x * (1.0f - t) + b->x * t; out->y = a->y * (1.0f - t) + b->y * t; } static void d2d_point_calculate_bezier(D2D1_POINT_2F *out, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2, float t) { float t_c = 1.0f - t; out->x = t_c * (t_c * p0->x + t * p1->x) + t * (t_c * p1->x + t * p2->x); out->y = t_c * (t_c * p0->y + t * p1->y) + t * (t_c * p1->y + t * p2->y); } static float d2d_point_length(const D2D1_POINT_2F *p) { return sqrtf(d2d_point_dot(p, p)); } static void d2d_point_normalise(D2D1_POINT_2F *p) { float l; if ((l = d2d_point_length(p)) != 0.0f) d2d_point_scale(p, 1.0f / l); } static BOOL d2d_vertex_type_is_bezier(enum d2d_vertex_type t) { return (t == D2D_VERTEX_TYPE_BEZIER || t == D2D_VERTEX_TYPE_SPLIT_BEZIER); } static BOOL d2d_vertex_type_is_split_bezier(enum d2d_vertex_type t) { return t == D2D_VERTEX_TYPE_SPLIT_BEZIER; } /* This implementation is based on the paper "Adaptive Precision * Floating-Point Arithmetic and Fast Robust Geometric Predicates" and * associated (Public Domain) code by Jonathan Richard Shewchuk. */ static float d2d_point_ccw(const D2D1_POINT_2F *a, const D2D1_POINT_2F *b, const D2D1_POINT_2F *c) { static const float err_bound_result = (3.0f + 8.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_a = (3.0f + 16.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_b = (2.0f + 12.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_c = (9.0f + 64.0f * D2D_FP_EPS) * D2D_FP_EPS * D2D_FP_EPS; float det_d[16], det_c2[12], det_c1[8], det_b[4], temp4[4], temp2a[2], temp2b[2], abxacy[2], abyacx[2]; size_t det_d_len, det_c2_len, det_c1_len; float det, det_sum, err_bound; struct d2d_fp_two_vec2 ab, ac; ab.x[1] = b->x - a->x; ab.y[1] = b->y - a->y; ac.x[1] = c->x - a->x; ac.y[1] = c->y - a->y; abxacy[1] = ab.x[1] * ac.y[1]; abyacx[1] = ab.y[1] * ac.x[1]; det = abxacy[1] - abyacx[1]; if (abxacy[1] > 0.0f) { if (abyacx[1] <= 0.0f) return det; det_sum = abxacy[1] + abyacx[1]; } else if (abxacy[1] < 0.0f) { if (abyacx[1] >= 0.0f) return det; det_sum = -abxacy[1] - abyacx[1]; } else { return det; } err_bound = err_bound_a * det_sum; if (det >= err_bound || -det >= err_bound) return det; d2d_fp_two_product(abxacy, ab.x[1], ac.y[1]); d2d_fp_two_product(abyacx, ab.y[1], ac.x[1]); d2d_fp_two_two_diff(det_b, abxacy, abyacx); det = d2d_fp_estimate(det_b, 4); err_bound = err_bound_b * det_sum; if (det >= err_bound || -det >= err_bound) return det; d2d_fp_two_diff_tail(&ab.x[0], b->x, a->x, ab.x[1]); d2d_fp_two_diff_tail(&ab.y[0], b->y, a->y, ab.y[1]); d2d_fp_two_diff_tail(&ac.x[0], c->x, a->x, ac.x[1]); d2d_fp_two_diff_tail(&ac.y[0], c->y, a->y, ac.y[1]); if (ab.x[0] == 0.0f && ab.y[0] == 0.0f && ac.x[0] == 0.0f && ac.y[0] == 0.0f) return det; err_bound = err_bound_c * det_sum + err_bound_result * fabsf(det); det += (ab.x[1] * ac.y[0] + ac.y[1] * ab.x[0]) - (ab.y[1] * ac.x[0] + ac.x[1] * ab.y[0]); if (det >= err_bound || -det >= err_bound) return det; d2d_fp_two_product(temp2a, ab.x[0], ac.y[1]); d2d_fp_two_product(temp2b, ab.y[0], ac.x[1]); d2d_fp_two_two_diff(temp4, temp2a, temp2b); d2d_fp_fast_expansion_sum_zeroelim(det_c1, &det_c1_len, det_b, 4, temp4, 4); d2d_fp_two_product(temp2a, ab.x[1], ac.y[0]); d2d_fp_two_product(temp2b, ab.y[1], ac.x[0]); d2d_fp_two_two_diff(temp4, temp2a, temp2b); d2d_fp_fast_expansion_sum_zeroelim(det_c2, &det_c2_len, det_c1, det_c1_len, temp4, 4); d2d_fp_two_product(temp2a, ab.x[0], ac.y[0]); d2d_fp_two_product(temp2b, ab.y[0], ac.x[0]); d2d_fp_two_two_diff(temp4, temp2a, temp2b); d2d_fp_fast_expansion_sum_zeroelim(det_d, &det_d_len, det_c2, det_c2_len, temp4, 4); return det_d[det_d_len - 1]; } /* Determine whether the point q is within the given tolerance of the line * segment defined by p0 and p1, with the given stroke width and transform. * Note that we don't care about the tolerance with respect to end-points or * joins here; those are handled separately. */ static BOOL d2d_point_on_line_segment(const D2D1_POINT_2F *q, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_MATRIX_3X2_F *transform, float stroke_width, float tolerance) { D2D1_POINT_2F v_n, v_p, v_q, v_r; float l; d2d_point_subtract(&v_p, p1, p0); if ((l = d2d_point_length(&v_p)) == 0.0f) return FALSE; /* After (shear) transformation, the line segment is a parallelogram * defined by p⃑' and n⃑': * * p⃑ = P₁ - P₀ * n⃑ = wp̂⟂ * p⃑' = p⃑T * n⃑' = n⃑T */ l = stroke_width / l; d2d_point_set(&v_r, transform->_31, transform->_32); d2d_point_transform(&v_n, transform, -v_p.y * l, v_p.x * l); d2d_point_subtract(&v_n, &v_n, &v_r); d2d_point_transform(&v_p, transform, v_p.x, v_p.y); d2d_point_subtract(&v_p, &v_p, &v_r); /* Decompose the vector q⃑ = Q - P₀T into a linear combination of * p⃑' and n⃑': * * lq⃑ = xp⃑' + yn⃑' */ d2d_point_transform(&v_q, transform, p0->x, p0->y); d2d_point_subtract(&v_q, q, &v_q); l = v_p.x * v_n.y - v_p.y * v_n.x; v_r.x = v_q.x * v_n.y - v_q.y * v_n.x; v_r.y = v_q.x * v_p.y - v_q.y * v_p.x; if (l < 0.0f) { l *= -1.0f; v_r.x *= -1.0f; } /* Check where Q projects onto p⃑'. */ if (v_r.x < 0.0f || v_r.x > l) return FALSE; /* Check where Q projects onto n⃑'. */ if (fabs(v_r.y) < l) return TRUE; /* Q lies outside the segment. Check whether the distance to the edge is * within the tolerance. * * P₀' = P₀T + n⃑' * q⃑' = Q - P₀' * = q⃑ - n⃑' * * The distance is then q⃑' · p̂'⟂. */ if (v_r.y > 0.0f) d2d_point_scale(&v_n, -1.0f); d2d_point_subtract(&v_q, &v_q, &v_n); /* Check where Q projects onto p⃑' + n⃑'. */ l = d2d_point_dot(&v_q, &v_p); if (l < 0.0f || l > d2d_point_dot(&v_p, &v_p)) return FALSE; v_n.x = -v_p.y; v_n.y = v_p.x; d2d_point_normalise(&v_n); return fabsf(d2d_point_dot(&v_q, &v_n)) < tolerance; } /* Approximate the Bézier segment with a (wide) line segment. If the point * lies outside the approximation, we're done. If the width of the * approximation is less than the tolerance and the point lies inside, we're * also done. If neither of those is the case, we subdivide the Bézier segment * and try again. */ static BOOL d2d_point_on_bezier_segment(const D2D1_POINT_2F *q, const D2D1_POINT_2F *p0, const D2D1_BEZIER_SEGMENT *b, const D2D1_MATRIX_3X2_F *transform, float stroke_width, float tolerance) { float d1, d2, d3, d4, d, l, m, w, w2; D2D1_POINT_2F t[7], start, end, v_p; D2D1_BEZIER_SEGMENT b0, b1; m = 1.0f; w = stroke_width * 0.5f; d2d_point_subtract(&v_p, &b->point3, p0); /* If the endpoints coincide, use the line through the control points as * the direction vector. That choice is somewhat arbitrary; other choices * with tighter error bounds exist. */ if ((l = d2d_point_dot(&v_p, &v_p)) == 0.0f) { d2d_point_subtract(&v_p, &b->point2, &b->point1); /* If the control points also coincide, the curve is in fact a line. */ if ((l = d2d_point_dot(&v_p, &v_p)) == 0.0f) { d2d_point_subtract(&v_p, &b->point1, p0); end.x = p0->x + 0.75f * v_p.x; end.y = p0->y + 0.75f * v_p.y; return d2d_point_on_line_segment(q, p0, &end, transform, w, tolerance); } m = 0.0f; } l = sqrtf(l); d2d_point_scale(&v_p, 1.0f / l); m *= l; /* Calculate the width w2 of the approximation. */ end.x = p0->x + v_p.x; end.y = p0->y + v_p.y; /* Here, d1 and d2 are the maximum (signed) distance of the control points * from the line through the start and end points. */ d1 = d2d_point_ccw(p0, &end, &b->point1); d2 = d2d_point_ccw(p0, &end, &b->point2); /* It can be shown that if the control points of a cubic Bézier curve lie * on the same side of the line through the endpoints, the distance of the * curve itself to that line will be within 3/4 of the distance of the * control points to that line; if the control points lie on opposite * sides, that distance will be within 4/9 of the distance of the * corresponding control point. We're taking that as a given here. */ if (d1 * d2 > 0.0f) { d1 *= 0.75f; d2 *= 0.75f; } else { d1 = (d1 * 4.0f) / 9.0f; d2 = (d2 * 4.0f) / 9.0f; } w2 = max(fabsf(d1), fabsf(d2)); /* Project the control points onto the line through the endpoints of the * curve. We will use these to calculate the endpoints of the * approximation. */ d2d_point_subtract(&t[1], &b->point1, p0); d1 = d2d_point_dot(&v_p, &t[1]); d2d_point_subtract(&t[2], &b->point2, p0); d2 = d2d_point_dot(&v_p, &t[2]); /* Calculate the start point of the approximation. Like further above, the * actual curve is somewhat closer to the endpoints than the control * points are. */ d = min(min(d1, d2), 0); if (d1 * d2 > 0.0f) d *= 0.75f; else d = (d * 4.0f) / 9.0f; /* Account for the stroke width and tolerance around the endpoints by * adjusting the endpoints here. This matters because there are no joins * in the original geometry for the places where we subdivide the original * curve. We do this here because it's easy; alternatively we could * explicitly test for this when subdividing the curve further below. */ d -= min(w + tolerance, w2); start.x = p0->x + d * v_p.x; start.y = p0->y + d * v_p.y; /* Calculate the end point of the approximation. */ d1 -= m; d2 -= m; d = max(max(d1, d2), 0); if (d1 * d2 > 0.0f) d = m + d * 0.75f; else d = m + (d * 4.0f) / 9.0f; d += min(w2, w + tolerance); end.x = p0->x + d * v_p.x; end.y = p0->y + d * v_p.y; /* Calculate the error bounds of the approximation. We do this in * transformed space because we need these to be relative to the given * tolerance. */ d2d_point_transform(&t[0], transform, p0->x, p0->y); d2d_point_transform(&t[1], transform, b->point1.x, b->point1.y); d2d_point_transform(&t[2], transform, b->point2.x, b->point2.y); d2d_point_transform(&t[3], transform, b->point3.x, b->point3.y); d2d_point_transform(&t[4], transform, start.x, start.y); d2d_point_transform(&t[5], transform, end.x, end.y); d2d_point_subtract(&t[6], &t[5], &t[4]); l = d2d_point_length(&t[6]); /* Here, d1 and d2 are the maximum (signed) distance of the control points * from the line through the start and end points. */ d1 = d2d_point_ccw(&t[4], &t[5], &t[1]) / l; d2 = d2d_point_ccw(&t[4], &t[5], &t[2]) / l; if (d1 * d2 > 0.0f) { d1 *= 0.75f; d2 *= 0.75f; } else { d1 = (d1 * 4.0f) / 9.0f; d2 = (d2 * 4.0f) / 9.0f; } l = max(max(d1, d2), 0) - min(min(d1, d2), 0); /* d3 and d4 are the (unsigned) distance of the endpoints of the * approximation from the original endpoints. */ d2d_point_subtract(&t[6], &t[4], &t[0]); d3 = d2d_point_length(&t[6]); d2d_point_subtract(&t[6], &t[5], &t[3]); d4 = d2d_point_length(&t[6]); l = max(max(d3, d4), l); /* If the error of the approximation is less than the tolerance, and Q * lies on the approximation, the distance of Q to the stroked curve is * definitely within the tolerance. */ if (l <= tolerance && d2d_point_on_line_segment(q, &start, &end, transform, w, tolerance - l)) return TRUE; /* On the other hand, if the distance of Q to the stroked curve is more * than the sum of the tolerance and d, the distance of Q to the stroked * curve can't possibly be within the tolerance. */ if (!d2d_point_on_line_segment(q, &start, &end, transform, w + w2, tolerance)) return FALSE; /* Subdivide the curve. Note that simply splitting the segment in half * here works and is easy, but may not be optimal. We could potentially * reduce the number of iterations we need to do by splitting based on * curvature or segment length. */ d2d_point_lerp(&t[0], &b->point1, &b->point2, 0.5f); b1.point3 = b->point3; d2d_point_lerp(&b1.point2, &b->point3, &b->point2, 0.5f); d2d_point_lerp(&b1.point1, &t[0], &b1.point2, 0.5f); d2d_point_lerp(&b0.point1, p0, &b->point1, 0.5f); d2d_point_lerp(&b0.point2, &t[0], &b0.point1, 0.5f); d2d_point_lerp(&b0.point3, &b0.point2, &b1.point1, 0.5f); return d2d_point_on_bezier_segment(q, p0, &b0, transform, stroke_width, tolerance) || d2d_point_on_bezier_segment(q, &b0.point3, &b1, transform, stroke_width, tolerance); } static void d2d_rect_union(D2D1_RECT_F *l, const D2D1_RECT_F *r) { l->left = min(l->left, r->left); l->top = min(l->top, r->top); l->right = max(l->right, r->right); l->bottom = max(l->bottom, r->bottom); } static BOOL d2d_rect_check_overlap(const D2D_RECT_F *p, const D2D_RECT_F *q) { return p->left < q->right && p->top < q->bottom && p->right > q->left && p->bottom > q->top; } static void d2d_rect_get_bezier_bounds(D2D_RECT_F *bounds, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2) { D2D1_POINT_2F p; float root; bounds->left = p0->x; bounds->top = p0->y; bounds->right = p0->x; bounds->bottom = p0->y; d2d_rect_expand(bounds, p2); /* f(t) = (1 - t)²P₀ + 2(1 - t)tP₁ + t²P₂ * f'(t) = 2(1 - t)(P₁ - P₀) + 2t(P₂ - P₁) * = 2(P₂ - 2P₁ + P₀)t + 2(P₁ - P₀) * * f'(t) = 0 * t = (P₀ - P₁) / (P₂ - 2P₁ + P₀) */ root = (p0->x - p1->x) / (p2->x - 2.0f * p1->x + p0->x); if (root > 0.0f && root < 1.0f) { d2d_point_calculate_bezier(&p, p0, p1, p2, root); d2d_rect_expand(bounds, &p); } root = (p0->y - p1->y) / (p2->y - 2.0f * p1->y + p0->y); if (root > 0.0f && root < 1.0f) { d2d_point_calculate_bezier(&p, p0, p1, p2, root); d2d_rect_expand(bounds, &p); } } static void d2d_rect_get_bezier_segment_bounds(D2D_RECT_F *bounds, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2, float start, float end) { D2D1_POINT_2F q[3], r[2]; d2d_point_lerp(&r[0], p0, p1, start); d2d_point_lerp(&r[1], p1, p2, start); d2d_point_lerp(&q[0], &r[0], &r[1], start); end = (end - start) / (1.0f - start); d2d_point_lerp(&q[1], &q[0], &r[1], end); d2d_point_lerp(&r[0], &r[1], p2, end); d2d_point_lerp(&q[2], &q[1], &r[0], end); d2d_rect_get_bezier_bounds(bounds, &q[0], &q[1], &q[2]); } static BOOL d2d_figure_insert_vertex(struct d2d_figure *figure, size_t idx, D2D1_POINT_2F vertex) { if (!d2d_array_reserve((void **)&figure->vertices, &figure->vertices_size, figure->vertex_count + 1, sizeof(*figure->vertices))) { ERR("Failed to grow vertices array.\n"); return FALSE; } if (!d2d_array_reserve((void **)&figure->vertex_types, &figure->vertex_types_size, figure->vertex_count + 1, sizeof(*figure->vertex_types))) { ERR("Failed to grow vertex types array.\n"); return FALSE; } memmove(&figure->vertices[idx + 1], &figure->vertices[idx], (figure->vertex_count - idx) * sizeof(*figure->vertices)); memmove(&figure->vertex_types[idx + 1], &figure->vertex_types[idx], (figure->vertex_count - idx) * sizeof(*figure->vertex_types)); figure->vertices[idx] = vertex; figure->vertex_types[idx] = D2D_VERTEX_TYPE_NONE; d2d_rect_expand(&figure->bounds, &vertex); ++figure->vertex_count; return TRUE; } static BOOL d2d_figure_add_vertex(struct d2d_figure *figure, D2D1_POINT_2F vertex) { size_t last = figure->vertex_count - 1; if (figure->vertex_count && figure->vertex_types[last] == D2D_VERTEX_TYPE_LINE && !memcmp(&figure->vertices[last], &vertex, sizeof(vertex))) return TRUE; if (!d2d_array_reserve((void **)&figure->vertices, &figure->vertices_size, figure->vertex_count + 1, sizeof(*figure->vertices))) { ERR("Failed to grow vertices array.\n"); return FALSE; } if (!d2d_array_reserve((void **)&figure->vertex_types, &figure->vertex_types_size, figure->vertex_count + 1, sizeof(*figure->vertex_types))) { ERR("Failed to grow vertex types array.\n"); return FALSE; } figure->vertices[figure->vertex_count] = vertex; figure->vertex_types[figure->vertex_count] = D2D_VERTEX_TYPE_NONE; d2d_rect_expand(&figure->bounds, &vertex); ++figure->vertex_count; return TRUE; } static BOOL d2d_figure_insert_bezier_controls(struct d2d_figure *figure, size_t idx, size_t count, const D2D1_POINT_2F *p) { if (!d2d_array_reserve((void **)&figure->bezier_controls, &figure->bezier_controls_size, figure->bezier_control_count + count, sizeof(*figure->bezier_controls))) { ERR("Failed to grow bezier controls array.\n"); return FALSE; } memmove(&figure->bezier_controls[idx + count], &figure->bezier_controls[idx], (figure->bezier_control_count - idx) * sizeof(*figure->bezier_controls)); memcpy(&figure->bezier_controls[idx], p, count * sizeof(*figure->bezier_controls)); figure->bezier_control_count += count; return TRUE; } static BOOL d2d_figure_add_bezier_controls(struct d2d_figure *figure, size_t count, const D2D1_POINT_2F *p) { if (!d2d_array_reserve((void **)&figure->bezier_controls, &figure->bezier_controls_size, figure->bezier_control_count + count, sizeof(*figure->bezier_controls))) { ERR("Failed to grow bezier controls array.\n"); return FALSE; } memcpy(&figure->bezier_controls[figure->bezier_control_count], p, count * sizeof(*figure->bezier_controls)); figure->bezier_control_count += count; return TRUE; } static BOOL d2d_figure_add_original_bezier_controls(struct d2d_figure *figure, size_t count, const D2D1_POINT_2F *p) { if (!d2d_array_reserve((void **)&figure->original_bezier_controls, &figure->original_bezier_controls_size, figure->original_bezier_control_count + count, sizeof(*figure->original_bezier_controls))) { ERR("Failed to grow cubic Bézier controls array.\n"); return FALSE; } memcpy(&figure->original_bezier_controls[figure->original_bezier_control_count], p, count * sizeof(*figure->original_bezier_controls)); figure->original_bezier_control_count += count; return TRUE; } static void d2d_cdt_edge_rot(struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { dst->idx = src->idx; dst->r = (src->r + D2D_EDGE_NEXT_ROT) & 3; } static void d2d_cdt_edge_sym(struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { dst->idx = src->idx; dst->r = (src->r + D2D_EDGE_NEXT_SYM) & 3; } static void d2d_cdt_edge_tor(struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { dst->idx = src->idx; dst->r = (src->r + D2D_EDGE_NEXT_TOR) & 3; } static void d2d_cdt_edge_next_left(const struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { d2d_cdt_edge_rot(dst, &cdt->edges[src->idx].next[(src->r + D2D_EDGE_NEXT_TOR) & 3]); } static void d2d_cdt_edge_next_origin(const struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { *dst = cdt->edges[src->idx].next[src->r]; } static void d2d_cdt_edge_prev_origin(const struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *dst, const struct d2d_cdt_edge_ref *src) { d2d_cdt_edge_rot(dst, &cdt->edges[src->idx].next[(src->r + D2D_EDGE_NEXT_ROT) & 3]); } static size_t d2d_cdt_edge_origin(const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *e) { return cdt->edges[e->idx].vertex[e->r >> 1]; } static size_t d2d_cdt_edge_destination(const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *e) { return cdt->edges[e->idx].vertex[!(e->r >> 1)]; } static void d2d_cdt_edge_set_origin(const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *e, size_t vertex) { cdt->edges[e->idx].vertex[e->r >> 1] = vertex; } static void d2d_cdt_edge_set_destination(const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *e, size_t vertex) { cdt->edges[e->idx].vertex[!(e->r >> 1)] = vertex; } static float d2d_cdt_ccw(const struct d2d_cdt *cdt, size_t a, size_t b, size_t c) { return d2d_point_ccw(&cdt->vertices[a], &cdt->vertices[b], &cdt->vertices[c]); } static BOOL d2d_cdt_rightof(const struct d2d_cdt *cdt, size_t p, const struct d2d_cdt_edge_ref *e) { return d2d_cdt_ccw(cdt, p, d2d_cdt_edge_destination(cdt, e), d2d_cdt_edge_origin(cdt, e)) > 0.0f; } static BOOL d2d_cdt_leftof(const struct d2d_cdt *cdt, size_t p, const struct d2d_cdt_edge_ref *e) { return d2d_cdt_ccw(cdt, p, d2d_cdt_edge_origin(cdt, e), d2d_cdt_edge_destination(cdt, e)) > 0.0f; } /* |ax ay| * |bx by| */ static void d2d_fp_four_det2x2(float *out, float ax, float ay, float bx, float by) { float axby[2], aybx[2]; d2d_fp_two_product(axby, ax, by); d2d_fp_two_product(aybx, ay, bx); d2d_fp_two_two_diff(out, axby, aybx); } /* (a->x² + a->y²) * det2x2 */ static void d2d_fp_sub_det3x3(float *out, size_t *out_len, const struct d2d_fp_two_vec2 *a, const float *det2x2) { size_t axd_len, ayd_len, axxd_len, ayyd_len; float axd[8], ayd[8], axxd[16], ayyd[16]; d2d_fp_scale_expansion_zeroelim(axd, &axd_len, det2x2, 4, a->x[1]); d2d_fp_scale_expansion_zeroelim(axxd, &axxd_len, axd, axd_len, a->x[1]); d2d_fp_scale_expansion_zeroelim(ayd, &ayd_len, det2x2, 4, a->y[1]); d2d_fp_scale_expansion_zeroelim(ayyd, &ayyd_len, ayd, ayd_len, a->y[1]); d2d_fp_fast_expansion_sum_zeroelim(out, out_len, axxd, axxd_len, ayyd, ayyd_len); } /* det_abt = det_ab * c[0] * fin += c[0] * (az * b - bz * a + c[1] * det_ab * 2.0f) */ static void d2d_cdt_incircle_refine1(struct d2d_fp_fin *fin, float *det_abt, size_t *det_abt_len, const float *det_ab, float a, const float *az, float b, const float *bz, const float *c) { size_t temp48_len, temp32_len, temp16a_len, temp16b_len, temp16c_len, temp8_len; float temp48[48], temp32[32], temp16a[16], temp16b[16], temp16c[16], temp8[8]; float *swap; d2d_fp_scale_expansion_zeroelim(det_abt, det_abt_len, det_ab, 4, c[0]); d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, det_abt, *det_abt_len, 2.0f * c[1]); d2d_fp_scale_expansion_zeroelim(temp8, &temp8_len, az, 4, c[0]); d2d_fp_scale_expansion_zeroelim(temp16b, &temp16b_len, temp8, temp8_len, b); d2d_fp_scale_expansion_zeroelim(temp8, &temp8_len, bz, 4, c[0]); d2d_fp_scale_expansion_zeroelim(temp16c, &temp16c_len, temp8, temp8_len, -a); d2d_fp_fast_expansion_sum_zeroelim(temp32, &temp32_len, temp16a, temp16a_len, temp16b, temp16b_len); d2d_fp_fast_expansion_sum_zeroelim(temp48, &temp48_len, temp16c, temp16c_len, temp32, temp32_len); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp48, temp48_len); swap = fin->now; fin->now = fin->other; fin->other = swap; } static void d2d_cdt_incircle_refine2(struct d2d_fp_fin *fin, const struct d2d_fp_two_vec2 *a, const struct d2d_fp_two_vec2 *b, const float *bz, const struct d2d_fp_two_vec2 *c, const float *cz, const float *axt_det_bc, size_t axt_det_bc_len, const float *ayt_det_bc, size_t ayt_det_bc_len) { size_t temp64_len, temp48_len, temp32a_len, temp32b_len, temp16a_len, temp16b_len, temp8_len; float temp64[64], temp48[48], temp32a[32], temp32b[32], temp16a[16], temp16b[16], temp8[8]; float bct[8], bctt[4], temp4a[4], temp4b[4], temp2a[2], temp2b[2]; size_t bct_len, bctt_len; float *swap; /* bct = (b->x[0] * c->y[1] + b->x[1] * c->y[0]) - (c->x[0] * b->y[1] + c->x[1] * b->y[0]) */ /* bctt = b->x[0] * c->y[0] + c->x[0] * b->y[0] */ if (b->x[0] != 0.0f || b->y[0] != 0.0f || c->x[0] != 0.0f || c->y[0] != 0.0f) { d2d_fp_two_product(temp2a, b->x[0], c->y[1]); d2d_fp_two_product(temp2b, b->x[1], c->y[0]); d2d_fp_two_two_sum(temp4a, temp2a, temp2b); d2d_fp_two_product(temp2a, c->x[0], -b->y[1]); d2d_fp_two_product(temp2b, c->x[1], -b->y[0]); d2d_fp_two_two_sum(temp4b, temp2a, temp2b); d2d_fp_fast_expansion_sum_zeroelim(bct, &bct_len, temp4a, 4, temp4b, 4); d2d_fp_two_product(temp2a, b->x[0], c->y[0]); d2d_fp_two_product(temp2b, c->x[0], b->y[0]); d2d_fp_two_two_diff(bctt, temp2a, temp2b); bctt_len = 4; } else { bct[0] = 0.0f; bct_len = 1; bctt[0] = 0.0f; bctt_len = 1; } if (a->x[0] != 0.0f) { size_t axt_bct_len, axt_bctt_len; float axt_bct[16], axt_bctt[8]; /* fin += a->x[0] * (axt_det_bc + bct * 2.0f * a->x[1]) */ d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, axt_det_bc, axt_det_bc_len, a->x[0]); d2d_fp_scale_expansion_zeroelim(axt_bct, &axt_bct_len, bct, bct_len, a->x[0]); d2d_fp_scale_expansion_zeroelim(temp32a, &temp32a_len, axt_bct, axt_bct_len, 2.0f * a->x[1]); d2d_fp_fast_expansion_sum_zeroelim(temp48, &temp48_len, temp16a, temp16a_len, temp32a, temp32a_len); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp48, temp48_len); swap = fin->now; fin->now = fin->other; fin->other = swap; if (b->y[0] != 0.0f) { /* fin += a->x[0] * cz * b->y[0] */ d2d_fp_scale_expansion_zeroelim(temp8, &temp8_len, cz, 4, a->x[0]); d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, temp8, temp8_len, b->y[0]); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp16a, temp16a_len); swap = fin->now; fin->now = fin->other; fin->other = swap; } if (c->y[0] != 0.0f) { /* fin -= a->x[0] * bz * c->y[0] */ d2d_fp_scale_expansion_zeroelim(temp8, &temp8_len, bz, 4, -a->x[0]); d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, temp8, temp8_len, c->y[0]); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp16a, temp16a_len); swap = fin->now; fin->now = fin->other; fin->other = swap; } /* fin += a->x[0] * (bct * a->x[0] + bctt * (2.0f * a->x[1] + a->x[0])) */ d2d_fp_scale_expansion_zeroelim(temp32a, &temp32a_len, axt_bct, axt_bct_len, a->x[0]); d2d_fp_scale_expansion_zeroelim(axt_bctt, &axt_bctt_len, bctt, bctt_len, a->x[0]); d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, axt_bctt, axt_bctt_len, 2.0f * a->x[1]); d2d_fp_scale_expansion_zeroelim(temp16b, &temp16b_len, axt_bctt, axt_bctt_len, a->x[0]); d2d_fp_fast_expansion_sum_zeroelim(temp32b, &temp32b_len, temp16a, temp16a_len, temp16b, temp16b_len); d2d_fp_fast_expansion_sum_zeroelim(temp64, &temp64_len, temp32a, temp32a_len, temp32b, temp32b_len); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp64, temp64_len); swap = fin->now; fin->now = fin->other; fin->other = swap; } if (a->y[0] != 0.0f) { size_t ayt_bct_len, ayt_bctt_len; float ayt_bct[16], ayt_bctt[8]; /* fin += a->y[0] * (ayt_det_bc + bct * 2.0f * a->y[1]) */ d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, ayt_det_bc, ayt_det_bc_len, a->y[0]); d2d_fp_scale_expansion_zeroelim(ayt_bct, &ayt_bct_len, bct, bct_len, a->y[0]); d2d_fp_scale_expansion_zeroelim(temp32a, &temp32a_len, ayt_bct, ayt_bct_len, 2.0f * a->y[1]); d2d_fp_fast_expansion_sum_zeroelim(temp48, &temp48_len, temp16a, temp16a_len, temp32a, temp32a_len); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp48, temp48_len); swap = fin->now; fin->now = fin->other; fin->other = swap; /* fin += a->y[0] * (bct * a->y[0] + bctt * (2.0f * a->y[1] + a->y[0])) */ d2d_fp_scale_expansion_zeroelim(temp32a, &temp32a_len, ayt_bct, ayt_bct_len, a->y[0]); d2d_fp_scale_expansion_zeroelim(ayt_bctt, &ayt_bctt_len, bctt, bctt_len, a->y[0]); d2d_fp_scale_expansion_zeroelim(temp16a, &temp16a_len, ayt_bctt, ayt_bctt_len, 2.0f * a->y[1]); d2d_fp_scale_expansion_zeroelim(temp16b, &temp16b_len, ayt_bctt, ayt_bctt_len, a->y[0]); d2d_fp_fast_expansion_sum_zeroelim(temp32b, &temp32b_len, temp16a, temp16a_len, temp16b, temp16b_len); d2d_fp_fast_expansion_sum_zeroelim(temp64, &temp64_len, temp32a, temp32a_len, temp32b, temp32b_len); d2d_fp_fast_expansion_sum_zeroelim(fin->other, &fin->length, fin->now, fin->length, temp64, temp64_len); swap = fin->now; fin->now = fin->other; fin->other = swap; } } /* Determine if point D is inside or outside the circle defined by points A, * B, C. As explained in the paper by Guibas and Stolfi, this is equivalent to * calculating the signed volume of the tetrahedron defined by projecting the * points onto the paraboloid of revolution x = x² + y², * λ:(x, y) → (x, y, x² + y²). I.e., D is inside the cirlce if * * |λ(A) 1| * |λ(B) 1| > 0 * |λ(C) 1| * |λ(D) 1| * * After translating D to the origin, that becomes: * * |λ(A-D)| * |λ(B-D)| > 0 * |λ(C-D)| * * This implementation is based on the paper "Adaptive Precision * Floating-Point Arithmetic and Fast Robust Geometric Predicates" and * associated (Public Domain) code by Jonathan Richard Shewchuk. */ static BOOL d2d_cdt_incircle(const struct d2d_cdt *cdt, size_t a, size_t b, size_t c, size_t d) { static const float err_bound_result = (3.0f + 8.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_a = (10.0f + 96.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_b = (4.0f + 48.0f * D2D_FP_EPS) * D2D_FP_EPS; static const float err_bound_c = (44.0f + 576.0f * D2D_FP_EPS) * D2D_FP_EPS * D2D_FP_EPS; size_t axt_det_bc_len, ayt_det_bc_len, bxt_det_ca_len, byt_det_ca_len, cxt_det_ab_len, cyt_det_ab_len; float axt_det_bc[8], ayt_det_bc[8], bxt_det_ca[8], byt_det_ca[8], cxt_det_ab[8], cyt_det_ab[8]; float fin1[1152], fin2[1152], temp64[64], sub_det_a[32], sub_det_b[32], sub_det_c[32]; float det_bc[4], det_ca[4], det_ab[4], daz[4], dbz[4], dcz[4], temp2a[2], temp2b[2]; size_t temp64_len, sub_det_a_len, sub_det_b_len, sub_det_c_len; float dbxdcy, dbydcx, dcxday, dcydax, daxdby, daydbx; const D2D1_POINT_2F *p = cdt->vertices; struct d2d_fp_two_vec2 da, db, dc; float permanent, err_bound, det; struct d2d_fp_fin fin; da.x[1] = p[a].x - p[d].x; da.y[1] = p[a].y - p[d].y; db.x[1] = p[b].x - p[d].x; db.y[1] = p[b].y - p[d].y; dc.x[1] = p[c].x - p[d].x; dc.y[1] = p[c].y - p[d].y; daz[3] = da.x[1] * da.x[1] + da.y[1] * da.y[1]; dbxdcy = db.x[1] * dc.y[1]; dbydcx = db.y[1] * dc.x[1]; dbz[3] = db.x[1] * db.x[1] + db.y[1] * db.y[1]; dcxday = dc.x[1] * da.y[1]; dcydax = dc.y[1] * da.x[1]; dcz[3] = dc.x[1] * dc.x[1] + dc.y[1] * dc.y[1]; daxdby = da.x[1] * db.y[1]; daydbx = da.y[1] * db.x[1]; det = daz[3] * (dbxdcy - dbydcx) + dbz[3] * (dcxday - dcydax) + dcz[3] * (daxdby - daydbx); permanent = daz[3] * (fabsf(dbxdcy) + fabsf(dbydcx)) + dbz[3] * (fabsf(dcxday) + fabsf(dcydax)) + dcz[3] * (fabsf(daxdby) + fabsf(daydbx)); err_bound = err_bound_a * permanent; if (det > err_bound || -det > err_bound) return det > 0.0f; fin.now = fin1; fin.other = fin2; d2d_fp_four_det2x2(det_bc, db.x[1], db.y[1], dc.x[1], dc.y[1]); d2d_fp_sub_det3x3(sub_det_a, &sub_det_a_len, &da, det_bc); d2d_fp_four_det2x2(det_ca, dc.x[1], dc.y[1], da.x[1], da.y[1]); d2d_fp_sub_det3x3(sub_det_b, &sub_det_b_len, &db, det_ca); d2d_fp_four_det2x2(det_ab, da.x[1], da.y[1], db.x[1], db.y[1]); d2d_fp_sub_det3x3(sub_det_c, &sub_det_c_len, &dc, det_ab); d2d_fp_fast_expansion_sum_zeroelim(temp64, &temp64_len, sub_det_a, sub_det_a_len, sub_det_b, sub_det_b_len); d2d_fp_fast_expansion_sum_zeroelim(fin.now, &fin.length, temp64, temp64_len, sub_det_c, sub_det_c_len); det = d2d_fp_estimate(fin.now, fin.length); err_bound = err_bound_b * permanent; if (det >= err_bound || -det >= err_bound) return det > 0.0f; d2d_fp_two_diff_tail(&da.x[0], p[a].x, p[d].x, da.x[1]); d2d_fp_two_diff_tail(&da.y[0], p[a].y, p[d].y, da.y[1]); d2d_fp_two_diff_tail(&db.x[0], p[b].x, p[d].x, db.x[1]); d2d_fp_two_diff_tail(&db.y[0], p[b].y, p[d].y, db.y[1]); d2d_fp_two_diff_tail(&dc.x[0], p[c].x, p[d].x, dc.x[1]); d2d_fp_two_diff_tail(&dc.y[0], p[c].y, p[d].y, dc.y[1]); if (da.x[0] == 0.0f && db.x[0] == 0.0f && dc.x[0] == 0.0f && da.y[0] == 0.0f && db.y[0] == 0.0f && dc.y[0] == 0.0f) return det > 0.0f; err_bound = err_bound_c * permanent + err_bound_result * fabsf(det); det += (daz[3] * ((db.x[1] * dc.y[0] + dc.y[1] * db.x[0]) - (db.y[1] * dc.x[0] + dc.x[1] * db.y[0])) + 2.0f * (da.x[1] * da.x[0] + da.y[1] * da.y[0]) * (db.x[1] * dc.y[1] - db.y[1] * dc.x[1])) + (dbz[3] * ((dc.x[1] * da.y[0] + da.y[1] * dc.x[0]) - (dc.y[1] * da.x[0] + da.x[1] * dc.y[0])) + 2.0f * (db.x[1] * db.x[0] + db.y[1] * db.y[0]) * (dc.x[1] * da.y[1] - dc.y[1] * da.x[1])) + (dcz[3] * ((da.x[1] * db.y[0] + db.y[1] * da.x[0]) - (da.y[1] * db.x[0] + db.x[1] * da.y[0])) + 2.0f * (dc.x[1] * dc.x[0] + dc.y[1] * dc.y[0]) * (da.x[1] * db.y[1] - da.y[1] * db.x[1])); if (det >= err_bound || -det >= err_bound) return det > 0.0f; if (db.x[0] != 0.0f || db.y[0] != 0.0f || dc.x[0] != 0.0f || dc.y[0] != 0.0f) { d2d_fp_square(temp2a, da.x[1]); d2d_fp_square(temp2b, da.y[1]); d2d_fp_two_two_sum(daz, temp2a, temp2b); } if (dc.x[0] != 0.0f || dc.y[0] != 0.0f || da.x[0] != 0.0f || da.y[0] != 0.0f) { d2d_fp_square(temp2a, db.x[1]); d2d_fp_square(temp2b, db.y[1]); d2d_fp_two_two_sum(dbz, temp2a, temp2b); } if (da.x[0] != 0.0f || da.y[0] != 0.0f || db.x[0] != 0.0f || db.y[0] != 0.0f) { d2d_fp_square(temp2a, dc.x[1]); d2d_fp_square(temp2b, dc.y[1]); d2d_fp_two_two_sum(dcz, temp2a, temp2b); } if (da.x[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, axt_det_bc, &axt_det_bc_len, det_bc, dc.y[1], dcz, db.y[1], dbz, da.x); if (da.y[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, ayt_det_bc, &ayt_det_bc_len, det_bc, db.x[1], dbz, dc.x[1], dcz, da.y); if (db.x[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, bxt_det_ca, &bxt_det_ca_len, det_ca, da.y[1], daz, dc.y[1], dcz, db.x); if (db.y[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, byt_det_ca, &byt_det_ca_len, det_ca, dc.x[1], dcz, da.x[1], daz, db.y); if (dc.x[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, cxt_det_ab, &cxt_det_ab_len, det_ab, db.y[1], dbz, da.y[1], daz, dc.x); if (dc.y[0] != 0.0f) d2d_cdt_incircle_refine1(&fin, cyt_det_ab, &cyt_det_ab_len, det_ab, da.x[1], daz, db.x[1], dbz, dc.y); if (da.x[0] != 0.0f || da.y[0] != 0.0f) d2d_cdt_incircle_refine2(&fin, &da, &db, dbz, &dc, dcz, axt_det_bc, axt_det_bc_len, ayt_det_bc, ayt_det_bc_len); if (db.x[0] != 0.0f || db.y[0] != 0.0f) d2d_cdt_incircle_refine2(&fin, &db, &dc, dcz, &da, daz, bxt_det_ca, bxt_det_ca_len, byt_det_ca, byt_det_ca_len); if (dc.x[0] != 0.0f || dc.y[0] != 0.0f) d2d_cdt_incircle_refine2(&fin, &dc, &da, daz, &db, dbz, cxt_det_ab, cxt_det_ab_len, cyt_det_ab, cyt_det_ab_len); return fin.now[fin.length - 1] > 0.0f; } static void d2d_cdt_splice(const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *a, const struct d2d_cdt_edge_ref *b) { struct d2d_cdt_edge_ref ta, tb, alpha, beta; ta = cdt->edges[a->idx].next[a->r]; tb = cdt->edges[b->idx].next[b->r]; cdt->edges[a->idx].next[a->r] = tb; cdt->edges[b->idx].next[b->r] = ta; d2d_cdt_edge_rot(&alpha, &ta); d2d_cdt_edge_rot(&beta, &tb); ta = cdt->edges[alpha.idx].next[alpha.r]; tb = cdt->edges[beta.idx].next[beta.r]; cdt->edges[alpha.idx].next[alpha.r] = tb; cdt->edges[beta.idx].next[beta.r] = ta; } static BOOL d2d_cdt_create_edge(struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *e) { struct d2d_cdt_edge *edge; if (cdt->free_edge != ~0u) { e->idx = cdt->free_edge; cdt->free_edge = cdt->edges[e->idx].next[D2D_EDGE_NEXT_ORIGIN].idx; } else { if (!d2d_array_reserve((void **)&cdt->edges, &cdt->edges_size, cdt->edge_count + 1, sizeof(*cdt->edges))) { ERR("Failed to grow edges array.\n"); return FALSE; } e->idx = cdt->edge_count++; } e->r = 0; edge = &cdt->edges[e->idx]; edge->next[D2D_EDGE_NEXT_ORIGIN] = *e; d2d_cdt_edge_tor(&edge->next[D2D_EDGE_NEXT_ROT], e); d2d_cdt_edge_sym(&edge->next[D2D_EDGE_NEXT_SYM], e); d2d_cdt_edge_rot(&edge->next[D2D_EDGE_NEXT_TOR], e); edge->flags = 0; return TRUE; } static void d2d_cdt_destroy_edge(struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *e) { struct d2d_cdt_edge_ref next, sym, prev; d2d_cdt_edge_next_origin(cdt, &next, e); if (next.idx != e->idx || next.r != e->r) { d2d_cdt_edge_prev_origin(cdt, &prev, e); d2d_cdt_splice(cdt, e, &prev); } d2d_cdt_edge_sym(&sym, e); d2d_cdt_edge_next_origin(cdt, &next, &sym); if (next.idx != sym.idx || next.r != sym.r) { d2d_cdt_edge_prev_origin(cdt, &prev, &sym); d2d_cdt_splice(cdt, &sym, &prev); } cdt->edges[e->idx].flags |= D2D_CDT_EDGE_FLAG_FREED; cdt->edges[e->idx].next[D2D_EDGE_NEXT_ORIGIN].idx = cdt->free_edge; cdt->free_edge = e->idx; } static BOOL d2d_cdt_connect(struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *e, const struct d2d_cdt_edge_ref *a, const struct d2d_cdt_edge_ref *b) { struct d2d_cdt_edge_ref tmp; if (!d2d_cdt_create_edge(cdt, e)) return FALSE; d2d_cdt_edge_set_origin(cdt, e, d2d_cdt_edge_destination(cdt, a)); d2d_cdt_edge_set_destination(cdt, e, d2d_cdt_edge_origin(cdt, b)); d2d_cdt_edge_next_left(cdt, &tmp, a); d2d_cdt_splice(cdt, e, &tmp); d2d_cdt_edge_sym(&tmp, e); d2d_cdt_splice(cdt, &tmp, b); return TRUE; } static BOOL d2d_cdt_merge(struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *left_outer, struct d2d_cdt_edge_ref *left_inner, struct d2d_cdt_edge_ref *right_inner, struct d2d_cdt_edge_ref *right_outer) { struct d2d_cdt_edge_ref base_edge, tmp; /* Create the base edge between both parts. */ for (;;) { if (d2d_cdt_leftof(cdt, d2d_cdt_edge_origin(cdt, right_inner), left_inner)) { d2d_cdt_edge_next_left(cdt, left_inner, left_inner); } else if (d2d_cdt_rightof(cdt, d2d_cdt_edge_origin(cdt, left_inner), right_inner)) { d2d_cdt_edge_sym(&tmp, right_inner); d2d_cdt_edge_next_origin(cdt, right_inner, &tmp); } else { break; } } d2d_cdt_edge_sym(&tmp, right_inner); if (!d2d_cdt_connect(cdt, &base_edge, &tmp, left_inner)) return FALSE; if (d2d_cdt_edge_origin(cdt, left_inner) == d2d_cdt_edge_origin(cdt, left_outer)) d2d_cdt_edge_sym(left_outer, &base_edge); if (d2d_cdt_edge_origin(cdt, right_inner) == d2d_cdt_edge_origin(cdt, right_outer)) *right_outer = base_edge; for (;;) { struct d2d_cdt_edge_ref left_candidate, right_candidate, sym_base_edge; BOOL left_valid, right_valid; /* Find the left candidate. */ d2d_cdt_edge_sym(&sym_base_edge, &base_edge); d2d_cdt_edge_next_origin(cdt, &left_candidate, &sym_base_edge); if ((left_valid = d2d_cdt_leftof(cdt, d2d_cdt_edge_destination(cdt, &left_candidate), &sym_base_edge))) { d2d_cdt_edge_next_origin(cdt, &tmp, &left_candidate); while (d2d_cdt_edge_destination(cdt, &tmp) != d2d_cdt_edge_destination(cdt, &sym_base_edge) && d2d_cdt_incircle(cdt, d2d_cdt_edge_origin(cdt, &sym_base_edge), d2d_cdt_edge_destination(cdt, &sym_base_edge), d2d_cdt_edge_destination(cdt, &left_candidate), d2d_cdt_edge_destination(cdt, &tmp))) { d2d_cdt_destroy_edge(cdt, &left_candidate); left_candidate = tmp; d2d_cdt_edge_next_origin(cdt, &tmp, &left_candidate); } } d2d_cdt_edge_sym(&left_candidate, &left_candidate); /* Find the right candidate. */ d2d_cdt_edge_prev_origin(cdt, &right_candidate, &base_edge); if ((right_valid = d2d_cdt_rightof(cdt, d2d_cdt_edge_destination(cdt, &right_candidate), &base_edge))) { d2d_cdt_edge_prev_origin(cdt, &tmp, &right_candidate); while (d2d_cdt_edge_destination(cdt, &tmp) != d2d_cdt_edge_destination(cdt, &base_edge) && d2d_cdt_incircle(cdt, d2d_cdt_edge_origin(cdt, &sym_base_edge), d2d_cdt_edge_destination(cdt, &sym_base_edge), d2d_cdt_edge_destination(cdt, &right_candidate), d2d_cdt_edge_destination(cdt, &tmp))) { d2d_cdt_destroy_edge(cdt, &right_candidate); right_candidate = tmp; d2d_cdt_edge_prev_origin(cdt, &tmp, &right_candidate); } } if (!left_valid && !right_valid) break; /* Connect the appropriate candidate with the base edge. */ if (!left_valid || (right_valid && d2d_cdt_incircle(cdt, d2d_cdt_edge_origin(cdt, &left_candidate), d2d_cdt_edge_destination(cdt, &left_candidate), d2d_cdt_edge_origin(cdt, &right_candidate), d2d_cdt_edge_destination(cdt, &right_candidate)))) { if (!d2d_cdt_connect(cdt, &base_edge, &right_candidate, &sym_base_edge)) return FALSE; } else { if (!d2d_cdt_connect(cdt, &base_edge, &sym_base_edge, &left_candidate)) return FALSE; } } return TRUE; } /* Create a Delaunay triangulation from a set of vertices. This is an * implementation of the divide-and-conquer algorithm described by Guibas and * Stolfi. Should be called with at least two vertices. */ static BOOL d2d_cdt_triangulate(struct d2d_cdt *cdt, size_t start_vertex, size_t vertex_count, struct d2d_cdt_edge_ref *left_edge, struct d2d_cdt_edge_ref *right_edge) { struct d2d_cdt_edge_ref left_inner, left_outer, right_inner, right_outer, tmp; size_t cut; /* Only two vertices, create a single edge. */ if (vertex_count == 2) { struct d2d_cdt_edge_ref a; if (!d2d_cdt_create_edge(cdt, &a)) return FALSE; d2d_cdt_edge_set_origin(cdt, &a, start_vertex); d2d_cdt_edge_set_destination(cdt, &a, start_vertex + 1); *left_edge = a; d2d_cdt_edge_sym(right_edge, &a); return TRUE; } /* Three vertices, create a triangle. */ if (vertex_count == 3) { struct d2d_cdt_edge_ref a, b, c; float det; if (!d2d_cdt_create_edge(cdt, &a)) return FALSE; if (!d2d_cdt_create_edge(cdt, &b)) return FALSE; d2d_cdt_edge_sym(&tmp, &a); d2d_cdt_splice(cdt, &tmp, &b); d2d_cdt_edge_set_origin(cdt, &a, start_vertex); d2d_cdt_edge_set_destination(cdt, &a, start_vertex + 1); d2d_cdt_edge_set_origin(cdt, &b, start_vertex + 1); d2d_cdt_edge_set_destination(cdt, &b, start_vertex + 2); det = d2d_cdt_ccw(cdt, start_vertex, start_vertex + 1, start_vertex + 2); if (det != 0.0f && !d2d_cdt_connect(cdt, &c, &b, &a)) return FALSE; if (det < 0.0f) { d2d_cdt_edge_sym(left_edge, &c); *right_edge = c; } else { *left_edge = a; d2d_cdt_edge_sym(right_edge, &b); } return TRUE; } /* More than tree vertices, divide. */ cut = vertex_count / 2; if (!d2d_cdt_triangulate(cdt, start_vertex, cut, &left_outer, &left_inner)) return FALSE; if (!d2d_cdt_triangulate(cdt, start_vertex + cut, vertex_count - cut, &right_inner, &right_outer)) return FALSE; /* Merge the left and right parts. */ if (!d2d_cdt_merge(cdt, &left_outer, &left_inner, &right_inner, &right_outer)) return FALSE; *left_edge = left_outer; *right_edge = right_outer; return TRUE; } static int __cdecl d2d_cdt_compare_vertices(const void *a, const void *b) { const D2D1_POINT_2F *p0 = a; const D2D1_POINT_2F *p1 = b; float diff = p0->x - p1->x; if (diff == 0.0f) diff = p0->y - p1->y; return diff == 0.0f ? 0 : (diff > 0.0f ? 1 : -1); } /* Determine whether a given point is inside the geometry, using the current * fill mode rule. */ static BOOL d2d_path_geometry_point_inside(const struct d2d_geometry *geometry, const D2D1_POINT_2F *probe, BOOL triangles_only) { const D2D1_POINT_2F *p0, *p1; D2D1_POINT_2F v_p, v_probe; unsigned int score; size_t i, j, last; for (i = 0, score = 0; i < geometry->u.path.figure_count; ++i) { const struct d2d_figure *figure = &geometry->u.path.figures[i]; if (probe->x < figure->bounds.left || probe->x > figure->bounds.right || probe->y < figure->bounds.top || probe->y > figure->bounds.bottom) continue; last = figure->vertex_count - 1; if (!triangles_only) { while (last && figure->vertex_types[last] == D2D_VERTEX_TYPE_NONE) --last; } p0 = &figure->vertices[last]; for (j = 0; j <= last; ++j) { if (!triangles_only && figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE) continue; p1 = &figure->vertices[j]; d2d_point_subtract(&v_p, p1, p0); d2d_point_subtract(&v_probe, probe, p0); if ((probe->y < p0->y) != (probe->y < p1->y) && v_probe.x < v_p.x * (v_probe.y / v_p.y)) { if (geometry->u.path.fill_mode == D2D1_FILL_MODE_ALTERNATE || (probe->y < p0->y)) ++score; else --score; } p0 = p1; } } return geometry->u.path.fill_mode == D2D1_FILL_MODE_ALTERNATE ? score & 1 : score; } static BOOL d2d_path_geometry_add_fill_face(struct d2d_geometry *geometry, const struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *base_edge) { struct d2d_cdt_edge_ref tmp; struct d2d_face *face; D2D1_POINT_2F probe; if (cdt->edges[base_edge->idx].flags & D2D_CDT_EDGE_FLAG_VISITED(base_edge->r)) return TRUE; if (!d2d_array_reserve((void **)&geometry->fill.faces, &geometry->fill.faces_size, geometry->fill.face_count + 1, sizeof(*geometry->fill.faces))) { ERR("Failed to grow faces array.\n"); return FALSE; } face = &geometry->fill.faces[geometry->fill.face_count]; /* It may seem tempting to use the center of the face as probe origin, but * multiplying by powers of two works much better for preserving accuracy. */ tmp = *base_edge; cdt->edges[tmp.idx].flags |= D2D_CDT_EDGE_FLAG_VISITED(tmp.r); face->v[0] = d2d_cdt_edge_origin(cdt, &tmp); probe.x = cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].x * 0.25f; probe.y = cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].y * 0.25f; d2d_cdt_edge_next_left(cdt, &tmp, &tmp); cdt->edges[tmp.idx].flags |= D2D_CDT_EDGE_FLAG_VISITED(tmp.r); face->v[1] = d2d_cdt_edge_origin(cdt, &tmp); probe.x += cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].x * 0.25f; probe.y += cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].y * 0.25f; d2d_cdt_edge_next_left(cdt, &tmp, &tmp); cdt->edges[tmp.idx].flags |= D2D_CDT_EDGE_FLAG_VISITED(tmp.r); face->v[2] = d2d_cdt_edge_origin(cdt, &tmp); probe.x += cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].x * 0.50f; probe.y += cdt->vertices[d2d_cdt_edge_origin(cdt, &tmp)].y * 0.50f; if (d2d_cdt_leftof(cdt, face->v[2], base_edge) && d2d_path_geometry_point_inside(geometry, &probe, TRUE)) ++geometry->fill.face_count; return TRUE; } static BOOL d2d_cdt_generate_faces(const struct d2d_cdt *cdt, struct d2d_geometry *geometry) { struct d2d_cdt_edge_ref base_edge; size_t i; for (i = 0; i < cdt->edge_count; ++i) { if (cdt->edges[i].flags & D2D_CDT_EDGE_FLAG_FREED) continue; base_edge.idx = i; base_edge.r = 0; if (!d2d_path_geometry_add_fill_face(geometry, cdt, &base_edge)) goto fail; d2d_cdt_edge_sym(&base_edge, &base_edge); if (!d2d_path_geometry_add_fill_face(geometry, cdt, &base_edge)) goto fail; } return TRUE; fail: heap_free(geometry->fill.faces); geometry->fill.faces = NULL; geometry->fill.faces_size = 0; geometry->fill.face_count = 0; return FALSE; } static BOOL d2d_cdt_fixup(struct d2d_cdt *cdt, const struct d2d_cdt_edge_ref *base_edge) { struct d2d_cdt_edge_ref candidate, next, new_base; unsigned int count = 0; d2d_cdt_edge_next_left(cdt, &next, base_edge); if (next.idx == base_edge->idx) { ERR("Degenerate face.\n"); return FALSE; } candidate = next; while (d2d_cdt_edge_destination(cdt, &next) != d2d_cdt_edge_origin(cdt, base_edge)) { if (d2d_cdt_incircle(cdt, d2d_cdt_edge_origin(cdt, base_edge), d2d_cdt_edge_destination(cdt, base_edge), d2d_cdt_edge_destination(cdt, &candidate), d2d_cdt_edge_destination(cdt, &next))) candidate = next; d2d_cdt_edge_next_left(cdt, &next, &next); ++count; } if (count > 1) { d2d_cdt_edge_next_left(cdt, &next, &candidate); if (d2d_cdt_edge_destination(cdt, &next) == d2d_cdt_edge_origin(cdt, base_edge)) d2d_cdt_edge_next_left(cdt, &next, base_edge); else next = *base_edge; if (!d2d_cdt_connect(cdt, &new_base, &candidate, &next)) return FALSE; if (!d2d_cdt_fixup(cdt, &new_base)) return FALSE; d2d_cdt_edge_sym(&new_base, &new_base); if (!d2d_cdt_fixup(cdt, &new_base)) return FALSE; } return TRUE; } static void d2d_cdt_cut_edges(struct d2d_cdt *cdt, struct d2d_cdt_edge_ref *end_edge, const struct d2d_cdt_edge_ref *base_edge, size_t start_vertex, size_t end_vertex) { struct d2d_cdt_edge_ref next; float ccw; d2d_cdt_edge_next_left(cdt, &next, base_edge); if (d2d_cdt_edge_destination(cdt, &next) == end_vertex) { *end_edge = next; return; } ccw = d2d_cdt_ccw(cdt, d2d_cdt_edge_destination(cdt, &next), end_vertex, start_vertex); if (ccw == 0.0f) { *end_edge = next; return; } if (ccw > 0.0f) d2d_cdt_edge_next_left(cdt, &next, &next); d2d_cdt_edge_sym(&next, &next); d2d_cdt_cut_edges(cdt, end_edge, &next, start_vertex, end_vertex); d2d_cdt_destroy_edge(cdt, &next); } static BOOL d2d_cdt_insert_segment(struct d2d_cdt *cdt, struct d2d_geometry *geometry, const struct d2d_cdt_edge_ref *origin, struct d2d_cdt_edge_ref *edge, size_t end_vertex) { struct d2d_cdt_edge_ref base_edge, current, new_origin, next, target; size_t current_destination, current_origin; for (current = *origin;; current = next) { d2d_cdt_edge_next_origin(cdt, &next, ¤t); current_destination = d2d_cdt_edge_destination(cdt, ¤t); if (current_destination == end_vertex) { d2d_cdt_edge_sym(edge, ¤t); return TRUE; } current_origin = d2d_cdt_edge_origin(cdt, ¤t); if (d2d_cdt_ccw(cdt, end_vertex, current_origin, current_destination) == 0.0f && (cdt->vertices[current_destination].x > cdt->vertices[current_origin].x) == (cdt->vertices[end_vertex].x > cdt->vertices[current_origin].x) && (cdt->vertices[current_destination].y > cdt->vertices[current_origin].y) == (cdt->vertices[end_vertex].y > cdt->vertices[current_origin].y)) { d2d_cdt_edge_sym(&new_origin, ¤t); return d2d_cdt_insert_segment(cdt, geometry, &new_origin, edge, end_vertex); } if (d2d_cdt_rightof(cdt, end_vertex, &next) && d2d_cdt_leftof(cdt, end_vertex, ¤t)) { d2d_cdt_edge_next_left(cdt, &base_edge, ¤t); d2d_cdt_edge_sym(&base_edge, &base_edge); d2d_cdt_cut_edges(cdt, &target, &base_edge, d2d_cdt_edge_origin(cdt, origin), end_vertex); d2d_cdt_destroy_edge(cdt, &base_edge); if (!d2d_cdt_connect(cdt, &base_edge, &target, ¤t)) return FALSE; *edge = base_edge; if (!d2d_cdt_fixup(cdt, &base_edge)) return FALSE; d2d_cdt_edge_sym(&base_edge, &base_edge); if (!d2d_cdt_fixup(cdt, &base_edge)) return FALSE; if (d2d_cdt_edge_origin(cdt, edge) == end_vertex) return TRUE; new_origin = *edge; return d2d_cdt_insert_segment(cdt, geometry, &new_origin, edge, end_vertex); } if (next.idx == origin->idx) { ERR("Triangle not found.\n"); return FALSE; } } } static BOOL d2d_cdt_insert_segments(struct d2d_cdt *cdt, struct d2d_geometry *geometry) { size_t start_vertex, end_vertex, i, j, k; struct d2d_cdt_edge_ref edge, new_edge; const struct d2d_figure *figure; const D2D1_POINT_2F *p; BOOL found; for (i = 0; i < geometry->u.path.figure_count; ++i) { figure = &geometry->u.path.figures[i]; if (figure->flags & D2D_FIGURE_FLAG_HOLLOW) continue; /* Degenerate figure. */ if (figure->vertex_count < 2) continue; p = bsearch(&figure->vertices[figure->vertex_count - 1], cdt->vertices, geometry->fill.vertex_count, sizeof(*p), d2d_cdt_compare_vertices); start_vertex = p - cdt->vertices; for (k = 0, found = FALSE; k < cdt->edge_count; ++k) { if (cdt->edges[k].flags & D2D_CDT_EDGE_FLAG_FREED) continue; edge.idx = k; edge.r = 0; if (d2d_cdt_edge_origin(cdt, &edge) == start_vertex) { found = TRUE; break; } d2d_cdt_edge_sym(&edge, &edge); if (d2d_cdt_edge_origin(cdt, &edge) == start_vertex) { found = TRUE; break; } } if (!found) { ERR("Edge not found.\n"); return FALSE; } for (j = 0; j < figure->vertex_count; start_vertex = end_vertex, ++j) { p = bsearch(&figure->vertices[j], cdt->vertices, geometry->fill.vertex_count, sizeof(*p), d2d_cdt_compare_vertices); end_vertex = p - cdt->vertices; if (start_vertex == end_vertex) continue; if (!d2d_cdt_insert_segment(cdt, geometry, &edge, &new_edge, end_vertex)) return FALSE; edge = new_edge; } } return TRUE; } static BOOL d2d_geometry_intersections_add(struct d2d_geometry_intersections *i, const struct d2d_segment_idx *segment_idx, float t, D2D1_POINT_2F p) { struct d2d_geometry_intersection *intersection; if (!d2d_array_reserve((void **)&i->intersections, &i->intersections_size, i->intersection_count + 1, sizeof(*i->intersections))) { ERR("Failed to grow intersections array.\n"); return FALSE; } intersection = &i->intersections[i->intersection_count++]; intersection->figure_idx = segment_idx->figure_idx; intersection->vertex_idx = segment_idx->vertex_idx; intersection->control_idx = segment_idx->control_idx; intersection->t = t; intersection->p = p; return TRUE; } static int __cdecl d2d_geometry_intersections_compare(const void *a, const void *b) { const struct d2d_geometry_intersection *i0 = a; const struct d2d_geometry_intersection *i1 = b; if (i0->figure_idx != i1->figure_idx) return i0->figure_idx - i1->figure_idx; if (i0->vertex_idx != i1->vertex_idx) return i0->vertex_idx - i1->vertex_idx; if (i0->t != i1->t) return i0->t > i1->t ? 1 : -1; return 0; } static BOOL d2d_geometry_intersect_line_line(struct d2d_geometry *geometry, struct d2d_geometry_intersections *intersections, const struct d2d_segment_idx *idx_p, const struct d2d_segment_idx *idx_q) { D2D1_POINT_2F v_p, v_q, v_qp, intersection; const D2D1_POINT_2F *p[2], *q[2]; const struct d2d_figure *figure; float s, t, det; size_t next; figure = &geometry->u.path.figures[idx_p->figure_idx]; p[0] = &figure->vertices[idx_p->vertex_idx]; next = idx_p->vertex_idx + 1; if (next == figure->vertex_count) next = 0; p[1] = &figure->vertices[next]; figure = &geometry->u.path.figures[idx_q->figure_idx]; q[0] = &figure->vertices[idx_q->vertex_idx]; next = idx_q->vertex_idx + 1; if (next == figure->vertex_count) next = 0; q[1] = &figure->vertices[next]; d2d_point_subtract(&v_p, p[1], p[0]); d2d_point_subtract(&v_q, q[1], q[0]); d2d_point_subtract(&v_qp, p[0], q[0]); det = v_p.x * v_q.y - v_p.y * v_q.x; if (det == 0.0f) return TRUE; s = (v_q.x * v_qp.y - v_q.y * v_qp.x) / det; t = (v_p.x * v_qp.y - v_p.y * v_qp.x) / det; if (s < 0.0f || s > 1.0f || t < 0.0f || t > 1.0f) return TRUE; intersection.x = p[0]->x + v_p.x * s; intersection.y = p[0]->y + v_p.y * s; if (s > 0.0f && s < 1.0f && !d2d_geometry_intersections_add(intersections, idx_p, s, intersection)) return FALSE; if (t > 0.0f && t < 1.0f && !d2d_geometry_intersections_add(intersections, idx_q, t, intersection)) return FALSE; return TRUE; } static BOOL d2d_geometry_add_bezier_line_intersections(struct d2d_geometry *geometry, struct d2d_geometry_intersections *intersections, const struct d2d_segment_idx *idx_p, const D2D1_POINT_2F **p, const struct d2d_segment_idx *idx_q, const D2D1_POINT_2F **q, float s) { D2D1_POINT_2F intersection; float t; d2d_point_calculate_bezier(&intersection, p[0], p[1], p[2], s); if (fabsf(q[1]->x - q[0]->x) > fabsf(q[1]->y - q[0]->y)) t = (intersection.x - q[0]->x) / (q[1]->x - q[0]->x); else t = (intersection.y - q[0]->y) / (q[1]->y - q[0]->y); if (t < 0.0f || t > 1.0f) return TRUE; d2d_point_lerp(&intersection, q[0], q[1], t); if (s > 0.0f && s < 1.0f && !d2d_geometry_intersections_add(intersections, idx_p, s, intersection)) return FALSE; if (t > 0.0f && t < 1.0f && !d2d_geometry_intersections_add(intersections, idx_q, t, intersection)) return FALSE; return TRUE; } static BOOL d2d_geometry_intersect_bezier_line(struct d2d_geometry *geometry, struct d2d_geometry_intersections *intersections, const struct d2d_segment_idx *idx_p, const struct d2d_segment_idx *idx_q) { const D2D1_POINT_2F *p[3], *q[2]; const struct d2d_figure *figure; float y[3], root, theta, d, e; size_t next; figure = &geometry->u.path.figures[idx_p->figure_idx]; p[0] = &figure->vertices[idx_p->vertex_idx]; p[1] = &figure->bezier_controls[idx_p->control_idx]; next = idx_p->vertex_idx + 1; if (next == figure->vertex_count) next = 0; p[2] = &figure->vertices[next]; figure = &geometry->u.path.figures[idx_q->figure_idx]; q[0] = &figure->vertices[idx_q->vertex_idx]; next = idx_q->vertex_idx + 1; if (next == figure->vertex_count) next = 0; q[1] = &figure->vertices[next]; /* Align the line with x-axis. */ theta = -atan2f(q[1]->y - q[0]->y, q[1]->x - q[0]->x); y[0] = (p[0]->x - q[0]->x) * sinf(theta) + (p[0]->y - q[0]->y) * cosf(theta); y[1] = (p[1]->x - q[0]->x) * sinf(theta) + (p[1]->y - q[0]->y) * cosf(theta); y[2] = (p[2]->x - q[0]->x) * sinf(theta) + (p[2]->y - q[0]->y) * cosf(theta); /* Intersect the transformed curve with the x-axis. * * f(t) = (1 - t)²P₀ + 2(1 - t)tP₁ + t²P₂ * = (P₀ - 2P₁ + P₂)t² + 2(P₁ - P₀)t + P₀ * * a = P₀ - 2P₁ + P₂ * b = 2(P₁ - P₀) * c = P₀ * * f(t) = 0 * t = (-b ± √(b² - 4ac)) / 2a * = (-2(P₁ - P₀) ± √((2(P₁ - P₀))² - 4((P₀ - 2P₁ + P₂)P₀))) / 2(P₀ - 2P₁ + P₂) * = (2P₀ - 2P₁ ± √(4P₀² + 4P₁² - 8P₀P₁ - 4P₀² + 8P₀P₁ - 4P₀P₂)) / (2P₀ - 4P₁ + 2P₂) * = (P₀ - P₁ ± √(P₁² - P₀P₂)) / (P₀ - 2P₁ + P₂) */ d = y[0] - 2 * y[1] + y[2]; if (d == 0.0f) { /* P₀ - 2P₁ + P₂ = 0 * f(t) = (P₀ - 2P₁ + P₂)t² + 2(P₁ - P₀)t + P₀ = 0 * t = -P₀ / 2(P₁ - P₀) */ root = -y[0] / (2.0f * (y[1] - y[0])); if (root < 0.0f || root > 1.0f) return TRUE; return d2d_geometry_add_bezier_line_intersections(geometry, intersections, idx_p, p, idx_q, q, root); } e = y[1] * y[1] - y[0] * y[2]; if (e < 0.0f) return TRUE; root = (y[0] - y[1] + sqrtf(e)) / d; if (root >= 0.0f && root <= 1.0f && !d2d_geometry_add_bezier_line_intersections(geometry, intersections, idx_p, p, idx_q, q, root)) return FALSE; root = (y[0] - y[1] - sqrtf(e)) / d; if (root >= 0.0f && root <= 1.0f && !d2d_geometry_add_bezier_line_intersections(geometry, intersections, idx_p, p, idx_q, q, root)) return FALSE; return TRUE; } static BOOL d2d_geometry_intersect_bezier_bezier(struct d2d_geometry *geometry, struct d2d_geometry_intersections *intersections, const struct d2d_segment_idx *idx_p, float start_p, float end_p, const struct d2d_segment_idx *idx_q, float start_q, float end_q) { const D2D1_POINT_2F *p[3], *q[3]; const struct d2d_figure *figure; D2D_RECT_F p_bounds, q_bounds; D2D1_POINT_2F intersection; float centre_p, centre_q; size_t next; figure = &geometry->u.path.figures[idx_p->figure_idx]; p[0] = &figure->vertices[idx_p->vertex_idx]; p[1] = &figure->bezier_controls[idx_p->control_idx]; next = idx_p->vertex_idx + 1; if (next == figure->vertex_count) next = 0; p[2] = &figure->vertices[next]; figure = &geometry->u.path.figures[idx_q->figure_idx]; q[0] = &figure->vertices[idx_q->vertex_idx]; q[1] = &figure->bezier_controls[idx_q->control_idx]; next = idx_q->vertex_idx + 1; if (next == figure->vertex_count) next = 0; q[2] = &figure->vertices[next]; d2d_rect_get_bezier_segment_bounds(&p_bounds, p[0], p[1], p[2], start_p, end_p); d2d_rect_get_bezier_segment_bounds(&q_bounds, q[0], q[1], q[2], start_q, end_q); if (!d2d_rect_check_overlap(&p_bounds, &q_bounds)) return TRUE; centre_p = (start_p + end_p) / 2.0f; centre_q = (start_q + end_q) / 2.0f; if (end_p - start_p < 1e-3f) { d2d_point_calculate_bezier(&intersection, p[0], p[1], p[2], centre_p); if (start_p > 0.0f && end_p < 1.0f && !d2d_geometry_intersections_add(intersections, idx_p, centre_p, intersection)) return FALSE; if (start_q > 0.0f && end_q < 1.0f && !d2d_geometry_intersections_add(intersections, idx_q, centre_q, intersection)) return FALSE; return TRUE; } if (!d2d_geometry_intersect_bezier_bezier(geometry, intersections, idx_p, start_p, centre_p, idx_q, start_q, centre_q)) return FALSE; if (!d2d_geometry_intersect_bezier_bezier(geometry, intersections, idx_p, start_p, centre_p, idx_q, centre_q, end_q)) return FALSE; if (!d2d_geometry_intersect_bezier_bezier(geometry, intersections, idx_p, centre_p, end_p, idx_q, start_q, centre_q)) return FALSE; if (!d2d_geometry_intersect_bezier_bezier(geometry, intersections, idx_p, centre_p, end_p, idx_q, centre_q, end_q)) return FALSE; return TRUE; } static BOOL d2d_geometry_apply_intersections(struct d2d_geometry *geometry, struct d2d_geometry_intersections *intersections) { size_t vertex_offset, control_offset, next, i; struct d2d_geometry_intersection *inter; enum d2d_vertex_type vertex_type; const D2D1_POINT_2F *p[3]; struct d2d_figure *figure; D2D1_POINT_2F q[2]; float t, t_prev; for (i = 0; i < intersections->intersection_count; ++i) { inter = &intersections->intersections[i]; if (!i || inter->figure_idx != intersections->intersections[i - 1].figure_idx) vertex_offset = control_offset = 0; figure = &geometry->u.path.figures[inter->figure_idx]; vertex_type = figure->vertex_types[inter->vertex_idx + vertex_offset]; if (!d2d_vertex_type_is_bezier(vertex_type)) { if (!d2d_figure_insert_vertex(&geometry->u.path.figures[inter->figure_idx], inter->vertex_idx + vertex_offset + 1, inter->p)) return FALSE; ++vertex_offset; continue; } t = inter->t; if (i && inter->figure_idx == intersections->intersections[i - 1].figure_idx && inter->vertex_idx == intersections->intersections[i - 1].vertex_idx) { t_prev = intersections->intersections[i - 1].t; if (t - t_prev < 1e-3f) { inter->t = intersections->intersections[i - 1].t; continue; } t = (t - t_prev) / (1.0f - t_prev); } p[0] = &figure->vertices[inter->vertex_idx + vertex_offset]; p[1] = &figure->bezier_controls[inter->control_idx + control_offset]; next = inter->vertex_idx + vertex_offset + 1; if (next == figure->vertex_count) next = 0; p[2] = &figure->vertices[next]; d2d_point_lerp(&q[0], p[0], p[1], t); d2d_point_lerp(&q[1], p[1], p[2], t); figure->bezier_controls[inter->control_idx + control_offset] = q[0]; if (!(d2d_figure_insert_bezier_controls(figure, inter->control_idx + control_offset + 1, 1, &q[1]))) return FALSE; ++control_offset; if (!(d2d_figure_insert_vertex(figure, inter->vertex_idx + vertex_offset + 1, inter->p))) return FALSE; figure->vertex_types[inter->vertex_idx + vertex_offset + 1] = D2D_VERTEX_TYPE_SPLIT_BEZIER; ++vertex_offset; } return TRUE; } /* Intersect the geometry's segments with themselves. This uses the * straightforward approach of testing everything against everything, but * there certainly exist more scalable algorithms for this. */ static BOOL d2d_geometry_intersect_self(struct d2d_geometry *geometry) { struct d2d_geometry_intersections intersections = {0}; const struct d2d_figure *figure_p, *figure_q; struct d2d_segment_idx idx_p, idx_q; enum d2d_vertex_type type_p, type_q; BOOL ret = FALSE; size_t max_q; if (!geometry->u.path.figure_count) return TRUE; for (idx_p.figure_idx = 0; idx_p.figure_idx < geometry->u.path.figure_count; ++idx_p.figure_idx) { figure_p = &geometry->u.path.figures[idx_p.figure_idx]; idx_p.control_idx = 0; for (idx_p.vertex_idx = 0; idx_p.vertex_idx < figure_p->vertex_count; ++idx_p.vertex_idx) { type_p = figure_p->vertex_types[idx_p.vertex_idx]; for (idx_q.figure_idx = 0; idx_q.figure_idx <= idx_p.figure_idx; ++idx_q.figure_idx) { figure_q = &geometry->u.path.figures[idx_q.figure_idx]; if (idx_q.figure_idx != idx_p.figure_idx) { if (!d2d_rect_check_overlap(&figure_p->bounds, &figure_q->bounds)) continue; max_q = figure_q->vertex_count; } else { max_q = idx_p.vertex_idx; } idx_q.control_idx = 0; for (idx_q.vertex_idx = 0; idx_q.vertex_idx < max_q; ++idx_q.vertex_idx) { type_q = figure_q->vertex_types[idx_q.vertex_idx]; if (d2d_vertex_type_is_bezier(type_q)) { if (d2d_vertex_type_is_bezier(type_p)) { if (!d2d_geometry_intersect_bezier_bezier(geometry, &intersections, &idx_p, 0.0f, 1.0f, &idx_q, 0.0f, 1.0f)) goto done; } else { if (!d2d_geometry_intersect_bezier_line(geometry, &intersections, &idx_q, &idx_p)) goto done; } ++idx_q.control_idx; } else { if (d2d_vertex_type_is_bezier(type_p)) { if (!d2d_geometry_intersect_bezier_line(geometry, &intersections, &idx_p, &idx_q)) goto done; } else { if (!d2d_geometry_intersect_line_line(geometry, &intersections, &idx_p, &idx_q)) goto done; } } } } if (d2d_vertex_type_is_bezier(type_p)) ++idx_p.control_idx; } } qsort(intersections.intersections, intersections.intersection_count, sizeof(*intersections.intersections), d2d_geometry_intersections_compare); ret = d2d_geometry_apply_intersections(geometry, &intersections); done: heap_free(intersections.intersections); return ret; } static HRESULT d2d_path_geometry_triangulate(struct d2d_geometry *geometry) { struct d2d_cdt_edge_ref left_edge, right_edge; size_t vertex_count, i, j; struct d2d_cdt cdt = {0}; D2D1_POINT_2F *vertices; for (i = 0, vertex_count = 0; i < geometry->u.path.figure_count; ++i) { if (geometry->u.path.figures[i].flags & D2D_FIGURE_FLAG_HOLLOW) continue; vertex_count += geometry->u.path.figures[i].vertex_count; } if (vertex_count < 3) { WARN("Geometry has %lu vertices.\n", (long)vertex_count); return S_OK; } if (!(vertices = heap_calloc(vertex_count, sizeof(*vertices)))) return E_OUTOFMEMORY; for (i = 0, j = 0; i < geometry->u.path.figure_count; ++i) { if (geometry->u.path.figures[i].flags & D2D_FIGURE_FLAG_HOLLOW) continue; memcpy(&vertices[j], geometry->u.path.figures[i].vertices, geometry->u.path.figures[i].vertex_count * sizeof(*vertices)); j += geometry->u.path.figures[i].vertex_count; } /* Sort vertices, eliminate duplicates. */ qsort(vertices, vertex_count, sizeof(*vertices), d2d_cdt_compare_vertices); for (i = 1; i < vertex_count; ++i) { if (!memcmp(&vertices[i - 1], &vertices[i], sizeof(*vertices))) { --vertex_count; memmove(&vertices[i], &vertices[i + 1], (vertex_count - i) * sizeof(*vertices)); --i; } } if (vertex_count < 3) { WARN("Geometry has %lu vertices after eliminating duplicates.\n", (long)vertex_count); heap_free(vertices); return S_OK; } geometry->fill.vertices = vertices; geometry->fill.vertex_count = vertex_count; cdt.free_edge = ~0u; cdt.vertices = vertices; if (!d2d_cdt_triangulate(&cdt, 0, vertex_count, &left_edge, &right_edge)) goto fail; if (!d2d_cdt_insert_segments(&cdt, geometry)) goto fail; if (!d2d_cdt_generate_faces(&cdt, geometry)) goto fail; heap_free(cdt.edges); return S_OK; fail: geometry->fill.vertices = NULL; geometry->fill.vertex_count = 0; heap_free(vertices); heap_free(cdt.edges); return E_FAIL; } static BOOL d2d_path_geometry_add_figure(struct d2d_geometry *geometry) { struct d2d_figure *figure; if (!d2d_array_reserve((void **)&geometry->u.path.figures, &geometry->u.path.figures_size, geometry->u.path.figure_count + 1, sizeof(*geometry->u.path.figures))) { ERR("Failed to grow figures array.\n"); return FALSE; } figure = &geometry->u.path.figures[geometry->u.path.figure_count]; memset(figure, 0, sizeof(*figure)); figure->bounds.left = FLT_MAX; figure->bounds.top = FLT_MAX; figure->bounds.right = -FLT_MAX; figure->bounds.bottom = -FLT_MAX; ++geometry->u.path.figure_count; return TRUE; } static BOOL d2d_geometry_outline_add_join(struct d2d_geometry *geometry, const D2D1_POINT_2F *prev, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *next) { static const D2D1_POINT_2F origin = {0.0f, 0.0f}; struct d2d_outline_vertex *v; struct d2d_face *f; size_t base_idx; float ccw; if (!d2d_array_reserve((void **)&geometry->outline.vertices, &geometry->outline.vertices_size, geometry->outline.vertex_count + 4, sizeof(*geometry->outline.vertices))) { ERR("Failed to grow outline vertices array.\n"); return FALSE; } base_idx = geometry->outline.vertex_count; v = &geometry->outline.vertices[base_idx]; if (!d2d_array_reserve((void **)&geometry->outline.faces, &geometry->outline.faces_size, geometry->outline.face_count + 2, sizeof(*geometry->outline.faces))) { ERR("Failed to grow outline faces array.\n"); return FALSE; } f = &geometry->outline.faces[geometry->outline.face_count]; ccw = d2d_point_ccw(&origin, prev, next); if (ccw == 0.0f) { d2d_outline_vertex_set(&v[0], p0->x, p0->y, -prev->x, -prev->y, -prev->x, -prev->y); d2d_outline_vertex_set(&v[1], p0->x, p0->y, prev->x, prev->y, prev->x, prev->y); d2d_outline_vertex_set(&v[2], p0->x + 25.0f * -prev->x, p0->y + 25.0f * -prev->y, prev->x, prev->y, prev->x, prev->y); d2d_outline_vertex_set(&v[3], p0->x + 25.0f * -prev->x, p0->y + 25.0f * -prev->y, -prev->x, -prev->y, -prev->x, -prev->y); } else if (ccw < 0.0f) { d2d_outline_vertex_set(&v[0], p0->x, p0->y, next->x, next->y, -prev->x, -prev->y); d2d_outline_vertex_set(&v[1], p0->x, p0->y, -next->x, -next->y, -next->x, -next->y); d2d_outline_vertex_set(&v[2], p0->x, p0->y, -next->x, -next->y, prev->x, prev->y); d2d_outline_vertex_set(&v[3], p0->x, p0->y, prev->x, prev->y, prev->x, prev->y); } else { d2d_outline_vertex_set(&v[0], p0->x, p0->y, prev->x, prev->y, -next->x, -next->y); d2d_outline_vertex_set(&v[1], p0->x, p0->y, -prev->x, -prev->y, -prev->x, -prev->y); d2d_outline_vertex_set(&v[2], p0->x, p0->y, -prev->x, -prev->y, next->x, next->y); d2d_outline_vertex_set(&v[3], p0->x, p0->y, next->x, next->y, next->x, next->y); } geometry->outline.vertex_count += 4; d2d_face_set(&f[0], base_idx + 1, base_idx + 0, base_idx + 2); d2d_face_set(&f[1], base_idx + 2, base_idx + 0, base_idx + 3); geometry->outline.face_count += 2; return TRUE; } static BOOL d2d_geometry_outline_add_line_segment(struct d2d_geometry *geometry, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *next) { struct d2d_outline_vertex *v; D2D1_POINT_2F q_next; struct d2d_face *f; size_t base_idx; if (!d2d_array_reserve((void **)&geometry->outline.vertices, &geometry->outline.vertices_size, geometry->outline.vertex_count + 4, sizeof(*geometry->outline.vertices))) { ERR("Failed to grow outline vertices array.\n"); return FALSE; } base_idx = geometry->outline.vertex_count; v = &geometry->outline.vertices[base_idx]; if (!d2d_array_reserve((void **)&geometry->outline.faces, &geometry->outline.faces_size, geometry->outline.face_count + 2, sizeof(*geometry->outline.faces))) { ERR("Failed to grow outline faces array.\n"); return FALSE; } f = &geometry->outline.faces[geometry->outline.face_count]; d2d_point_subtract(&q_next, next, p0); d2d_point_normalise(&q_next); d2d_outline_vertex_set(&v[0], p0->x, p0->y, q_next.x, q_next.y, q_next.x, q_next.y); d2d_outline_vertex_set(&v[1], p0->x, p0->y, -q_next.x, -q_next.y, -q_next.x, -q_next.y); d2d_outline_vertex_set(&v[2], next->x, next->y, q_next.x, q_next.y, q_next.x, q_next.y); d2d_outline_vertex_set(&v[3], next->x, next->y, -q_next.x, -q_next.y, -q_next.x, -q_next.y); geometry->outline.vertex_count += 4; d2d_face_set(&f[0], base_idx + 0, base_idx + 1, base_idx + 2); d2d_face_set(&f[1], base_idx + 2, base_idx + 1, base_idx + 3); geometry->outline.face_count += 2; return TRUE; } static BOOL d2d_geometry_outline_add_bezier_segment(struct d2d_geometry *geometry, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2) { struct d2d_curve_outline_vertex *b; D2D1_POINT_2F r0, r1, r2; D2D1_POINT_2F q0, q1, q2; struct d2d_face *f; size_t base_idx; if (!d2d_array_reserve((void **)&geometry->outline.beziers, &geometry->outline.beziers_size, geometry->outline.bezier_count + 7, sizeof(*geometry->outline.beziers))) { ERR("Failed to grow outline beziers array.\n"); return FALSE; } base_idx = geometry->outline.bezier_count; b = &geometry->outline.beziers[base_idx]; if (!d2d_array_reserve((void **)&geometry->outline.bezier_faces, &geometry->outline.bezier_faces_size, geometry->outline.bezier_face_count + 5, sizeof(*geometry->outline.bezier_faces))) { ERR("Failed to grow outline faces array.\n"); return FALSE; } f = &geometry->outline.bezier_faces[geometry->outline.bezier_face_count]; d2d_point_lerp(&q0, p0, p1, 0.5f); d2d_point_lerp(&q1, p1, p2, 0.5f); d2d_point_lerp(&q2, &q0, &q1, 0.5f); d2d_point_subtract(&r0, &q0, p0); d2d_point_subtract(&r1, &q1, &q0); d2d_point_subtract(&r2, p2, &q1); d2d_point_normalise(&r0); d2d_point_normalise(&r1); d2d_point_normalise(&r2); if (d2d_point_ccw(p0, p1, p2) > 0.0f) { d2d_point_scale(&r0, -1.0f); d2d_point_scale(&r1, -1.0f); d2d_point_scale(&r2, -1.0f); } d2d_curve_outline_vertex_set(&b[0], p0, p0, p1, p2, r0.x, r0.y, r0.x, r0.y); d2d_curve_outline_vertex_set(&b[1], p0, p0, p1, p2, -r0.x, -r0.y, -r0.x, -r0.y); d2d_curve_outline_vertex_set(&b[2], &q0, p0, p1, p2, r0.x, r0.y, r1.x, r1.y); d2d_curve_outline_vertex_set(&b[3], &q2, p0, p1, p2, -r1.x, -r1.y, -r1.x, -r1.y); d2d_curve_outline_vertex_set(&b[4], &q1, p0, p1, p2, r1.x, r1.y, r2.x, r2.y); d2d_curve_outline_vertex_set(&b[5], p2, p0, p1, p2, -r2.x, -r2.y, -r2.x, -r2.y); d2d_curve_outline_vertex_set(&b[6], p2, p0, p1, p2, r2.x, r2.y, r2.x, r2.y); geometry->outline.bezier_count += 7; d2d_face_set(&f[0], base_idx + 0, base_idx + 1, base_idx + 2); d2d_face_set(&f[1], base_idx + 2, base_idx + 1, base_idx + 3); d2d_face_set(&f[2], base_idx + 3, base_idx + 4, base_idx + 2); d2d_face_set(&f[3], base_idx + 5, base_idx + 4, base_idx + 3); d2d_face_set(&f[4], base_idx + 5, base_idx + 6, base_idx + 4); geometry->outline.bezier_face_count += 5; return TRUE; } static BOOL d2d_geometry_outline_add_arc_quadrant(struct d2d_geometry *geometry, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2) { struct d2d_curve_outline_vertex *a; D2D1_POINT_2F r0, r1; struct d2d_face *f; size_t base_idx; if (!d2d_array_reserve((void **)&geometry->outline.arcs, &geometry->outline.arcs_size, geometry->outline.arc_count + 5, sizeof(*geometry->outline.arcs))) { ERR("Failed to grow outline arcs array.\n"); return FALSE; } base_idx = geometry->outline.arc_count; a = &geometry->outline.arcs[base_idx]; if (!d2d_array_reserve((void **)&geometry->outline.arc_faces, &geometry->outline.arc_faces_size, geometry->outline.arc_face_count + 3, sizeof(*geometry->outline.arc_faces))) { ERR("Failed to grow outline faces array.\n"); return FALSE; } f = &geometry->outline.arc_faces[geometry->outline.arc_face_count]; d2d_point_subtract(&r0, p1, p0); d2d_point_subtract(&r1, p2, p1); d2d_point_normalise(&r0); d2d_point_normalise(&r1); if (d2d_point_ccw(p0, p1, p2) > 0.0f) { d2d_point_scale(&r0, -1.0f); d2d_point_scale(&r1, -1.0f); } d2d_curve_outline_vertex_set(&a[0], p0, p0, p1, p2, r0.x, r0.y, r0.x, r0.y); d2d_curve_outline_vertex_set(&a[1], p0, p0, p1, p2, -r0.x, -r0.y, -r0.x, -r0.y); d2d_curve_outline_vertex_set(&a[2], p1, p0, p1, p2, r0.x, r0.y, r1.x, r1.y); d2d_curve_outline_vertex_set(&a[3], p2, p0, p1, p2, -r1.x, -r1.y, -r1.x, -r1.y); d2d_curve_outline_vertex_set(&a[4], p2, p0, p1, p2, r1.x, r1.y, r1.x, r1.y); geometry->outline.arc_count += 5; d2d_face_set(&f[0], base_idx + 0, base_idx + 1, base_idx + 2); d2d_face_set(&f[1], base_idx + 2, base_idx + 1, base_idx + 3); d2d_face_set(&f[2], base_idx + 2, base_idx + 4, base_idx + 3); geometry->outline.arc_face_count += 3; return TRUE; } static BOOL d2d_geometry_add_figure_outline(struct d2d_geometry *geometry, struct d2d_figure *figure, D2D1_FIGURE_END figure_end) { const D2D1_POINT_2F *prev, *p0, *next; enum d2d_vertex_type prev_type, type; size_t bezier_idx, i; for (i = 0, bezier_idx = 0; i < figure->vertex_count; ++i) { type = figure->vertex_types[i]; if (type == D2D_VERTEX_TYPE_NONE) continue; p0 = &figure->vertices[i]; if (!i) { prev_type = figure->vertex_types[figure->vertex_count - 1]; if (d2d_vertex_type_is_bezier(prev_type)) prev = &figure->bezier_controls[figure->bezier_control_count - 1]; else prev = &figure->vertices[figure->vertex_count - 1]; } else { prev_type = figure->vertex_types[i - 1]; if (d2d_vertex_type_is_bezier(prev_type)) prev = &figure->bezier_controls[bezier_idx - 1]; else prev = &figure->vertices[i - 1]; } if (d2d_vertex_type_is_bezier(type)) next = &figure->bezier_controls[bezier_idx++]; else if (i == figure->vertex_count - 1) next = &figure->vertices[0]; else next = &figure->vertices[i + 1]; if (figure_end == D2D1_FIGURE_END_CLOSED || (i && i < figure->vertex_count - 1)) { D2D1_POINT_2F q_next, q_prev; d2d_point_subtract(&q_prev, prev, p0); d2d_point_subtract(&q_next, next, p0); d2d_point_normalise(&q_prev); d2d_point_normalise(&q_next); if (!d2d_geometry_outline_add_join(geometry, &q_prev, p0, &q_next)) { ERR("Failed to add join.\n"); return FALSE; } } if (type == D2D_VERTEX_TYPE_LINE && (figure_end == D2D1_FIGURE_END_CLOSED || i < figure->vertex_count - 1) && !d2d_geometry_outline_add_line_segment(geometry, p0, next)) { ERR("Failed to add line segment.\n"); return FALSE; } else if (d2d_vertex_type_is_bezier(type)) { const D2D1_POINT_2F *p2; if (i == figure->vertex_count - 1) p2 = &figure->vertices[0]; else p2 = &figure->vertices[i + 1]; if (!d2d_geometry_outline_add_bezier_segment(geometry, p0, next, p2)) { ERR("Failed to add bezier segment.\n"); return FALSE; } } } return TRUE; } static BOOL d2d_geometry_fill_add_arc_triangle(struct d2d_geometry *geometry, const D2D1_POINT_2F *p0, const D2D1_POINT_2F *p1, const D2D1_POINT_2F *p2) { struct d2d_curve_vertex *a; if (!d2d_array_reserve((void **)&geometry->fill.arc_vertices, &geometry->fill.arc_vertices_size, geometry->fill.arc_vertex_count + 3, sizeof(*geometry->fill.arc_vertices))) return FALSE; a = &geometry->fill.arc_vertices[geometry->fill.arc_vertex_count]; d2d_curve_vertex_set(&a[0], p0, 0.0f, 1.0f, -1.0f); d2d_curve_vertex_set(&a[1], p1, 1.0f, 1.0f, -1.0f); d2d_curve_vertex_set(&a[2], p2, 1.0f, 0.0f, -1.0f); geometry->fill.arc_vertex_count += 3; return TRUE; } static void d2d_geometry_cleanup(struct d2d_geometry *geometry) { heap_free(geometry->outline.arc_faces); heap_free(geometry->outline.arcs); heap_free(geometry->outline.bezier_faces); heap_free(geometry->outline.beziers); heap_free(geometry->outline.faces); heap_free(geometry->outline.vertices); heap_free(geometry->fill.arc_vertices); heap_free(geometry->fill.bezier_vertices); heap_free(geometry->fill.faces); heap_free(geometry->fill.vertices); ID2D1Factory_Release(geometry->factory); } static void d2d_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory, const D2D1_MATRIX_3X2_F *transform, const struct ID2D1GeometryVtbl *vtbl) { geometry->ID2D1Geometry_iface.lpVtbl = vtbl; geometry->refcount = 1; ID2D1Factory_AddRef(geometry->factory = factory); geometry->transform = *transform; } static inline struct d2d_geometry *impl_from_ID2D1GeometrySink(ID2D1GeometrySink *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, u.path.ID2D1GeometrySink_iface); } static HRESULT STDMETHODCALLTYPE d2d_geometry_sink_QueryInterface(ID2D1GeometrySink *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1GeometrySink) || IsEqualGUID(iid, &IID_ID2D1SimplifiedGeometrySink) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1GeometrySink_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_geometry_sink_AddRef(ID2D1GeometrySink *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); TRACE("iface %p.\n", iface); return ID2D1Geometry_AddRef(&geometry->ID2D1Geometry_iface); } static ULONG STDMETHODCALLTYPE d2d_geometry_sink_Release(ID2D1GeometrySink *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); TRACE("iface %p.\n", iface); return ID2D1Geometry_Release(&geometry->ID2D1Geometry_iface); } static void STDMETHODCALLTYPE d2d_geometry_sink_SetFillMode(ID2D1GeometrySink *iface, D2D1_FILL_MODE mode) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); TRACE("iface %p, mode %#x.\n", iface, mode); if (geometry->u.path.state == D2D_GEOMETRY_STATE_CLOSED) return; geometry->u.path.fill_mode = mode; } static void STDMETHODCALLTYPE d2d_geometry_sink_SetSegmentFlags(ID2D1GeometrySink *iface, D2D1_PATH_SEGMENT flags) { TRACE("iface %p, flags %#x.\n", iface, flags); if (flags != D2D1_PATH_SEGMENT_NONE) FIXME("Ignoring flags %#x.\n", flags); } static void STDMETHODCALLTYPE d2d_geometry_sink_BeginFigure(ID2D1GeometrySink *iface, D2D1_POINT_2F start_point, D2D1_FIGURE_BEGIN figure_begin) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); struct d2d_figure *figure; TRACE("iface %p, start_point %s, figure_begin %#x.\n", iface, debug_d2d_point_2f(&start_point), figure_begin); if (geometry->u.path.state != D2D_GEOMETRY_STATE_OPEN) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } if (!d2d_path_geometry_add_figure(geometry)) { ERR("Failed to add figure.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } figure = &geometry->u.path.figures[geometry->u.path.figure_count - 1]; if (figure_begin == D2D1_FIGURE_BEGIN_HOLLOW) figure->flags |= D2D_FIGURE_FLAG_HOLLOW; if (!d2d_figure_add_vertex(figure, start_point)) { ERR("Failed to add vertex.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } geometry->u.path.state = D2D_GEOMETRY_STATE_FIGURE; } static void STDMETHODCALLTYPE d2d_geometry_sink_AddLines(ID2D1GeometrySink *iface, const D2D1_POINT_2F *points, UINT32 count) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); struct d2d_figure *figure = &geometry->u.path.figures[geometry->u.path.figure_count - 1]; unsigned int i; TRACE("iface %p, points %p, count %u.\n", iface, points, count); if (geometry->u.path.state != D2D_GEOMETRY_STATE_FIGURE) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } for (i = 0; i < count; ++i) { figure->vertex_types[figure->vertex_count - 1] = D2D_VERTEX_TYPE_LINE; if (!d2d_figure_add_vertex(figure, points[i])) { ERR("Failed to add vertex.\n"); return; } } geometry->u.path.segment_count += count; } static void STDMETHODCALLTYPE d2d_geometry_sink_AddBeziers(ID2D1GeometrySink *iface, const D2D1_BEZIER_SEGMENT *beziers, UINT32 count) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); struct d2d_figure *figure = &geometry->u.path.figures[geometry->u.path.figure_count - 1]; D2D1_POINT_2F p; unsigned int i; TRACE("iface %p, beziers %p, count %u.\n", iface, beziers, count); if (geometry->u.path.state != D2D_GEOMETRY_STATE_FIGURE) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } for (i = 0; i < count; ++i) { D2D1_RECT_F bezier_bounds; if (!d2d_figure_add_original_bezier_controls(figure, 1, &beziers[i].point1) || !d2d_figure_add_original_bezier_controls(figure, 1, &beziers[i].point2)) { ERR("Failed to add cubic Bézier controls.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } /* FIXME: This tries to approximate a cubic Bézier with a quadratic one. */ p.x = (beziers[i].point1.x + beziers[i].point2.x) * 0.75f; p.y = (beziers[i].point1.y + beziers[i].point2.y) * 0.75f; p.x -= (figure->vertices[figure->vertex_count - 1].x + beziers[i].point3.x) * 0.25f; p.y -= (figure->vertices[figure->vertex_count - 1].y + beziers[i].point3.y) * 0.25f; figure->vertex_types[figure->vertex_count - 1] = D2D_VERTEX_TYPE_BEZIER; d2d_rect_get_bezier_bounds(&bezier_bounds, &figure->vertices[figure->vertex_count - 1], &p, &beziers[i].point3); if (!d2d_figure_add_bezier_controls(figure, 1, &p)) { ERR("Failed to add bezier control.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } if (!d2d_figure_add_vertex(figure, beziers[i].point3)) { ERR("Failed to add bezier vertex.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } d2d_rect_union(&figure->bounds, &bezier_bounds); } geometry->u.path.segment_count += count; } static void STDMETHODCALLTYPE d2d_geometry_sink_EndFigure(ID2D1GeometrySink *iface, D2D1_FIGURE_END figure_end) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); struct d2d_figure *figure; TRACE("iface %p, figure_end %#x.\n", iface, figure_end); if (geometry->u.path.state != D2D_GEOMETRY_STATE_FIGURE) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } figure = &geometry->u.path.figures[geometry->u.path.figure_count - 1]; figure->vertex_types[figure->vertex_count - 1] = D2D_VERTEX_TYPE_LINE; if (figure_end == D2D1_FIGURE_END_CLOSED) { ++geometry->u.path.segment_count; figure->flags |= D2D_FIGURE_FLAG_CLOSED; if (!memcmp(&figure->vertices[0], &figure->vertices[figure->vertex_count - 1], sizeof(*figure->vertices))) --figure->vertex_count; } if (!d2d_geometry_add_figure_outline(geometry, figure, figure_end)) { ERR("Failed to add figure outline.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } geometry->u.path.state = D2D_GEOMETRY_STATE_OPEN; } static void d2d_path_geometry_free_figures(struct d2d_geometry *geometry) { size_t i; if (!geometry->u.path.figures) return; for (i = 0; i < geometry->u.path.figure_count; ++i) { heap_free(geometry->u.path.figures[i].original_bezier_controls); heap_free(geometry->u.path.figures[i].bezier_controls); heap_free(geometry->u.path.figures[i].vertices); } heap_free(geometry->u.path.figures); geometry->u.path.figures = NULL; geometry->u.path.figures_size = 0; } static BOOL d2d_geometry_get_bezier_segment_idx(struct d2d_geometry *geometry, struct d2d_segment_idx *idx, BOOL next) { if (next) { ++idx->vertex_idx; ++idx->control_idx; } for (; idx->figure_idx < geometry->u.path.figure_count; ++idx->figure_idx, idx->vertex_idx = idx->control_idx = 0) { struct d2d_figure *figure = &geometry->u.path.figures[idx->figure_idx]; if (!figure->bezier_control_count || figure->flags & D2D_FIGURE_FLAG_HOLLOW) continue; for (; idx->vertex_idx < figure->vertex_count; ++idx->vertex_idx) { if (d2d_vertex_type_is_bezier(figure->vertex_types[idx->vertex_idx])) return TRUE; } } return FALSE; } static BOOL d2d_geometry_get_first_bezier_segment_idx(struct d2d_geometry *geometry, struct d2d_segment_idx *idx) { memset(idx, 0, sizeof(*idx)); return d2d_geometry_get_bezier_segment_idx(geometry, idx, FALSE); } static BOOL d2d_geometry_get_next_bezier_segment_idx(struct d2d_geometry *geometry, struct d2d_segment_idx *idx) { return d2d_geometry_get_bezier_segment_idx(geometry, idx, TRUE); } static BOOL d2d_geometry_check_bezier_overlap(struct d2d_geometry *geometry, const struct d2d_segment_idx *idx_p, const struct d2d_segment_idx *idx_q) { const D2D1_POINT_2F *a[3], *b[3], *p[2], *q; const struct d2d_figure *figure; D2D1_POINT_2F v_q[3], v_p, v_qp; unsigned int i, j, score; float det, t; figure = &geometry->u.path.figures[idx_p->figure_idx]; a[0] = &figure->vertices[idx_p->vertex_idx]; a[1] = &figure->bezier_controls[idx_p->control_idx]; if (idx_p->vertex_idx == figure->vertex_count - 1) a[2] = &figure->vertices[0]; else a[2] = &figure->vertices[idx_p->vertex_idx + 1]; figure = &geometry->u.path.figures[idx_q->figure_idx]; b[0] = &figure->vertices[idx_q->vertex_idx]; b[1] = &figure->bezier_controls[idx_q->control_idx]; if (idx_q->vertex_idx == figure->vertex_count - 1) b[2] = &figure->vertices[0]; else b[2] = &figure->vertices[idx_q->vertex_idx + 1]; if (d2d_point_ccw(a[0], a[1], a[2]) == 0.0f || d2d_point_ccw(b[0], b[1], b[2]) == 0.0f) return FALSE; d2d_point_subtract(&v_q[0], b[1], b[0]); d2d_point_subtract(&v_q[1], b[2], b[0]); d2d_point_subtract(&v_q[2], b[1], b[2]); /* Check for intersections between the edges. Strictly speaking we'd only * need to check 8 of the 9 possible intersections, since if there's any * intersection there has to be a second intersection as well. */ for (i = 0; i < 3; ++i) { d2d_point_subtract(&v_p, a[(i & 1) + 1], a[i & 2]); for (j = 0; j < 3; ++j) { det = v_p.x * v_q[j].y - v_p.y * v_q[j].x; if (det == 0.0f) continue; d2d_point_subtract(&v_qp, a[i & 2], b[j & 2]); t = (v_q[j].x * v_qp.y - v_q[j].y * v_qp.x) / det; if (t <= 0.0f || t >= 1.0f) continue; t = (v_p.x * v_qp.y - v_p.y * v_qp.x) / det; if (t <= 0.0f || t >= 1.0f) continue; return TRUE; } } /* Check if one triangle is contained within the other. */ for (j = 0, score = 0, q = a[1], p[0] = b[2]; j < 3; ++j) { p[1] = b[j]; d2d_point_subtract(&v_p, p[1], p[0]); d2d_point_subtract(&v_qp, q, p[0]); if ((q->y < p[0]->y) != (q->y < p[1]->y) && v_qp.x < v_p.x * (v_qp.y / v_p.y)) ++score; p[0] = p[1]; } if (score & 1) return TRUE; for (j = 0, score = 0, q = b[1], p[0] = a[2]; j < 3; ++j) { p[1] = a[j]; d2d_point_subtract(&v_p, p[1], p[0]); d2d_point_subtract(&v_qp, q, p[0]); if ((q->y < p[0]->y) != (q->y < p[1]->y) && v_qp.x < v_p.x * (v_qp.y / v_p.y)) ++score; p[0] = p[1]; } return score & 1; } static float d2d_geometry_bezier_ccw(struct d2d_geometry *geometry, const struct d2d_segment_idx *idx) { const struct d2d_figure *figure = &geometry->u.path.figures[idx->figure_idx]; size_t next = idx->vertex_idx + 1; if (next == figure->vertex_count) next = 0; return d2d_point_ccw(&figure->vertices[idx->vertex_idx], &figure->bezier_controls[idx->control_idx], &figure->vertices[next]); } static BOOL d2d_geometry_split_bezier(struct d2d_geometry *geometry, const struct d2d_segment_idx *idx) { const D2D1_POINT_2F *p[3]; struct d2d_figure *figure; D2D1_POINT_2F q[3]; size_t next; figure = &geometry->u.path.figures[idx->figure_idx]; p[0] = &figure->vertices[idx->vertex_idx]; p[1] = &figure->bezier_controls[idx->control_idx]; next = idx->vertex_idx + 1; if (next == figure->vertex_count) next = 0; p[2] = &figure->vertices[next]; d2d_point_lerp(&q[0], p[0], p[1], 0.5f); d2d_point_lerp(&q[1], p[1], p[2], 0.5f); d2d_point_lerp(&q[2], &q[0], &q[1], 0.5f); figure->bezier_controls[idx->control_idx] = q[0]; if (!(d2d_figure_insert_bezier_controls(figure, idx->control_idx + 1, 1, &q[1]))) return FALSE; if (!(d2d_figure_insert_vertex(figure, idx->vertex_idx + 1, q[2]))) return FALSE; figure->vertex_types[idx->vertex_idx + 1] = D2D_VERTEX_TYPE_SPLIT_BEZIER; return TRUE; } static HRESULT d2d_geometry_resolve_beziers(struct d2d_geometry *geometry) { struct d2d_segment_idx idx_p, idx_q; struct d2d_curve_vertex *b; const D2D1_POINT_2F *p[3]; struct d2d_figure *figure; size_t bezier_idx, i; if (!d2d_geometry_get_first_bezier_segment_idx(geometry, &idx_p)) return S_OK; /* Split overlapping bezier control triangles. */ while (d2d_geometry_get_next_bezier_segment_idx(geometry, &idx_p)) { d2d_geometry_get_first_bezier_segment_idx(geometry, &idx_q); while (idx_q.figure_idx < idx_p.figure_idx || idx_q.vertex_idx < idx_p.vertex_idx) { while (d2d_geometry_check_bezier_overlap(geometry, &idx_p, &idx_q)) { if (fabsf(d2d_geometry_bezier_ccw(geometry, &idx_q)) > fabsf(d2d_geometry_bezier_ccw(geometry, &idx_p))) { if (!d2d_geometry_split_bezier(geometry, &idx_q)) return E_OUTOFMEMORY; if (idx_p.figure_idx == idx_q.figure_idx) { ++idx_p.vertex_idx; ++idx_p.control_idx; } } else { if (!d2d_geometry_split_bezier(geometry, &idx_p)) return E_OUTOFMEMORY; } } d2d_geometry_get_next_bezier_segment_idx(geometry, &idx_q); } } for (i = 0; i < geometry->u.path.figure_count; ++i) { if (geometry->u.path.figures[i].flags & D2D_FIGURE_FLAG_HOLLOW) continue; geometry->fill.bezier_vertex_count += 3 * geometry->u.path.figures[i].bezier_control_count; } if (!(geometry->fill.bezier_vertices = heap_calloc(geometry->fill.bezier_vertex_count, sizeof(*geometry->fill.bezier_vertices)))) { ERR("Failed to allocate bezier vertices array.\n"); geometry->fill.bezier_vertex_count = 0; return E_OUTOFMEMORY; } bezier_idx = 0; d2d_geometry_get_first_bezier_segment_idx(geometry, &idx_p); for (;;) { float sign = -1.0f; figure = &geometry->u.path.figures[idx_p.figure_idx]; p[0] = &figure->vertices[idx_p.vertex_idx]; p[1] = &figure->bezier_controls[idx_p.control_idx]; i = idx_p.vertex_idx + 1; if (d2d_path_geometry_point_inside(geometry, p[1], FALSE)) { sign = 1.0f; d2d_figure_insert_vertex(figure, i, *p[1]); /* Inserting a vertex potentially invalidates p[0]. */ p[0] = &figure->vertices[idx_p.vertex_idx]; ++i; } if (i == figure->vertex_count) i = 0; p[2] = &figure->vertices[i]; b = &geometry->fill.bezier_vertices[bezier_idx * 3]; d2d_curve_vertex_set(&b[0], p[0], 0.0f, 0.0f, sign); d2d_curve_vertex_set(&b[1], p[1], 0.5f, 0.0f, sign); d2d_curve_vertex_set(&b[2], p[2], 1.0f, 1.0f, sign); if (!d2d_geometry_get_next_bezier_segment_idx(geometry, &idx_p)) break; ++bezier_idx; } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_geometry_sink_Close(ID2D1GeometrySink *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); HRESULT hr = E_FAIL; TRACE("iface %p.\n", iface); if (geometry->u.path.state != D2D_GEOMETRY_STATE_OPEN) { if (geometry->u.path.state != D2D_GEOMETRY_STATE_CLOSED) geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return D2DERR_WRONG_STATE; } geometry->u.path.state = D2D_GEOMETRY_STATE_CLOSED; if (!d2d_geometry_intersect_self(geometry)) goto done; if (FAILED(hr = d2d_geometry_resolve_beziers(geometry))) goto done; if (FAILED(hr = d2d_path_geometry_triangulate(geometry))) goto done; done: if (FAILED(hr)) { heap_free(geometry->fill.bezier_vertices); geometry->fill.bezier_vertex_count = 0; d2d_path_geometry_free_figures(geometry); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; } return hr; } static void STDMETHODCALLTYPE d2d_geometry_sink_AddLine(ID2D1GeometrySink *iface, D2D1_POINT_2F point) { TRACE("iface %p, point %s.\n", iface, debug_d2d_point_2f(&point)); d2d_geometry_sink_AddLines(iface, &point, 1); } static void STDMETHODCALLTYPE d2d_geometry_sink_AddBezier(ID2D1GeometrySink *iface, const D2D1_BEZIER_SEGMENT *bezier) { TRACE("iface %p, bezier %p.\n", iface, bezier); d2d_geometry_sink_AddBeziers(iface, bezier, 1); } static void STDMETHODCALLTYPE d2d_geometry_sink_AddQuadraticBezier(ID2D1GeometrySink *iface, const D2D1_QUADRATIC_BEZIER_SEGMENT *bezier) { TRACE("iface %p, bezier %p.\n", iface, bezier); ID2D1GeometrySink_AddQuadraticBeziers(iface, bezier, 1); } static void STDMETHODCALLTYPE d2d_geometry_sink_AddQuadraticBeziers(ID2D1GeometrySink *iface, const D2D1_QUADRATIC_BEZIER_SEGMENT *beziers, UINT32 bezier_count) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); struct d2d_figure *figure = &geometry->u.path.figures[geometry->u.path.figure_count - 1]; unsigned int i; TRACE("iface %p, beziers %p, bezier_count %u.\n", iface, beziers, bezier_count); if (geometry->u.path.state != D2D_GEOMETRY_STATE_FIGURE) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } for (i = 0; i < bezier_count; ++i) { D2D1_RECT_F bezier_bounds; D2D1_POINT_2F p[2]; /* Construct a cubic curve. */ d2d_point_lerp(&p[0], &figure->vertices[figure->vertex_count - 1], &beziers[i].point1, 2.0f / 3.0f); d2d_point_lerp(&p[1], &beziers[i].point2, &beziers[i].point1, 2.0f / 3.0f); if (!d2d_figure_add_original_bezier_controls(figure, 2, p)) { ERR("Failed to add cubic Bézier controls.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } d2d_rect_get_bezier_bounds(&bezier_bounds, &figure->vertices[figure->vertex_count - 1], &beziers[i].point1, &beziers[i].point2); figure->vertex_types[figure->vertex_count - 1] = D2D_VERTEX_TYPE_BEZIER; if (!d2d_figure_add_bezier_controls(figure, 1, &beziers[i].point1)) { ERR("Failed to add bezier.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } if (!d2d_figure_add_vertex(figure, beziers[i].point2)) { ERR("Failed to add bezier vertex.\n"); geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } d2d_rect_union(&figure->bounds, &bezier_bounds); } geometry->u.path.segment_count += bezier_count; } static void STDMETHODCALLTYPE d2d_geometry_sink_AddArc(ID2D1GeometrySink *iface, const D2D1_ARC_SEGMENT *arc) { struct d2d_geometry *geometry = impl_from_ID2D1GeometrySink(iface); FIXME("iface %p, arc %p stub!\n", iface, arc); if (geometry->u.path.state != D2D_GEOMETRY_STATE_FIGURE) { geometry->u.path.state = D2D_GEOMETRY_STATE_ERROR; return; } if (!d2d_figure_add_vertex(&geometry->u.path.figures[geometry->u.path.figure_count - 1], arc->point)) { ERR("Failed to add vertex.\n"); return; } ++geometry->u.path.segment_count; } static const struct ID2D1GeometrySinkVtbl d2d_geometry_sink_vtbl = { d2d_geometry_sink_QueryInterface, d2d_geometry_sink_AddRef, d2d_geometry_sink_Release, d2d_geometry_sink_SetFillMode, d2d_geometry_sink_SetSegmentFlags, d2d_geometry_sink_BeginFigure, d2d_geometry_sink_AddLines, d2d_geometry_sink_AddBeziers, d2d_geometry_sink_EndFigure, d2d_geometry_sink_Close, d2d_geometry_sink_AddLine, d2d_geometry_sink_AddBezier, d2d_geometry_sink_AddQuadraticBezier, d2d_geometry_sink_AddQuadraticBeziers, d2d_geometry_sink_AddArc, }; static inline struct d2d_geometry *impl_from_ID2D1PathGeometry(ID2D1PathGeometry *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_QueryInterface(ID2D1PathGeometry *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1PathGeometry) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1PathGeometry_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_path_geometry_AddRef(ID2D1PathGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_path_geometry_Release(ID2D1PathGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { d2d_path_geometry_free_figures(geometry); d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_path_geometry_GetFactory(ID2D1PathGeometry *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_GetBounds(ID2D1PathGeometry *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); size_t i; TRACE("iface %p, transform %p, bounds %p.\n", iface, transform, bounds); if (geometry->u.path.state != D2D_GEOMETRY_STATE_CLOSED) return D2DERR_WRONG_STATE; bounds->left = FLT_MAX; bounds->top = FLT_MAX; bounds->right = -FLT_MAX; bounds->bottom = -FLT_MAX; if (!transform) { if (geometry->u.path.bounds.left > geometry->u.path.bounds.right && !isinf(geometry->u.path.bounds.left)) { for (i = 0; i < geometry->u.path.figure_count; ++i) { if (geometry->u.path.figures[i].flags & D2D_FIGURE_FLAG_HOLLOW) continue; d2d_rect_union(&geometry->u.path.bounds, &geometry->u.path.figures[i].bounds); } if (geometry->u.path.bounds.left > geometry->u.path.bounds.right) { geometry->u.path.bounds.left = INFINITY; geometry->u.path.bounds.right = FLT_MAX; geometry->u.path.bounds.top = INFINITY; geometry->u.path.bounds.bottom = FLT_MAX; } } *bounds = geometry->u.path.bounds; return S_OK; } for (i = 0; i < geometry->u.path.figure_count; ++i) { const struct d2d_figure *figure = &geometry->u.path.figures[i]; enum d2d_vertex_type type = D2D_VERTEX_TYPE_NONE; D2D1_RECT_F bezier_bounds; D2D1_POINT_2F p, p1, p2; size_t j, bezier_idx; if (figure->flags & D2D_FIGURE_FLAG_HOLLOW) continue; /* Single vertex figures are reduced by CloseFigure(). */ if (figure->vertex_count == 0) { d2d_point_transform(&p, transform, figure->bounds.left, figure->bounds.top); d2d_rect_expand(bounds, &p); continue; } for (j = 0; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE) continue; p = figure->vertices[j]; type = figure->vertex_types[j]; d2d_point_transform(&p, transform, p.x, p.y); d2d_rect_expand(bounds, &p); break; } for (bezier_idx = 0, ++j; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE || d2d_vertex_type_is_split_bezier(figure->vertex_types[j])) continue; switch (type) { case D2D_VERTEX_TYPE_LINE: p = figure->vertices[j]; d2d_point_transform(&p, transform, p.x, p.y); d2d_rect_expand(bounds, &p); break; case D2D_VERTEX_TYPE_BEZIER: /* FIXME: This attempts to approximate a cubic Bézier with * a quadratic one. */ p1 = figure->original_bezier_controls[bezier_idx++]; d2d_point_transform(&p1, transform, p1.x, p1.y); p2 = figure->original_bezier_controls[bezier_idx++]; d2d_point_transform(&p2, transform, p2.x, p2.y); p1.x = (p1.x + p2.x) * 0.75f; p1.y = (p1.y + p2.y) * 0.75f; p2 = figure->vertices[j]; d2d_point_transform(&p2, transform, p2.x, p2.y); p1.x -= (p.x + p2.x) * 0.25f; p1.y -= (p.y + p2.y) * 0.25f; d2d_rect_get_bezier_bounds(&bezier_bounds, &p, &p1, &p2); d2d_rect_union(bounds, &bezier_bounds); p = p2; break; default: FIXME("Unhandled vertex type %#x.\n", type); p = figure->vertices[j]; d2d_point_transform(&p, transform, p.x, p.y); d2d_rect_expand(bounds, &p); break; } type = figure->vertex_types[j]; } if (d2d_vertex_type_is_bezier(type)) { /* FIXME: This attempts to approximate a cubic Bézier with * a quadratic one. */ p1 = figure->original_bezier_controls[bezier_idx++]; d2d_point_transform(&p1, transform, p1.x, p1.y); p2 = figure->original_bezier_controls[bezier_idx++]; d2d_point_transform(&p2, transform, p2.x, p2.y); p1.x = (p1.x + p2.x) * 0.75f; p1.y = (p1.y + p2.y) * 0.75f; p2 = figure->vertices[0]; d2d_point_transform(&p2, transform, p2.x, p2.y); p1.x -= (p.x + p2.x) * 0.25f; p1.y -= (p.y + p2.y) * 0.25f; d2d_rect_get_bezier_bounds(&bezier_bounds, &p, &p1, &p2); d2d_rect_union(bounds, &bezier_bounds); } } if (bounds->left > bounds->right) { bounds->left = INFINITY; bounds->right = FLT_MAX; bounds->top = INFINITY; bounds->bottom = FLT_MAX; } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_GetWidenedBounds(ID2D1PathGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_StrokeContainsPoint(ID2D1PathGeometry *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); enum d2d_vertex_type type = D2D_VERTEX_TYPE_NONE; unsigned int i, j, bezier_idx; D2D1_BEZIER_SEGMENT b; D2D1_POINT_2F p, p1; TRACE("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); if (stroke_style) FIXME("Ignoring stroke style %p.\n", stroke_style); if (!transform) transform = &identity; if (tolerance <= 0.0f) tolerance = D2D1_DEFAULT_FLATTENING_TOLERANCE; *contains = FALSE; for (i = 0; i < geometry->u.path.figure_count; ++i) { const struct d2d_figure *figure = &geometry->u.path.figures[i]; for (j = 0; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE) continue; p = figure->vertices[j]; type = figure->vertex_types[j]; break; } for (bezier_idx = 0, ++j; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE || d2d_vertex_type_is_split_bezier(figure->vertex_types[j])) continue; switch (type) { case D2D_VERTEX_TYPE_LINE: p1 = figure->vertices[j]; *contains = d2d_point_on_line_segment(&point, &p, &p1, transform, stroke_width * 0.5f, tolerance); p = p1; break; case D2D_VERTEX_TYPE_BEZIER: b.point1 = figure->original_bezier_controls[bezier_idx++]; b.point2 = figure->original_bezier_controls[bezier_idx++]; b.point3 = figure->vertices[j]; *contains = d2d_point_on_bezier_segment(&point, &p, &b, transform, stroke_width, tolerance); p = b.point3; break; default: FIXME("Unhandled vertex type %#x.\n", type); p = figure->vertices[j]; break; } if (*contains) return S_OK; type = figure->vertex_types[j]; } if (figure->flags & D2D_FIGURE_FLAG_CLOSED && (!*contains)) { if (type == D2D_VERTEX_TYPE_LINE) { p1 = figure->vertices[0]; *contains = d2d_point_on_line_segment(&point, &p, &p1, transform, stroke_width * 0.5f, tolerance); p = p1; } else if (d2d_vertex_type_is_bezier(type)) { b.point1 = figure->original_bezier_controls[bezier_idx++]; b.point2 = figure->original_bezier_controls[bezier_idx++]; b.point3 = figure->vertices[0]; *contains = d2d_point_on_bezier_segment(&point, &p, &b, transform, stroke_width, tolerance); p = b.point3; } } if (*contains) return S_OK; } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_FillContainsPoint(ID2D1PathGeometry *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); D2D1_MATRIX_3X2_F g_i; TRACE("iface %p, point %s, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); if (transform) { if (!d2d_matrix_invert(&g_i, transform)) return D2DERR_UNSUPPORTED_OPERATION; d2d_point_transform(&point, &g_i, point.x, point.y); } *contains = !!d2d_path_geometry_point_inside(geometry, &point, FALSE); TRACE("-> %#x.\n", *contains); return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_CompareWithGeometry(ID2D1PathGeometry *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static void d2d_geometry_flatten_cubic(ID2D1SimplifiedGeometrySink *sink, const D2D1_POINT_2F *p0, const D2D1_BEZIER_SEGMENT *b, float tolerance) { D2D1_BEZIER_SEGMENT b0, b1; D2D1_POINT_2F q; float d; /* It's certainly possible to calculate the maximum deviation of the * approximation from the curve, but it's a little involved. Instead, note * that if the control points were evenly spaced and collinear, p1 would * be exactly between p0 and p2, and p2 would be exactly between p1 and * p3. The deviation is a decent enough approximation, and much easier to * calculate. * * p1' = (p0 + p2) / 2 * p2' = (p1 + p3) / 2 * d = ‖p1 - p1'‖₁ + ‖p2 - p2'‖₁ */ d2d_point_lerp(&q, p0, &b->point2, 0.5f); d2d_point_subtract(&q, &b->point1, &q); d = fabsf(q.x) + fabsf(q.y); d2d_point_lerp(&q, &b->point1, &b->point3, 0.5f); d2d_point_subtract(&q, &b->point2, &q); d += fabsf(q.x) + fabsf(q.y); if (d < tolerance) { ID2D1SimplifiedGeometrySink_AddLines(sink, &b->point3, 1); return; } d2d_point_lerp(&q, &b->point1, &b->point2, 0.5f); b1.point3 = b->point3; d2d_point_lerp(&b1.point2, &b1.point3, &b->point2, 0.5f); d2d_point_lerp(&b1.point1, &b1.point2, &q, 0.5f); d2d_point_lerp(&b0.point1, p0, &b->point1, 0.5f); d2d_point_lerp(&b0.point2, &b0.point1, &q, 0.5f); d2d_point_lerp(&b0.point3, &b0.point2, &b1.point1, 0.5f); d2d_geometry_flatten_cubic(sink, p0, &b0, tolerance); ID2D1SimplifiedGeometrySink_SetSegmentFlags(sink, D2D1_PATH_SEGMENT_FORCE_ROUND_LINE_JOIN); d2d_geometry_flatten_cubic(sink, &b0.point3, &b1, tolerance); ID2D1SimplifiedGeometrySink_SetSegmentFlags(sink, D2D1_PATH_SEGMENT_NONE); } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Simplify(ID2D1PathGeometry *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); enum d2d_vertex_type type = D2D_VERTEX_TYPE_NONE; unsigned int i, j, bezier_idx; D2D1_FIGURE_BEGIN begin; D2D1_BEZIER_SEGMENT b; D2D1_FIGURE_END end; D2D1_POINT_2F p; TRACE("iface %p, option %#x, transform %p, tolerance %.8e, sink %p.\n", iface, option, transform, tolerance, sink); ID2D1SimplifiedGeometrySink_SetFillMode(sink, geometry->u.path.fill_mode); for (i = 0; i < geometry->u.path.figure_count; ++i) { const struct d2d_figure *figure = &geometry->u.path.figures[i]; for (j = 0; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE) continue; p = figure->vertices[j]; if (transform) d2d_point_transform(&p, transform, p.x, p.y); begin = figure->flags & D2D_FIGURE_FLAG_HOLLOW ? D2D1_FIGURE_BEGIN_HOLLOW : D2D1_FIGURE_BEGIN_FILLED; ID2D1SimplifiedGeometrySink_BeginFigure(sink, p, begin); type = figure->vertex_types[j]; break; } for (bezier_idx = 0, ++j; j < figure->vertex_count; ++j) { if (figure->vertex_types[j] == D2D_VERTEX_TYPE_NONE || d2d_vertex_type_is_split_bezier(figure->vertex_types[j])) continue; switch (type) { case D2D_VERTEX_TYPE_LINE: p = figure->vertices[j]; if (transform) d2d_point_transform(&p, transform, p.x, p.y); ID2D1SimplifiedGeometrySink_AddLines(sink, &p, 1); break; case D2D_VERTEX_TYPE_BEZIER: b.point1 = figure->original_bezier_controls[bezier_idx++]; b.point2 = figure->original_bezier_controls[bezier_idx++]; b.point3 = figure->vertices[j]; if (transform) { d2d_point_transform(&b.point1, transform, b.point1.x, b.point1.y); d2d_point_transform(&b.point2, transform, b.point2.x, b.point2.y); d2d_point_transform(&b.point3, transform, b.point3.x, b.point3.y); } if (option == D2D1_GEOMETRY_SIMPLIFICATION_OPTION_LINES) d2d_geometry_flatten_cubic(sink, &p, &b, tolerance); else ID2D1SimplifiedGeometrySink_AddBeziers(sink, &b, 1); p = b.point3; break; default: FIXME("Unhandled vertex type %#x.\n", type); p = figure->vertices[j]; if (transform) d2d_point_transform(&p, transform, p.x, p.y); ID2D1SimplifiedGeometrySink_AddLines(sink, &p, 1); break; } type = figure->vertex_types[j]; } if (d2d_vertex_type_is_bezier(type)) { b.point1 = figure->original_bezier_controls[bezier_idx++]; b.point2 = figure->original_bezier_controls[bezier_idx++]; b.point3 = figure->vertices[0]; if (transform) { d2d_point_transform(&b.point1, transform, b.point1.x, b.point1.y); d2d_point_transform(&b.point2, transform, b.point2.x, b.point2.y); d2d_point_transform(&b.point3, transform, b.point3.x, b.point3.y); } if (option == D2D1_GEOMETRY_SIMPLIFICATION_OPTION_LINES) d2d_geometry_flatten_cubic(sink, &p, &b, tolerance); else ID2D1SimplifiedGeometrySink_AddBeziers(sink, &b, 1); } end = figure->flags & D2D_FIGURE_FLAG_CLOSED ? D2D1_FIGURE_END_CLOSED : D2D1_FIGURE_END_OPEN; ID2D1SimplifiedGeometrySink_EndFigure(sink, end); } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Tessellate(ID2D1PathGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_CombineWithGeometry(ID2D1PathGeometry *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Outline(ID2D1PathGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_ComputeArea(ID2D1PathGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_ComputeLength(ID2D1PathGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_ComputePointAtLength(ID2D1PathGeometry *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Widen(ID2D1PathGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Open(ID2D1PathGeometry *iface, ID2D1GeometrySink **sink) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); TRACE("iface %p, sink %p.\n", iface, sink); if (geometry->u.path.state != D2D_GEOMETRY_STATE_INITIAL) return D2DERR_WRONG_STATE; *sink = &geometry->u.path.ID2D1GeometrySink_iface; ID2D1GeometrySink_AddRef(*sink); geometry->u.path.state = D2D_GEOMETRY_STATE_OPEN; return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_Stream(ID2D1PathGeometry *iface, ID2D1GeometrySink *sink) { FIXME("iface %p, sink %p stub!\n", iface, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_GetSegmentCount(ID2D1PathGeometry *iface, UINT32 *count) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); TRACE("iface %p, count %p.\n", iface, count); if (geometry->u.path.state != D2D_GEOMETRY_STATE_CLOSED) return D2DERR_WRONG_STATE; *count = geometry->u.path.segment_count; return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_path_geometry_GetFigureCount(ID2D1PathGeometry *iface, UINT32 *count) { struct d2d_geometry *geometry = impl_from_ID2D1PathGeometry(iface); TRACE("iface %p, count %p.\n", iface, count); if (geometry->u.path.state != D2D_GEOMETRY_STATE_CLOSED) return D2DERR_WRONG_STATE; *count = geometry->u.path.figure_count; return S_OK; } static const struct ID2D1PathGeometryVtbl d2d_path_geometry_vtbl = { d2d_path_geometry_QueryInterface, d2d_path_geometry_AddRef, d2d_path_geometry_Release, d2d_path_geometry_GetFactory, d2d_path_geometry_GetBounds, d2d_path_geometry_GetWidenedBounds, d2d_path_geometry_StrokeContainsPoint, d2d_path_geometry_FillContainsPoint, d2d_path_geometry_CompareWithGeometry, d2d_path_geometry_Simplify, d2d_path_geometry_Tessellate, d2d_path_geometry_CombineWithGeometry, d2d_path_geometry_Outline, d2d_path_geometry_ComputeArea, d2d_path_geometry_ComputeLength, d2d_path_geometry_ComputePointAtLength, d2d_path_geometry_Widen, d2d_path_geometry_Open, d2d_path_geometry_Stream, d2d_path_geometry_GetSegmentCount, d2d_path_geometry_GetFigureCount, }; void d2d_path_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory) { d2d_geometry_init(geometry, factory, &identity, (ID2D1GeometryVtbl *)&d2d_path_geometry_vtbl); geometry->u.path.ID2D1GeometrySink_iface.lpVtbl = &d2d_geometry_sink_vtbl; geometry->u.path.bounds.left = FLT_MAX; geometry->u.path.bounds.right = -FLT_MAX; geometry->u.path.bounds.top = FLT_MAX; geometry->u.path.bounds.bottom = -FLT_MAX; } static inline struct d2d_geometry *impl_from_ID2D1EllipseGeometry(ID2D1EllipseGeometry *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_QueryInterface(ID2D1EllipseGeometry *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1EllipseGeometry) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1EllipseGeometry_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_ellipse_geometry_AddRef(ID2D1EllipseGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1EllipseGeometry(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_ellipse_geometry_Release(ID2D1EllipseGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1EllipseGeometry(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_ellipse_geometry_GetFactory(ID2D1EllipseGeometry *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1EllipseGeometry(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_GetBounds(ID2D1EllipseGeometry *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { FIXME("iface %p, transform %p, bounds %p stub!\n", iface, transform, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_GetWidenedBounds(ID2D1EllipseGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_StrokeContainsPoint(ID2D1EllipseGeometry *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p stub!\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_FillContainsPoint(ID2D1EllipseGeometry *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, transform %p, tolerance %.8e, contains %p stub!\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_CompareWithGeometry(ID2D1EllipseGeometry *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_Simplify(ID2D1EllipseGeometry *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, option %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, option, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_Tessellate(ID2D1EllipseGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_CombineWithGeometry(ID2D1EllipseGeometry *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_Outline(ID2D1EllipseGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_ComputeArea(ID2D1EllipseGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_ComputeLength(ID2D1EllipseGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_ComputePointAtLength(ID2D1EllipseGeometry *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_ellipse_geometry_Widen(ID2D1EllipseGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static void STDMETHODCALLTYPE d2d_ellipse_geometry_GetEllipse(ID2D1EllipseGeometry *iface, D2D1_ELLIPSE *ellipse) { struct d2d_geometry *geometry = impl_from_ID2D1EllipseGeometry(iface); TRACE("iface %p, ellipse %p.\n", iface, ellipse); *ellipse = geometry->u.ellipse.ellipse; } static const struct ID2D1EllipseGeometryVtbl d2d_ellipse_geometry_vtbl = { d2d_ellipse_geometry_QueryInterface, d2d_ellipse_geometry_AddRef, d2d_ellipse_geometry_Release, d2d_ellipse_geometry_GetFactory, d2d_ellipse_geometry_GetBounds, d2d_ellipse_geometry_GetWidenedBounds, d2d_ellipse_geometry_StrokeContainsPoint, d2d_ellipse_geometry_FillContainsPoint, d2d_ellipse_geometry_CompareWithGeometry, d2d_ellipse_geometry_Simplify, d2d_ellipse_geometry_Tessellate, d2d_ellipse_geometry_CombineWithGeometry, d2d_ellipse_geometry_Outline, d2d_ellipse_geometry_ComputeArea, d2d_ellipse_geometry_ComputeLength, d2d_ellipse_geometry_ComputePointAtLength, d2d_ellipse_geometry_Widen, d2d_ellipse_geometry_GetEllipse, }; HRESULT d2d_ellipse_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory, const D2D1_ELLIPSE *ellipse) { D2D1_POINT_2F *v, v1, v2, v3, v4; struct d2d_face *f; float l, r, t, b; d2d_geometry_init(geometry, factory, &identity, (ID2D1GeometryVtbl *)&d2d_ellipse_geometry_vtbl); geometry->u.ellipse.ellipse = *ellipse; if (!(geometry->fill.vertices = heap_alloc(4 * sizeof(*geometry->fill.vertices)))) goto fail; if (!d2d_array_reserve((void **)&geometry->fill.faces, &geometry->fill.faces_size, 2, sizeof(*geometry->fill.faces))) goto fail; l = ellipse->point.x - ellipse->radiusX; r = ellipse->point.x + ellipse->radiusX; t = ellipse->point.y - ellipse->radiusY; b = ellipse->point.y + ellipse->radiusY; d2d_point_set(&v1, r, t); d2d_point_set(&v2, r, b); d2d_point_set(&v3, l, b); d2d_point_set(&v4, l, t); v = geometry->fill.vertices; d2d_point_set(&v[0], ellipse->point.x, t); d2d_point_set(&v[1], r, ellipse->point.y); d2d_point_set(&v[2], ellipse->point.x, b); d2d_point_set(&v[3], l, ellipse->point.y); geometry->fill.vertex_count = 4; f = geometry->fill.faces; d2d_face_set(&f[0], 0, 3, 2); d2d_face_set(&f[1], 0, 2, 1); geometry->fill.face_count = 2; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[0], &v1, &v[1])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[1], &v2, &v[2])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[2], &v3, &v[3])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[3], &v4, &v[0])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[0], &v1, &v[1])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[1], &v2, &v[2])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[2], &v3, &v[3])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[3], &v4, &v[0])) goto fail; return S_OK; fail: d2d_geometry_cleanup(geometry); return E_OUTOFMEMORY; } static inline struct d2d_geometry *impl_from_ID2D1RectangleGeometry(ID2D1RectangleGeometry *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_QueryInterface(ID2D1RectangleGeometry *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1RectangleGeometry) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1RectangleGeometry_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_rectangle_geometry_AddRef(ID2D1RectangleGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_rectangle_geometry_Release(ID2D1RectangleGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_rectangle_geometry_GetFactory(ID2D1RectangleGeometry *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_GetBounds(ID2D1RectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); D2D1_RECT_F *rect; D2D1_POINT_2F p; TRACE("iface %p, transform %p, bounds %p.\n", iface, transform, bounds); rect = &geometry->u.rectangle.rect; if (!transform) { *bounds = *rect; return S_OK; } bounds->left = FLT_MAX; bounds->top = FLT_MAX; bounds->right = -FLT_MAX; bounds->bottom = -FLT_MAX; d2d_point_transform(&p, transform, rect->left, rect->top); d2d_rect_expand(bounds, &p); d2d_point_transform(&p, transform, rect->left, rect->bottom); d2d_rect_expand(bounds, &p); d2d_point_transform(&p, transform, rect->right, rect->bottom); d2d_rect_expand(bounds, &p); d2d_point_transform(&p, transform, rect->right, rect->top); d2d_rect_expand(bounds, &p); return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_GetWidenedBounds(ID2D1RectangleGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_StrokeContainsPoint(ID2D1RectangleGeometry *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { const struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); const D2D1_RECT_F *rect = &geometry->u.rectangle.rect; unsigned int i; struct { D2D1_POINT_2F s, e; } segments[4]; TRACE("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); if (stroke_style) FIXME("Ignoring stroke style %p.\n", stroke_style); tolerance = fabsf(tolerance); if (!transform) { D2D1_POINT_2F d, s; s.x = rect->right - rect->left; s.y = rect->bottom - rect->top; d.x = fabsf((rect->right + rect->left) * 0.5f - point.x); d.y = fabsf((rect->bottom + rect->top) * 0.5f - point.y); /* Inside test. */ if (d.x <= (s.x - stroke_width) * 0.5f - tolerance && d.y <= (s.y - stroke_width) * 0.5f - tolerance) { *contains = FALSE; return S_OK; } if (tolerance == 0.0f) { *contains = d.x < (s.x + stroke_width) * 0.5f && d.y < (s.y + stroke_width) * 0.5f; } else { d.x = max(d.x - (s.x + stroke_width) * 0.5f, 0.0f); d.y = max(d.y - (s.y + stroke_width) * 0.5f, 0.0f); *contains = d2d_point_dot(&d, &d) < tolerance * tolerance; } return S_OK; } stroke_width *= 0.5f; d2d_point_set(&segments[0].s, rect->left - stroke_width, rect->bottom); d2d_point_set(&segments[0].e, rect->right + stroke_width, rect->bottom); d2d_point_set(&segments[1].s, rect->right, rect->bottom + stroke_width); d2d_point_set(&segments[1].e, rect->right, rect->top - stroke_width); d2d_point_set(&segments[2].s, rect->right + stroke_width, rect->top); d2d_point_set(&segments[2].e, rect->left - stroke_width, rect->top); d2d_point_set(&segments[3].s, rect->left, rect->top - stroke_width); d2d_point_set(&segments[3].e, rect->left, rect->bottom + stroke_width); *contains = FALSE; for (i = 0; i < ARRAY_SIZE(segments); ++i) { if (d2d_point_on_line_segment(&point, &segments[i].s, &segments[i].e, transform, stroke_width, tolerance)) { *contains = TRUE; break; } } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_FillContainsPoint(ID2D1RectangleGeometry *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); D2D1_RECT_F *rect = &geometry->u.rectangle.rect; float dx, dy; TRACE("iface %p, point %s, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); if (transform) { D2D1_MATRIX_3X2_F g_i; if (!d2d_matrix_invert(&g_i, transform)) return D2DERR_UNSUPPORTED_OPERATION; d2d_point_transform(&point, &g_i, point.x, point.y); } if (tolerance == 0.0f) tolerance = D2D1_DEFAULT_FLATTENING_TOLERANCE; dx = max(fabsf((rect->right + rect->left) / 2.0f - point.x) - (rect->right - rect->left) / 2.0f, 0.0f); dy = max(fabsf((rect->bottom + rect->top) / 2.0f - point.y) - (rect->bottom - rect->top) / 2.0f, 0.0f); *contains = tolerance * tolerance > (dx * dx + dy * dy); return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_CompareWithGeometry(ID2D1RectangleGeometry *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_Simplify(ID2D1RectangleGeometry *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); D2D1_RECT_F *rect = &geometry->u.rectangle.rect; D2D1_POINT_2F p[4]; unsigned int i; TRACE("iface %p, option %#x, transform %p, tolerance %.8e, sink %p.\n", iface, option, transform, tolerance, sink); d2d_point_set(&p[0], rect->left, rect->top); d2d_point_set(&p[1], rect->right, rect->top); d2d_point_set(&p[2], rect->right, rect->bottom); d2d_point_set(&p[3], rect->left, rect->bottom); if (transform) { for (i = 0; i < ARRAY_SIZE(p); ++i) { d2d_point_transform(&p[i], transform, p[i].x, p[i].y); } } ID2D1SimplifiedGeometrySink_SetFillMode(sink, D2D1_FILL_MODE_ALTERNATE); ID2D1SimplifiedGeometrySink_BeginFigure(sink, p[0], D2D1_FIGURE_BEGIN_FILLED); ID2D1SimplifiedGeometrySink_AddLines(sink, &p[1], 3); ID2D1SimplifiedGeometrySink_EndFigure(sink, D2D1_FIGURE_END_CLOSED); return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_Tessellate(ID2D1RectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_CombineWithGeometry(ID2D1RectangleGeometry *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_Outline(ID2D1RectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_ComputeArea(ID2D1RectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_ComputeLength(ID2D1RectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_ComputePointAtLength(ID2D1RectangleGeometry *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rectangle_geometry_Widen(ID2D1RectangleGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static void STDMETHODCALLTYPE d2d_rectangle_geometry_GetRect(ID2D1RectangleGeometry *iface, D2D1_RECT_F *rect) { struct d2d_geometry *geometry = impl_from_ID2D1RectangleGeometry(iface); TRACE("iface %p, rect %p.\n", iface, rect); *rect = geometry->u.rectangle.rect; } static const struct ID2D1RectangleGeometryVtbl d2d_rectangle_geometry_vtbl = { d2d_rectangle_geometry_QueryInterface, d2d_rectangle_geometry_AddRef, d2d_rectangle_geometry_Release, d2d_rectangle_geometry_GetFactory, d2d_rectangle_geometry_GetBounds, d2d_rectangle_geometry_GetWidenedBounds, d2d_rectangle_geometry_StrokeContainsPoint, d2d_rectangle_geometry_FillContainsPoint, d2d_rectangle_geometry_CompareWithGeometry, d2d_rectangle_geometry_Simplify, d2d_rectangle_geometry_Tessellate, d2d_rectangle_geometry_CombineWithGeometry, d2d_rectangle_geometry_Outline, d2d_rectangle_geometry_ComputeArea, d2d_rectangle_geometry_ComputeLength, d2d_rectangle_geometry_ComputePointAtLength, d2d_rectangle_geometry_Widen, d2d_rectangle_geometry_GetRect, }; HRESULT d2d_rectangle_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory, const D2D1_RECT_F *rect) { struct d2d_face *f; D2D1_POINT_2F *v; float l, r, t, b; static const D2D1_POINT_2F prev[] = { { 1.0f, 0.0f}, { 0.0f, -1.0f}, {-1.0f, 0.0f}, { 0.0f, 1.0f}, }; static const D2D1_POINT_2F next[] = { { 0.0f, 1.0f}, { 1.0f, 0.0f}, { 0.0f, -1.0f}, {-1.0f, 0.0f}, }; d2d_geometry_init(geometry, factory, &identity, (ID2D1GeometryVtbl *)&d2d_rectangle_geometry_vtbl); geometry->u.rectangle.rect = *rect; if (!(geometry->fill.vertices = heap_alloc(4 * sizeof(*geometry->fill.vertices)))) goto fail; if (!d2d_array_reserve((void **)&geometry->fill.faces, &geometry->fill.faces_size, 2, sizeof(*geometry->fill.faces))) goto fail; l = min(rect->left, rect->right); r = max(rect->left, rect->right); t = min(rect->top, rect->bottom); b = max(rect->top, rect->bottom); v = geometry->fill.vertices; d2d_point_set(&v[0], l, t); d2d_point_set(&v[1], l, b); d2d_point_set(&v[2], r, b); d2d_point_set(&v[3], r, t); geometry->fill.vertex_count = 4; f = geometry->fill.faces; d2d_face_set(&f[0], 1, 2, 0); d2d_face_set(&f[1], 0, 2, 3); geometry->fill.face_count = 2; if (!d2d_geometry_outline_add_line_segment(geometry, &v[0], &v[1])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[1], &v[2])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[2], &v[3])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[3], &v[0])) goto fail; if (!d2d_geometry_outline_add_join(geometry, &prev[0], &v[0], &next[0])) goto fail; if (!d2d_geometry_outline_add_join(geometry, &prev[1], &v[1], &next[1])) goto fail; if (!d2d_geometry_outline_add_join(geometry, &prev[2], &v[2], &next[2])) goto fail; if (!d2d_geometry_outline_add_join(geometry, &prev[3], &v[3], &next[3])) goto fail; return S_OK; fail: d2d_geometry_cleanup(geometry); return E_OUTOFMEMORY; } static inline struct d2d_geometry *impl_from_ID2D1RoundedRectangleGeometry(ID2D1RoundedRectangleGeometry *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_QueryInterface(ID2D1RoundedRectangleGeometry *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1RoundedRectangleGeometry) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1RoundedRectangleGeometry_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_AddRef(ID2D1RoundedRectangleGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1RoundedRectangleGeometry(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_Release(ID2D1RoundedRectangleGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1RoundedRectangleGeometry(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_GetFactory(ID2D1RoundedRectangleGeometry *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1RoundedRectangleGeometry(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_GetBounds(ID2D1RoundedRectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { FIXME("iface %p, transform %p, bounds %p stub!\n", iface, transform, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_GetWidenedBounds(ID2D1RoundedRectangleGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_StrokeContainsPoint( ID2D1RoundedRectangleGeometry *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p stub!\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_FillContainsPoint(ID2D1RoundedRectangleGeometry *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, transform %p, tolerance %.8e, contains %p stub!\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_CompareWithGeometry( ID2D1RoundedRectangleGeometry *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_Simplify(ID2D1RoundedRectangleGeometry *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, option %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, option, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_Tessellate(ID2D1RoundedRectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_CombineWithGeometry( ID2D1RoundedRectangleGeometry *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_Outline(ID2D1RoundedRectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_ComputeArea(ID2D1RoundedRectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_ComputeLength(ID2D1RoundedRectangleGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_ComputePointAtLength( ID2D1RoundedRectangleGeometry *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_Widen(ID2D1RoundedRectangleGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static void STDMETHODCALLTYPE d2d_rounded_rectangle_geometry_GetRoundedRect(ID2D1RoundedRectangleGeometry *iface, D2D1_ROUNDED_RECT *rounded_rect) { struct d2d_geometry *geometry = impl_from_ID2D1RoundedRectangleGeometry(iface); TRACE("iface %p, rounded_rect %p.\n", iface, rounded_rect); *rounded_rect = geometry->u.rounded_rectangle.rounded_rect; } static const struct ID2D1RoundedRectangleGeometryVtbl d2d_rounded_rectangle_geometry_vtbl = { d2d_rounded_rectangle_geometry_QueryInterface, d2d_rounded_rectangle_geometry_AddRef, d2d_rounded_rectangle_geometry_Release, d2d_rounded_rectangle_geometry_GetFactory, d2d_rounded_rectangle_geometry_GetBounds, d2d_rounded_rectangle_geometry_GetWidenedBounds, d2d_rounded_rectangle_geometry_StrokeContainsPoint, d2d_rounded_rectangle_geometry_FillContainsPoint, d2d_rounded_rectangle_geometry_CompareWithGeometry, d2d_rounded_rectangle_geometry_Simplify, d2d_rounded_rectangle_geometry_Tessellate, d2d_rounded_rectangle_geometry_CombineWithGeometry, d2d_rounded_rectangle_geometry_Outline, d2d_rounded_rectangle_geometry_ComputeArea, d2d_rounded_rectangle_geometry_ComputeLength, d2d_rounded_rectangle_geometry_ComputePointAtLength, d2d_rounded_rectangle_geometry_Widen, d2d_rounded_rectangle_geometry_GetRoundedRect, }; HRESULT d2d_rounded_rectangle_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory, const D2D1_ROUNDED_RECT *rounded_rect) { D2D1_POINT_2F *v, v1, v2, v3, v4; struct d2d_face *f; float l, r, t, b; float rx, ry; d2d_geometry_init(geometry, factory, &identity, (ID2D1GeometryVtbl *)&d2d_rounded_rectangle_geometry_vtbl); geometry->u.rounded_rectangle.rounded_rect = *rounded_rect; if (!(geometry->fill.vertices = heap_alloc(8 * sizeof(*geometry->fill.vertices)))) goto fail; if (!d2d_array_reserve((void **)&geometry->fill.faces, &geometry->fill.faces_size, 6, sizeof(*geometry->fill.faces))) goto fail; l = min(rounded_rect->rect.left, rounded_rect->rect.right); r = max(rounded_rect->rect.left, rounded_rect->rect.right); t = min(rounded_rect->rect.top, rounded_rect->rect.bottom); b = max(rounded_rect->rect.top, rounded_rect->rect.bottom); rx = min(rounded_rect->radiusX, 0.5f * (r - l)); ry = min(rounded_rect->radiusY, 0.5f * (b - t)); d2d_point_set(&v1, r, t); d2d_point_set(&v2, r, b); d2d_point_set(&v3, l, b); d2d_point_set(&v4, l, t); v = geometry->fill.vertices; d2d_point_set(&v[0], l + rx, t); d2d_point_set(&v[1], r - rx, t); d2d_point_set(&v[2], r, t + ry); d2d_point_set(&v[3], r, b - ry); d2d_point_set(&v[4], r - rx, b); d2d_point_set(&v[5], l + rx, b); d2d_point_set(&v[6], l, b - ry); d2d_point_set(&v[7], l, t + ry); geometry->fill.vertex_count = 8; f = geometry->fill.faces; d2d_face_set(&f[0], 0, 7, 6); d2d_face_set(&f[1], 0, 6, 5); d2d_face_set(&f[2], 0, 5, 4); d2d_face_set(&f[3], 0, 4, 1); d2d_face_set(&f[4], 1, 4, 3); d2d_face_set(&f[5], 1, 3, 2); geometry->fill.face_count = 6; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[1], &v1, &v[2])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[3], &v2, &v[4])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[5], &v3, &v[6])) goto fail; if (!d2d_geometry_fill_add_arc_triangle(geometry, &v[7], &v4, &v[0])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[0], &v[1])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[1], &v1, &v[2])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[2], &v[3])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[3], &v2, &v[4])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[4], &v[5])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[5], &v3, &v[6])) goto fail; if (!d2d_geometry_outline_add_line_segment(geometry, &v[6], &v[7])) goto fail; if (!d2d_geometry_outline_add_arc_quadrant(geometry, &v[7], &v4, &v[0])) goto fail; return S_OK; fail: d2d_geometry_cleanup(geometry); return E_OUTOFMEMORY; } static inline struct d2d_geometry *impl_from_ID2D1TransformedGeometry(ID2D1TransformedGeometry *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_QueryInterface(ID2D1TransformedGeometry *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1TransformedGeometry) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1TransformedGeometry_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_transformed_geometry_AddRef(ID2D1TransformedGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_transformed_geometry_Release(ID2D1TransformedGeometry *iface) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { geometry->outline.arc_faces = NULL; geometry->outline.arcs = NULL; geometry->outline.bezier_faces = NULL; geometry->outline.beziers = NULL; geometry->outline.faces = NULL; geometry->outline.vertices = NULL; geometry->fill.arc_vertices = NULL; geometry->fill.bezier_vertices = NULL; geometry->fill.faces = NULL; geometry->fill.vertices = NULL; ID2D1Geometry_Release(geometry->u.transformed.src_geometry); d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_transformed_geometry_GetFactory(ID2D1TransformedGeometry *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_GetBounds(ID2D1TransformedGeometry *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); D2D1_MATRIX_3X2_F g; TRACE("iface %p, transform %p, bounds %p.\n", iface, transform, bounds); g = geometry->transform; if (transform) d2d_matrix_multiply(&g, transform); return ID2D1Geometry_GetBounds(geometry->u.transformed.src_geometry, &g, bounds); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_GetWidenedBounds(ID2D1TransformedGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_StrokeContainsPoint(ID2D1TransformedGeometry *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); D2D1_MATRIX_3X2_F g; TRACE("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); g = geometry->transform; if (transform) d2d_matrix_multiply(&g, transform); return ID2D1Geometry_StrokeContainsPoint(geometry->u.transformed.src_geometry, point, stroke_width, stroke_style, &g, tolerance, contains); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_FillContainsPoint(ID2D1TransformedGeometry *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); D2D1_MATRIX_3X2_F g; TRACE("iface %p, point %s, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); g = geometry->transform; if (transform) d2d_matrix_multiply(&g, transform); return ID2D1Geometry_FillContainsPoint(geometry->u.transformed.src_geometry, point, &g, tolerance, contains); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_CompareWithGeometry(ID2D1TransformedGeometry *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_Simplify(ID2D1TransformedGeometry *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); D2D1_MATRIX_3X2_F g; TRACE("iface %p, option %#x, transform %p, tolerance %.8e, sink %p.\n", iface, option, transform, tolerance, sink); g = geometry->transform; if (transform) d2d_matrix_multiply(&g, transform); return ID2D1Geometry_Simplify(geometry->u.transformed.src_geometry, option, &g, tolerance, sink); } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_Tessellate(ID2D1TransformedGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_CombineWithGeometry(ID2D1TransformedGeometry *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_Outline(ID2D1TransformedGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_ComputeArea(ID2D1TransformedGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_ComputeLength(ID2D1TransformedGeometry *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_ComputePointAtLength(ID2D1TransformedGeometry *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_transformed_geometry_Widen(ID2D1TransformedGeometry *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static void STDMETHODCALLTYPE d2d_transformed_geometry_GetSourceGeometry(ID2D1TransformedGeometry *iface, ID2D1Geometry **src_geometry) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); TRACE("iface %p, src_geometry %p.\n", iface, src_geometry); ID2D1Geometry_AddRef(*src_geometry = geometry->u.transformed.src_geometry); } static void STDMETHODCALLTYPE d2d_transformed_geometry_GetTransform(ID2D1TransformedGeometry *iface, D2D1_MATRIX_3X2_F *transform) { struct d2d_geometry *geometry = impl_from_ID2D1TransformedGeometry(iface); TRACE("iface %p, transform %p.\n", iface, transform); *transform = geometry->u.transformed.transform; } static const struct ID2D1TransformedGeometryVtbl d2d_transformed_geometry_vtbl = { d2d_transformed_geometry_QueryInterface, d2d_transformed_geometry_AddRef, d2d_transformed_geometry_Release, d2d_transformed_geometry_GetFactory, d2d_transformed_geometry_GetBounds, d2d_transformed_geometry_GetWidenedBounds, d2d_transformed_geometry_StrokeContainsPoint, d2d_transformed_geometry_FillContainsPoint, d2d_transformed_geometry_CompareWithGeometry, d2d_transformed_geometry_Simplify, d2d_transformed_geometry_Tessellate, d2d_transformed_geometry_CombineWithGeometry, d2d_transformed_geometry_Outline, d2d_transformed_geometry_ComputeArea, d2d_transformed_geometry_ComputeLength, d2d_transformed_geometry_ComputePointAtLength, d2d_transformed_geometry_Widen, d2d_transformed_geometry_GetSourceGeometry, d2d_transformed_geometry_GetTransform, }; void d2d_transformed_geometry_init(struct d2d_geometry *geometry, ID2D1Factory *factory, ID2D1Geometry *src_geometry, const D2D_MATRIX_3X2_F *transform) { struct d2d_geometry *src_impl; D2D_MATRIX_3X2_F g; src_impl = unsafe_impl_from_ID2D1Geometry(src_geometry); g = src_impl->transform; d2d_matrix_multiply(&g, transform); d2d_geometry_init(geometry, factory, &g, (ID2D1GeometryVtbl *)&d2d_transformed_geometry_vtbl); ID2D1Geometry_AddRef(geometry->u.transformed.src_geometry = src_geometry); geometry->u.transformed.transform = *transform; geometry->fill = src_impl->fill; geometry->outline = src_impl->outline; } static inline struct d2d_geometry *impl_from_ID2D1GeometryGroup(ID2D1GeometryGroup *iface) { return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_QueryInterface(ID2D1GeometryGroup *iface, REFIID iid, void **out) { TRACE("iface %p, iid %s, out %p.\n", iface, debugstr_guid(iid), out); if (IsEqualGUID(iid, &IID_ID2D1GeometryGroup) || IsEqualGUID(iid, &IID_ID2D1Geometry) || IsEqualGUID(iid, &IID_ID2D1Resource) || IsEqualGUID(iid, &IID_IUnknown)) { ID2D1GeometryGroup_AddRef(iface); *out = iface; return S_OK; } WARN("%s not implemented, returning E_NOINTERFACE.\n", debugstr_guid(iid)); *out = NULL; return E_NOINTERFACE; } static ULONG STDMETHODCALLTYPE d2d_geometry_group_AddRef(ID2D1GeometryGroup *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); ULONG refcount = InterlockedIncrement(&geometry->refcount); TRACE("%p increasing refcount to %u.\n", iface, refcount); return refcount; } static ULONG STDMETHODCALLTYPE d2d_geometry_group_Release(ID2D1GeometryGroup *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); ULONG refcount = InterlockedDecrement(&geometry->refcount); unsigned int i; TRACE("%p decreasing refcount to %u.\n", iface, refcount); if (!refcount) { for (i = 0; i < geometry->u.group.geometry_count; ++i) ID2D1Geometry_Release(geometry->u.group.src_geometries[i]); heap_free(geometry->u.group.src_geometries); d2d_geometry_cleanup(geometry); heap_free(geometry); } return refcount; } static void STDMETHODCALLTYPE d2d_geometry_group_GetFactory(ID2D1GeometryGroup *iface, ID2D1Factory **factory) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); TRACE("iface %p, factory %p.\n", iface, factory); ID2D1Factory_AddRef(*factory = geometry->factory); } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_GetBounds(ID2D1GeometryGroup *iface, const D2D1_MATRIX_3X2_F *transform, D2D1_RECT_F *bounds) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); D2D1_RECT_F rect; unsigned int i; TRACE("iface %p, transform %p, bounds %p.\n", iface, transform, bounds); bounds->left = FLT_MAX; bounds->top = FLT_MAX; bounds->right = -FLT_MAX; bounds->bottom = -FLT_MAX; for (i = 0; i < geometry->u.group.geometry_count; ++i) { if (SUCCEEDED(ID2D1Geometry_GetBounds(geometry->u.group.src_geometries[i], transform, &rect))) d2d_rect_union(bounds, &rect); } return S_OK; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_GetWidenedBounds(ID2D1GeometryGroup *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_RECT_F *bounds) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, bounds %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, bounds); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_StrokeContainsPoint(ID2D1GeometryGroup *iface, D2D1_POINT_2F point, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, contains %p.\n", iface, debug_d2d_point_2f(&point), stroke_width, stroke_style, transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_FillContainsPoint(ID2D1GeometryGroup *iface, D2D1_POINT_2F point, const D2D1_MATRIX_3X2_F *transform, float tolerance, BOOL *contains) { FIXME("iface %p, point %s, transform %p, tolerance %.8e, contains %p stub!.\n", iface, debug_d2d_point_2f(&point), transform, tolerance, contains); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_CompareWithGeometry(ID2D1GeometryGroup *iface, ID2D1Geometry *geometry, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_GEOMETRY_RELATION *relation) { FIXME("iface %p, geometry %p, transform %p, tolerance %.8e, relation %p stub!\n", iface, geometry, transform, tolerance, relation); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_Simplify(ID2D1GeometryGroup *iface, D2D1_GEOMETRY_SIMPLIFICATION_OPTION option, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, option %#x, transform %p, tolerance %.8e, sink %p stub!.\n", iface, option, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_Tessellate(ID2D1GeometryGroup *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1TessellationSink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_CombineWithGeometry(ID2D1GeometryGroup *iface, ID2D1Geometry *geometry, D2D1_COMBINE_MODE combine_mode, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, geometry %p, combine_mode %#x, transform %p, tolerance %.8e, sink %p stub!\n", iface, geometry, combine_mode, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_Outline(ID2D1GeometryGroup *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, transform, tolerance, sink); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_ComputeArea(ID2D1GeometryGroup *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *area) { FIXME("iface %p, transform %p, tolerance %.8e, area %p stub!\n", iface, transform, tolerance, area); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_ComputeLength(ID2D1GeometryGroup *iface, const D2D1_MATRIX_3X2_F *transform, float tolerance, float *length) { FIXME("iface %p, transform %p, tolerance %.8e, length %p stub!\n", iface, transform, tolerance, length); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_ComputePointAtLength(ID2D1GeometryGroup *iface, float length, const D2D1_MATRIX_3X2_F *transform, float tolerance, D2D1_POINT_2F *point, D2D1_POINT_2F *tangent) { FIXME("iface %p, length %.8e, transform %p, tolerance %.8e, point %p, tangent %p stub!\n", iface, length, transform, tolerance, point, tangent); return E_NOTIMPL; } static HRESULT STDMETHODCALLTYPE d2d_geometry_group_Widen(ID2D1GeometryGroup *iface, float stroke_width, ID2D1StrokeStyle *stroke_style, const D2D1_MATRIX_3X2_F *transform, float tolerance, ID2D1SimplifiedGeometrySink *sink) { FIXME("iface %p, stroke_width %.8e, stroke_style %p, transform %p, tolerance %.8e, sink %p stub!\n", iface, stroke_width, stroke_style, transform, tolerance, sink); return E_NOTIMPL; } static D2D1_FILL_MODE STDMETHODCALLTYPE d2d_geometry_group_GetFillMode(ID2D1GeometryGroup *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); TRACE("iface %p.\n", iface); return geometry->u.group.fill_mode; } static UINT32 STDMETHODCALLTYPE d2d_geometry_group_GetSourceGeometryCount(ID2D1GeometryGroup *iface) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); TRACE("iface %p.\n", iface); return geometry->u.group.geometry_count; } static void STDMETHODCALLTYPE d2d_geometry_group_GetSourceGeometries(ID2D1GeometryGroup *iface, ID2D1Geometry **geometries, UINT32 geometry_count) { struct d2d_geometry *geometry = impl_from_ID2D1GeometryGroup(iface); unsigned int i; TRACE("iface %p, geometries %p, geometry_count %u.\n", iface, geometries, geometry_count); geometry_count = min(geometry_count, geometry->u.group.geometry_count); for (i = 0; i < geometry_count; ++i) ID2D1Geometry_AddRef(geometries[i] = geometry->u.group.src_geometries[i]); } static const struct ID2D1GeometryGroupVtbl d2d_geometry_group_vtbl = { d2d_geometry_group_QueryInterface, d2d_geometry_group_AddRef, d2d_geometry_group_Release, d2d_geometry_group_GetFactory, d2d_geometry_group_GetBounds, d2d_geometry_group_GetWidenedBounds, d2d_geometry_group_StrokeContainsPoint, d2d_geometry_group_FillContainsPoint, d2d_geometry_group_CompareWithGeometry, d2d_geometry_group_Simplify, d2d_geometry_group_Tessellate, d2d_geometry_group_CombineWithGeometry, d2d_geometry_group_Outline, d2d_geometry_group_ComputeArea, d2d_geometry_group_ComputeLength, d2d_geometry_group_ComputePointAtLength, d2d_geometry_group_Widen, d2d_geometry_group_GetFillMode, d2d_geometry_group_GetSourceGeometryCount, d2d_geometry_group_GetSourceGeometries, }; HRESULT d2d_geometry_group_init(struct d2d_geometry *geometry, ID2D1Factory *factory, D2D1_FILL_MODE fill_mode, ID2D1Geometry **geometries, unsigned int geometry_count) { unsigned int i; d2d_geometry_init(geometry, factory, &identity, (ID2D1GeometryVtbl *)&d2d_geometry_group_vtbl); if (!(geometry->u.group.src_geometries = heap_calloc(geometry_count, sizeof(*geometries)))) { d2d_geometry_cleanup(geometry); return E_OUTOFMEMORY; } for (i = 0; i < geometry_count; ++i) { ID2D1Geometry_AddRef(geometry->u.group.src_geometries[i] = geometries[i]); } geometry->u.group.geometry_count = geometry_count; geometry->u.group.fill_mode = fill_mode; return S_OK; } struct d2d_geometry *unsafe_impl_from_ID2D1Geometry(ID2D1Geometry *iface) { if (!iface) return NULL; assert(iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_ellipse_geometry_vtbl || iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_path_geometry_vtbl || iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_rectangle_geometry_vtbl || iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_rounded_rectangle_geometry_vtbl || iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_transformed_geometry_vtbl || iface->lpVtbl == (const ID2D1GeometryVtbl *)&d2d_geometry_group_vtbl); return CONTAINING_RECORD(iface, struct d2d_geometry, ID2D1Geometry_iface); }