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LIVE / compute_distance.h
Xu Ma
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#pragma once
#include "diffvg.h"
#include "edge_query.h"
#include "scene.h"
#include "shape.h"
#include "solve.h"
#include "vector.h"
#include <cassert>
struct ClosestPointPathInfo {
 int base_point_id;
 int point_id;
 float t_root;
};
DEVICE
inline
bool closest_point(const Circle &circle, const Vector2f &pt,
 Vector2f *result) {
 *result = circle.center + circle.radius * normalize(pt - circle.center);
 return false;
}
DEVICE
inline
bool closest_point(const Path &path, const BVHNode *bvh_nodes, const Vector2f &pt, float max_radius,
 ClosestPointPathInfo *path_info,
 Vector2f *result) {
 auto min_dist = max_radius;
 auto ret_pt = Vector2f{0, 0};
 auto found = false;
 auto num_segments = path.num_base_points;
 constexpr auto max_bvh_size = 128;
 int bvh_stack[max_bvh_size];
 auto stack_size = 0;
 bvh_stack[stack_size++] = 2 * num_segments - 2;
 while (stack_size > 0) {
 const BVHNode &node = bvh_nodes[bvh_stack[--stack_size]];
 if (node.child1 < 0) {
 // leaf
 auto base_point_id = node.child0;
 auto point_id = - node.child1 - 1;
 assert(base_point_id < num_segments);
 assert(point_id < path.num_points);
 auto dist = 0.f;
 auto closest_pt = Vector2f{0, 0};
 auto t_root = 0.f;
 if (path.num_control_points[base_point_id] == 0) {
 // Straight line
 auto i0 = point_id;
 auto i1 = (point_id + 1) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 // project pt to line
 auto t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0);
 if (t < 0) {
 dist = distance(p0, pt);
 closest_pt = p0;
 t_root = 0;
 } else if (t > 1) {
 dist = distance(p1, pt);
 closest_pt = p1;
 t_root = 1;
 } else {
 dist = distance(p0 + t * (p1 - p0), pt);
 closest_pt = p0 + t * (p1 - p0);
 t_root = t;
 }
 } else if (path.num_control_points[base_point_id] == 1) {
 // Quadratic Bezier curve
 auto i0 = point_id;
 auto i1 = point_id + 1;
 auto i2 = (point_id + 2) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 auto p2 = Vector2f{path.points[2 * i2], path.points[2 * i2 + 1]};
 if (path.use_distance_approx) {
 closest_pt = quadratic_closest_pt_approx(p0, p1, p2, pt, &t_root);
 dist = distance(closest_pt, pt);
 } else {
 auto eval = [&](float t) -> Vector2f {
 auto tt = 1 - t;
 return (tt*tt)*p0 + (2*tt*t)*p1 + (t*t)*p2;
 };
 auto pt0 = eval(0);
 auto pt1 = eval(1);
 auto dist0 = distance(pt0, pt);
 auto dist1 = distance(pt1, pt);
 {
 dist = dist0;
 closest_pt = pt0;
 t_root = 0;
 }
 if (dist1 < dist) {
 dist = dist1;
 closest_pt = pt1;
 t_root = 1;
 }
 // The curve is (1-t)^2p0 + 2(1-t)tp1 + t^2p2
 // = (p0-2p1+p2)t^2+(-2p0+2p1)t+p0 = q
 // Want to solve (q - pt) dot q' = 0
 // q' = (p0-2p1+p2)t + (-p0+p1)
 // Expanding (p0-2p1+p2)^2 t^3 +
 // 3(p0-2p1+p2)(-p0+p1) t^2 +
 // (2(-p0+p1)^2+(p0-2p1+p2)(p0-pt))t +
 // (-p0+p1)(p0-pt) = 0
 auto A = sum((p0-2*p1+p2)*(p0-2*p1+p2));
 auto B = sum(3*(p0-2*p1+p2)*(-p0+p1));
 auto C = sum(2*(-p0+p1)*(-p0+p1)+(p0-2*p1+p2)*(p0-pt));
 auto D = sum((-p0+p1)*(p0-pt));
 float t[3];
 int num_sol = solve_cubic(A, B, C, D, t);
 for (int j = 0; j < num_sol; j++) {
 if (t[j] >= 0 && t[j] <= 1) {
 auto p = eval(t[j]);
 auto distp = distance(p, pt);
 if (distp < dist) {
 dist = distp;
 closest_pt = p;
 t_root = t[j];
 }
 }
 }
 }
 } else if (path.num_control_points[base_point_id] == 2) {
 // Cubic Bezier curve
 auto i0 = point_id;
 auto i1 = point_id + 1;
 auto i2 = point_id + 2;
 auto i3 = (point_id + 3) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 auto p2 = Vector2f{path.points[2 * i2], path.points[2 * i2 + 1]};
 auto p3 = Vector2f{path.points[2 * i3], path.points[2 * i3 + 1]};
 auto eval = [&](float t) -> Vector2f {
 auto tt = 1 - t;
 return (tt*tt*tt)*p0 + (3*tt*tt*t)*p1 + (3*tt*t*t)*p2 + (t*t*t)*p3;
 };
 auto pt0 = eval(0);
 auto pt1 = eval(1);
 auto dist0 = distance(pt0, pt);
 auto dist1 = distance(pt1, pt);
 {
 dist = dist0;
 closest_pt = pt0;
 t_root = 0;
 }
 if (dist1 < dist) {
 dist = dist1;
 closest_pt = pt1;
 t_root = 1;
 }
 // The curve is (1 - t)^3 p0 + 3 * (1 - t)^2 t p1 + 3 * (1 - t) t^2 p2 + t^3 p3
 // = (-p0+3p1-3p2+p3) t^3 + (3p0-6p1+3p2) t^2 + (-3p0+3p1) t + p0
 // Want to solve (q - pt) dot q' = 0
 // q' = 3*(-p0+3p1-3p2+p3)t^2 + 2*(3p0-6p1+3p2)t + (-3p0+3p1)
 // Expanding
// 3*(-p0+3p1-3p2+p3)^2 t^5
 // 5*(-p0+3p1-3p2+p3)(3p0-6p1+3p2) t^4
 // 4*(-p0+3p1-3p2+p3)(-3p0+3p1) + 2*(3p0-6p1+3p2)^2 t^3
 // 3*(3p0-6p1+3p2)(-3p0+3p1) + 3*(-p0+3p1-3p2+p3)(p0-pt) t^2
 // (-3p0+3p1)^2+2(p0-pt)(3p0-6p1+3p2) t
 // (p0-pt)(-3p0+3p1)
 double A = 3*sum((-p0+3*p1-3*p2+p3)*(-p0+3*p1-3*p2+p3));
 double B = 5*sum((-p0+3*p1-3*p2+p3)*(3*p0-6*p1+3*p2));
 double C = 4*sum((-p0+3*p1-3*p2+p3)*(-3*p0+3*p1)) + 2*sum((3*p0-6*p1+3*p2)*(3*p0-6*p1+3*p2));
 double D = 3*(sum((3*p0-6*p1+3*p2)*(-3*p0+3*p1)) + sum((-p0+3*p1-3*p2+p3)*(p0-pt)));
 double E = sum((-3*p0+3*p1)*(-3*p0+3*p1)) + 2*sum((p0-pt)*(3*p0-6*p1+3*p2));
 double F = sum((p0-pt)*(-3*p0+3*p1));
 // normalize the polynomial
 B /= A;
 C /= A;
 D /= A;
 E /= A;
 F /= A;
 // Isolator Polynomials:
 // https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.133.2233&rep=rep1&type=pdf
 // x/5 + B/25
 // /-----------------------------------------------------
 // 5x^4 + 4B x^3 + 3C x^2 + 2D x + E / x^5 + B x^4 + C x^3 + D x^2 + E x + F
 // x^5 + 4B/5 x^4 + 3C/5 x^3 + 2D/5 x^2 + E/5 x
 // ----------------------------------------------------
 // B/5 x^4 + 2C/5 x^3 + 3D/5 x^2 + 4E/5 x + F
 // B/5 x^4 + 4B^2/25 x^3 + 3BC/25 x^2 + 2BD/25 x + BE/25
 // ----------------------------------------------------
 // (2C/5 - 4B^2/25)x^3 + (3D/5-3BC/25)x^2 + (4E/5-2BD/25) + (F-BE/25)
 auto p1A = ((2 / 5.f) * C - (4 / 25.f) * B * B);
 auto p1B = ((3 / 5.f) * D - (3 / 25.f) * B * C);
 auto p1C = ((4 / 5.f) * E - (2 / 25.f) * B * D);
 auto p1D = F - B * E / 25.f;
 // auto q1A = 1 / 5.f;
 // auto q1B = B / 25.f;
 // x/5 + B/25 = 0
 // x = -B/5
 auto q_root = -B/5.f;
 double p_roots[3];
 int num_sol = solve_cubic(p1A, p1B, p1C, p1D, p_roots);
 float intervals[4];
 if (q_root >= 0 && q_root <= 1) {
 intervals[0] = q_root;
 }
 for (int j = 0; j < num_sol; j++) {
 intervals[j + 1] = p_roots[j];
 }
 auto num_intervals = 1 + num_sol;
 // sort intervals
 for (int j = 1; j < num_intervals; j++) {
 for (int k = j; k > 0 && intervals[k - 1] > intervals[k]; k--) {
 auto tmp = intervals[k];
 intervals[k] = intervals[k - 1];
 intervals[k - 1] = tmp;
 }
 }
 auto eval_polynomial = [&] (double t) {
 return t*t*t*t*t+
 B*t*t*t*t+
 C*t*t*t+
 D*t*t+
 E*t+
 F;
 };
 auto eval_polynomial_deriv = [&] (double t) {
 return 5*t*t*t*t+
 4*B*t*t*t+
 3*C*t*t+
 2*D*t+
 E;
 };
 auto lower_bound = 0.f;
 for (int j = 0; j < num_intervals + 1; j++) {
 if (j < num_intervals && intervals[j] < 0.f) {
 continue;
 }
 auto upper_bound = j < num_intervals ?
 min(intervals[j], 1.f) : 1.f;
 auto lb = lower_bound;
 auto ub = upper_bound;
 auto lb_eval = eval_polynomial(lb);
 auto ub_eval = eval_polynomial(ub);
 if (lb_eval * ub_eval > 0) {
 // Doesn't have root
 continue;
 }
 if (lb_eval > ub_eval) {
 swap_(lb, ub);
 }
 auto t = 0.5f * (lb + ub);
 auto num_iter = 20;
 for (int it = 0; it < num_iter; it++) {
 if (!(t >= lb && t <= ub)) {
 t = 0.5f * (lb + ub);
 }
 auto value = eval_polynomial(t);
 if (fabs(value) < 1e-5f || it == num_iter - 1) {
 break;
 }
 // The derivative may not be entirely accurate,
 // but the bisection is going to handle this
 if (value > 0.f) {
 ub = t;
 } else {
 lb = t;
 }
 auto derivative = eval_polynomial_deriv(t);
 t -= value / derivative;
 }
 auto p = eval(t);
 auto distp = distance(p, pt);
 if (distp < dist) {
 dist = distp;
 closest_pt = p;
 t_root = t;
 }
 if (upper_bound >= 1.f) {
 break;
 }
 lower_bound = upper_bound;
 }
 } else {
 assert(false);
 }
 if (dist < min_dist) {
 min_dist = dist;
 ret_pt = closest_pt;
 path_info->base_point_id = base_point_id;
 path_info->point_id = point_id;
 path_info->t_root = t_root;
 found = true;
 }
 } else {
 assert(node.child0 >= 0 && node.child1 >= 0);
 const AABB &b0 = bvh_nodes[node.child0].box;
 if (within_distance(b0, pt, min_dist)) {
 bvh_stack[stack_size++] = node.child0;
 }
 const AABB &b1 = bvh_nodes[node.child1].box;
 if (within_distance(b1, pt, min_dist)) {
 bvh_stack[stack_size++] = node.child1;
 }
 assert(stack_size <= max_bvh_size);
 }
 }
 if (found) {
 assert(path_info->base_point_id < num_segments);
 }
 *result = ret_pt;
 return found;
}
DEVICE
inline
bool closest_point(const Rect &rect, const Vector2f &pt,
 Vector2f *result) {
 auto min_dist = 0.f;
 auto closest_pt = Vector2f{0, 0};
 auto update = [&](const Vector2f &p0, const Vector2f &p1, bool first) {
 // project pt to line
 auto t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0);
 if (t < 0) {
 auto d = distance(p0, pt);
 if (first || d < min_dist) {
 min_dist = d;
 closest_pt = p0;
 }
 } else if (t > 1) {
 auto d = distance(p1, pt);
 if (first || d < min_dist) {
 min_dist = d;
 closest_pt = p1;
 }
 } else {
 auto p = p0 + t * (p1 - p0);
 auto d = distance(p, pt);
 if (first || d < min_dist) {
 min_dist = d;
 closest_pt = p0;
 }
 }
 };
 auto left_top = rect.p_min;
 auto right_top = Vector2f{rect.p_max.x, rect.p_min.y};
 auto left_bottom = Vector2f{rect.p_min.x, rect.p_max.y};
 auto right_bottom = rect.p_max;
 update(left_top, left_bottom, true);
 update(left_top, right_top, false);
 update(right_top, right_bottom, false);
 update(left_bottom, right_bottom, false);
 *result = closest_pt;
 return true;
}
DEVICE
inline
bool closest_point(const Shape &shape, const BVHNode *bvh_nodes, const Vector2f &pt, float max_radius,
 ClosestPointPathInfo *path_info,
 Vector2f *result) {
 switch (shape.type) {
 case ShapeType::Circle:
 return closest_point(*(const Circle *)shape.ptr, pt, result);
 case ShapeType::Ellipse:
 // https://www.geometrictools.com/Documentation/DistancePointEllipseEllipsoid.pdf
 assert(false);
 return false;
 case ShapeType::Path:
 return closest_point(*(const Path *)shape.ptr, bvh_nodes, pt, max_radius, path_info, result);
 case ShapeType::Rect:
 return closest_point(*(const Rect *)shape.ptr, pt, result);
 }
 assert(false);
 return false;
}
DEVICE
inline
bool compute_distance(const SceneData &scene,
 int shape_group_id,
 const Vector2f &pt,
 float max_radius,
 int *min_shape_id,
 Vector2f *closest_pt_,
 ClosestPointPathInfo *path_info,
 float *result) {
 const ShapeGroup &shape_group = scene.shape_groups[shape_group_id];
 // pt is in canvas space, transform it to shape's local space
 auto local_pt = xform_pt(shape_group.canvas_to_shape, pt);
constexpr auto max_bvh_stack_size = 64;
 int bvh_stack[max_bvh_stack_size];
 auto stack_size = 0;
 bvh_stack[stack_size++] = 2 * shape_group.num_shapes - 2;
 const auto &bvh_nodes = scene.shape_groups_bvh_nodes[shape_group_id];
auto min_dist = max_radius;
 auto found = false;
while (stack_size > 0) {
 const BVHNode &node = bvh_nodes[bvh_stack[--stack_size]];
 if (node.child1 < 0) {
 // leaf
 auto shape_id = node.child0;
 const auto &shape = scene.shapes[shape_id];
 ClosestPointPathInfo local_path_info{-1, -1};
 auto local_closest_pt = Vector2f{0, 0};
 if (closest_point(shape, scene.path_bvhs[shape_id], local_pt, max_radius, &local_path_info, &local_closest_pt)) {
 auto closest_pt = xform_pt(shape_group.shape_to_canvas, local_closest_pt);
 auto dist = distance(closest_pt, pt);
 if (!found || dist < min_dist) {
 found = true;
 min_dist = dist;
 if (min_shape_id != nullptr) {
 *min_shape_id = shape_id;
 }
 if (closest_pt_ != nullptr) {
 *closest_pt_ = closest_pt;
 }
 if (path_info != nullptr) {
 *path_info = local_path_info;
 }
 }
 }
 } else {
 assert(node.child0 >= 0 && node.child1 >= 0);
 const AABB &b0 = bvh_nodes[node.child0].box;
 if (inside(b0, local_pt, max_radius)) {
 bvh_stack[stack_size++] = node.child0;
 }
 const AABB &b1 = bvh_nodes[node.child1].box;
 if (inside(b1, local_pt, max_radius)) {
 bvh_stack[stack_size++] = node.child1;
 }
 assert(stack_size <= max_bvh_stack_size);
 }
 }
*result = min_dist;
 return found;
}
DEVICE
inline
void d_closest_point(const Circle &circle,
 const Vector2f &pt,
 const Vector2f &d_closest_pt,
 Circle &d_circle,
 Vector2f &d_pt) {
 // return circle.center + circle.radius * normalize(pt - circle.center);
 auto d_center = d_closest_pt *
 (1 + d_normalize(pt - circle.center, circle.radius * d_closest_pt));
 atomic_add(&d_circle.center.x, d_center);
 atomic_add(&d_circle.radius, dot(d_closest_pt, normalize(pt - circle.center)));
}
DEVICE
inline
void d_closest_point(const Path &path,
 const Vector2f &pt,
 const Vector2f &d_closest_pt,
 const ClosestPointPathInfo &path_info,
 Path &d_path,
 Vector2f &d_pt) {
 auto base_point_id = path_info.base_point_id;
 auto point_id = path_info.point_id;
 auto min_t_root = path_info.t_root;
if (path.num_control_points[base_point_id] == 0) {
 // Straight line
 auto i0 = point_id;
 auto i1 = (point_id + 1) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 // project pt to line
 auto t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0);
 auto d_p0 = Vector2f{0, 0};
 auto d_p1 = Vector2f{0, 0};
 if (t < 0) {
 d_p0 += d_closest_pt;
 } else if (t > 1) {
 d_p1 += d_closest_pt;
 } else {
 auto d_p = d_closest_pt;
 // p = p0 + t * (p1 - p0)
 d_p0 += d_p * (1 - t);
 d_p1 += d_p * t;
 }
 atomic_add(d_path.points + 2 * i0, d_p0);
 atomic_add(d_path.points + 2 * i1, d_p1);
 } else if (path.num_control_points[base_point_id] == 1) {
 // Quadratic Bezier curve
 auto i0 = point_id;
 auto i1 = point_id + 1;
 auto i2 = (point_id + 2) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 auto p2 = Vector2f{path.points[2 * i2], path.points[2 * i2 + 1]};
 // auto eval = [&](float t) -> Vector2f {
 // auto tt = 1 - t;
 // return (tt*tt)*p0 + (2*tt*t)*p1 + (t*t)*p2;
 // };
 // auto dist0 = distance(eval(0), pt);
 // auto dist1 = distance(eval(1), pt);
 auto d_p0 = Vector2f{0, 0};
 auto d_p1 = Vector2f{0, 0};
 auto d_p2 = Vector2f{0, 0};
 auto t = min_t_root;
 if (t == 0) {
 d_p0 += d_closest_pt;
 } else if (t == 1) {
 d_p2 += d_closest_pt;
 } else {
 // The curve is (1-t)^2p0 + 2(1-t)tp1 + t^2p2
 // = (p0-2p1+p2)t^2+(-2p0+2p1)t+p0 = q
 // Want to solve (q - pt) dot q' = 0
 // q' = (p0-2p1+p2)t + (-p0+p1)
 // Expanding (p0-2p1+p2)^2 t^3 +
 // 3(p0-2p1+p2)(-p0+p1) t^2 +
 // (2(-p0+p1)^2+(p0-2p1+p2)(p0-pt))t +
 // (-p0+p1)(p0-pt) = 0
 auto A = sum((p0-2*p1+p2)*(p0-2*p1+p2));
 auto B = sum(3*(p0-2*p1+p2)*(-p0+p1));
 auto C = sum(2*(-p0+p1)*(-p0+p1)+(p0-2*p1+p2)*(p0-pt));
 // auto D = sum((-p0+p1)*(p0-pt));
 auto d_p = d_closest_pt;
 // p = eval(t)
 auto tt = 1 - t;
 // (tt*tt)*p0 + (2*tt*t)*p1 + (t*t)*p2
 auto d_tt = 2 * tt * dot(d_p, p0) + 2 * t * dot(d_p, p1);
 auto d_t = -d_tt + 2 * tt * dot(d_p, p1) + 2 * t * dot(d_p, p2);
 auto d_p0 = d_p * tt * tt;
 auto d_p1 = 2 * d_p * tt * t;
 auto d_p2 = d_p * t * t;
 // implicit function theorem: dt/dA = -1/(p'(t)) * dp/dA
 auto poly_deriv_t = 3 * A * t * t + 2 * B * t + C;
 if (fabs(poly_deriv_t) > 1e-6f) {
 auto d_A = - (d_t / poly_deriv_t) * t * t * t;
 auto d_B = - (d_t / poly_deriv_t) * t * t;
 auto d_C = - (d_t / poly_deriv_t) * t;
 auto d_D = - (d_t / poly_deriv_t);
 // A = sum((p0-2*p1+p2)*(p0-2*p1+p2))
 // B = sum(3*(p0-2*p1+p2)*(-p0+p1))
 // C = sum(2*(-p0+p1)*(-p0+p1)+(p0-2*p1+p2)*(p0-pt))
 // D = sum((-p0+p1)*(p0-pt))
 d_p0 += 2*d_A*(p0-2*p1+p2)+
 3*d_B*((-p0+p1)-(p0-2*p1+p2))+
 2*d_C*(-2*(-p0+p1))+
 d_C*((p0-pt)+(p0-2*p1+p2))+
 2*d_D*(-(p0-pt)+(-p0+p1));
 d_p1 += (-2)*2*d_A*(p0-2*p1+p2)+
 3*d_B*(-2*(-p0+p1)+(p0-2*p1+p2))+
 2*d_C*(2*(-p0+p1))+
 d_C*((-2)*(p0-pt))+
 d_D*(p0-pt);
 d_p2 += 2*d_A*(p0-2*p1+p2)+
 3*d_B*(-p0+p1)+
 d_C*(p0-pt);
 d_pt += d_C*(-(p0-2*p1+p2))+
 d_D*(-(-p0+p1));
 }
 }
 atomic_add(d_path.points + 2 * i0, d_p0);
 atomic_add(d_path.points + 2 * i1, d_p1);
 atomic_add(d_path.points + 2 * i2, d_p2);
 } else if (path.num_control_points[base_point_id] == 2) {
 // Cubic Bezier curve
 auto i0 = point_id;
 auto i1 = point_id + 1;
 auto i2 = point_id + 2;
 auto i3 = (point_id + 3) % path.num_points;
 auto p0 = Vector2f{path.points[2 * i0], path.points[2 * i0 + 1]};
 auto p1 = Vector2f{path.points[2 * i1], path.points[2 * i1 + 1]};
 auto p2 = Vector2f{path.points[2 * i2], path.points[2 * i2 + 1]};
 auto p3 = Vector2f{path.points[2 * i3], path.points[2 * i3 + 1]};
 // auto eval = [&](float t) -> Vector2f {
 // auto tt = 1 - t;
 // return (tt*tt*tt)*p0 + (3*tt*tt*t)*p1 + (3*tt*t*t)*p2 + (t*t*t)*p3;
 // };
 auto d_p0 = Vector2f{0, 0};
 auto d_p1 = Vector2f{0, 0};
 auto d_p2 = Vector2f{0, 0};
 auto d_p3 = Vector2f{0, 0};
 auto t = min_t_root;
 if (t == 0) {
 // closest_pt = p0
 d_p0 += d_closest_pt;
 } else if (t == 1) {
 // closest_pt = p1
 d_p3 += d_closest_pt;
 } else {
 // The curve is (1 - t)^3 p0 + 3 * (1 - t)^2 t p1 + 3 * (1 - t) t^2 p2 + t^3 p3
 // = (-p0+3p1-3p2+p3) t^3 + (3p0-6p1+3p2) t^2 + (-3p0+3p1) t + p0
 // Want to solve (q - pt) dot q' = 0
 // q' = 3*(-p0+3p1-3p2+p3)t^2 + 2*(3p0-6p1+3p2)t + (-3p0+3p1)
 // Expanding
// 3*(-p0+3p1-3p2+p3)^2 t^5
 // 5*(-p0+3p1-3p2+p3)(3p0-6p1+3p2) t^4
 // 4*(-p0+3p1-3p2+p3)(-3p0+3p1) + 2*(3p0-6p1+3p2)^2 t^3
 // 3*(3p0-6p1+3p2)(-3p0+3p1) + 3*(-p0+3p1-3p2+p3)(p0-pt) t^2
 // (-3p0+3p1)^2+2(p0-pt)(3p0-6p1+3p2) t
 // (p0-pt)(-3p0+3p1)
 double A = 3*sum((-p0+3*p1-3*p2+p3)*(-p0+3*p1-3*p2+p3));
 double B = 5*sum((-p0+3*p1-3*p2+p3)*(3*p0-6*p1+3*p2));
 double C = 4*sum((-p0+3*p1-3*p2+p3)*(-3*p0+3*p1)) + 2*sum((3*p0-6*p1+3*p2)*(3*p0-6*p1+3*p2));
 double D = 3*(sum((3*p0-6*p1+3*p2)*(-3*p0+3*p1)) + sum((-p0+3*p1-3*p2+p3)*(p0-pt)));
 double E = sum((-3*p0+3*p1)*(-3*p0+3*p1)) + 2*sum((p0-pt)*(3*p0-6*p1+3*p2));
 double F = sum((p0-pt)*(-3*p0+3*p1));
 B /= A;
 C /= A;
 D /= A;
 E /= A;
 F /= A;
 // auto eval_polynomial = [&] (double t) {
 // return t*t*t*t*t+
 // B*t*t*t*t+
 // C*t*t*t+
 // D*t*t+
 // E*t+
 // F;
 // };
 auto eval_polynomial_deriv = [&] (double t) {
 return 5*t*t*t*t+
 4*B*t*t*t+
 3*C*t*t+
 2*D*t+
 E;
 };
// auto p = eval(t);
 auto d_p = d_closest_pt;
 // (tt*tt*tt)*p0 + (3*tt*tt*t)*p1 + (3*tt*t*t)*p2 + (t*t*t)*p3
 auto tt = 1 - t;
 auto d_tt = 3 * tt * tt * dot(d_p, p0) +
 6 * tt * t * dot(d_p, p1) +
 3 * t * t * dot(d_p, p2);
 auto d_t = -d_tt +
 3 * tt * tt * dot(d_p, p1) +
 6 * tt * t * dot(d_p, p2) +
 3 * t * t * dot(d_p, p3);
 d_p0 += d_p * (tt * tt * tt);
 d_p1 += d_p * (3 * tt * tt * t);
 d_p2 += d_p * (3 * tt * t * t);
 d_p3 += d_p * (t * t * t);
 // implicit function theorem: dt/dA = -1/(p'(t)) * dp/dA
 auto poly_deriv_t = eval_polynomial_deriv(t);
 if (fabs(poly_deriv_t) > 1e-10f) {
 auto d_B = -(d_t / poly_deriv_t) * t * t * t * t;
 auto d_C = -(d_t / poly_deriv_t) * t * t * t;
 auto d_D = -(d_t / poly_deriv_t) * t * t;
 auto d_E = -(d_t / poly_deriv_t) * t;
 auto d_F = -(d_t / poly_deriv_t);
 // B = B' / A
 // C = C' / A
 // D = D' / A
 // E = E' / A
 // F = F' / A
 auto d_A = -d_B * B / A
 -d_C * C / A
 -d_D * D / A
 -d_E * E / A
 -d_F * F / A;
 d_B /= A;
 d_C /= A;
 d_D /= A;
 d_E /= A;
 d_F /= A;
 {
 double A = 3*sum((-p0+3*p1-3*p2+p3)*(-p0+3*p1-3*p2+p3)) + 1e-3;
 double B = 5*sum((-p0+3*p1-3*p2+p3)*(3*p0-6*p1+3*p2));
 double C = 4*sum((-p0+3*p1-3*p2+p3)*(-3*p0+3*p1)) + 2*sum((3*p0-6*p1+3*p2)*(3*p0-6*p1+3*p2));
 double D = 3*(sum((3*p0-6*p1+3*p2)*(-3*p0+3*p1)) + sum((-p0+3*p1-3*p2+p3)*(p0-pt)));
 double E = sum((-3*p0+3*p1)*(-3*p0+3*p1)) + 2*sum((p0-pt)*(3*p0-6*p1+3*p2));
 double F = sum((p0-pt)*(-3*p0+3*p1));
 B /= A;
 C /= A;
 D /= A;
 E /= A;
 F /= A;
 auto eval_polynomial = [&] (double t) {
 return t*t*t*t*t+
 B*t*t*t*t+
 C*t*t*t+
 D*t*t+
 E*t+
 F;
 };
 auto eval_polynomial_deriv = [&] (double t) {
 return 5*t*t*t*t+
 4*B*t*t*t+
 3*C*t*t+
 2*D*t+
 E;
 };
 auto lb = t - 1e-2f;
 auto ub = t + 1e-2f;
 auto lb_eval = eval_polynomial(lb);
 auto ub_eval = eval_polynomial(ub);
 if (lb_eval > ub_eval) {
 swap_(lb, ub);
 }
 auto t_ = 0.5f * (lb + ub);
 auto num_iter = 20;
 for (int it = 0; it < num_iter; it++) {
 if (!(t_ >= lb && t_ <= ub)) {
 t_ = 0.5f * (lb + ub);
 }
 auto value = eval_polynomial(t_);
 if (fabs(value) < 1e-5f || it == num_iter - 1) {
 break;
 }
 // The derivative may not be entirely accurate,
 // but the bisection is going to handle this
 if (value > 0.f) {
 ub = t_;
 } else {
 lb = t_;
 }
 auto derivative = eval_polynomial_deriv(t);
 t_ -= value / derivative;
 }
 }
 // A = 3*sum((-p0+3*p1-3*p2+p3)*(-p0+3*p1-3*p2+p3))
 d_p0 += d_A * 3 * (-1) * 2 * (-p0+3*p1-3*p2+p3);
 d_p1 += d_A * 3 * 3 * 2 * (-p0+3*p1-3*p2+p3);
 d_p2 += d_A * 3 * (-3) * 2 * (-p0+3*p1-3*p2+p3);
 d_p3 += d_A * 3 * 1 * 2 * (-p0+3*p1-3*p2+p3);
 // B = 5*sum((-p0+3*p1-3*p2+p3)*(3*p0-6*p1+3*p2))
 d_p0 += d_B * 5 * ((-1) * (3*p0-6*p1+3*p2) + 3 * (-p0+3*p1-3*p2+p3));
 d_p1 += d_B * 5 * (3 * (3*p0-6*p1+3*p2) + (-6) * (-p0+3*p1-3*p2+p3));
 d_p2 += d_B * 5 * ((-3) * (3*p0-6*p1+3*p2) + 3 * (-p0+3*p1-3*p2+p3));
 d_p3 += d_B * 5 * (3*p0-6*p1+3*p2);
 // C = 4*sum((-p0+3*p1-3*p2+p3)*(-3*p0+3*p1)) + 2*sum((3*p0-6*p1+3*p2)*(3*p0-6*p1+3*p2))
 d_p0 += d_C * 4 * ((-1) * (-3*p0+3*p1) + (-3) * (-p0+3*p1-3*p2+p3)) +
 d_C * 2 * (3 * 2 * (3*p0-6*p1+3*p2));
 d_p1 += d_C * 4 * (3 * (-3*p0+3*p1) + 3 * (-p0+3*p1-3*p2+p3)) +
 d_C * 2 * ((-6) * 2 * (3*p0-6*p1+3*p2));
 d_p2 += d_C * 4 * ((-3) * (-3*p0+3*p1)) +
 d_C * 2 * (3 * 2 * (3*p0-6*p1+3*p2));
 d_p3 += d_C * 4 * (-3*p0+3*p1);
 // D = 3*(sum((3*p0-6*p1+3*p2)*(-3*p0+3*p1)) + sum((-p0+3*p1-3*p2+p3)*(p0-pt)))
 d_p0 += d_D * 3 * (3 * (-3*p0+3*p1) + (-3) * (3*p0-6*p1+3*p2)) +
 d_D * 3 * ((-1) * (p0-pt) + 1 * (-p0+3*p1-3*p2+p3));
 d_p1 += d_D * 3 * ((-6) * (-3*p0+3*p1) + (3) * (3*p0-6*p1+3*p2)) +
 d_D * 3 * (3 * (p0-pt));
 d_p2 += d_D * 3 * (3 * (-3*p0+3*p1)) +
 d_D * 3 * ((-3) * (p0-pt));
 d_pt += d_D * 3 * ((-1) * (-p0+3*p1-3*p2+p3));
 // E = sum((-3*p0+3*p1)*(-3*p0+3*p1)) + 2*sum((p0-pt)*(3*p0-6*p1+3*p2))
 d_p0 += d_E * ((-3) * 2 * (-3*p0+3*p1)) +
 d_E * 2 * (1 * (3*p0-6*p1+3*p2) + 3 * (p0-pt));
 d_p1 += d_E * ( 3 * 2 * (-3*p0+3*p1)) +
 d_E * 2 * ((-6) * (p0-pt));
 d_p2 += d_E * 2 * ( 3 * (p0-pt));
 d_pt += d_E * 2 * ((-1) * (3*p0-6*p1+3*p2));
 // F = sum((p0-pt)*(-3*p0+3*p1))
 d_p0 += d_F * (1 * (-3*p0+3*p1)) +
 d_F * ((-3) * (p0-pt));
 d_p1 += d_F * (3 * (p0-pt));
 d_pt += d_F * ((-1) * (-3*p0+3*p1));
 }
 }
 atomic_add(d_path.points + 2 * i0, d_p0);
 atomic_add(d_path.points + 2 * i1, d_p1);
 atomic_add(d_path.points + 2 * i2, d_p2);
 atomic_add(d_path.points + 2 * i3, d_p3);
 } else {
 assert(false);
 }
}
DEVICE
inline
void d_closest_point(const Rect &rect,
 const Vector2f &pt,
 const Vector2f &d_closest_pt,
 Rect &d_rect,
 Vector2f &d_pt) {
 auto dist = [&](const Vector2f &p0, const Vector2f &p1) -> float {
 // project pt to line
 auto t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0);
 if (t < 0) {
 return distance(p0, pt);
 } else if (t > 1) {
 return distance(p1, pt);
 } else {
 return distance(p0 + t * (p1 - p0), pt);
 }
 // return 0;
 };
 auto left_top = rect.p_min;
 auto right_top = Vector2f{rect.p_max.x, rect.p_min.y};
 auto left_bottom = Vector2f{rect.p_min.x, rect.p_max.y};
 auto right_bottom = rect.p_max;
 auto left_dist = dist(left_top, left_bottom);
 auto top_dist = dist(left_top, right_top);
 auto right_dist = dist(right_top, right_bottom);
 auto bottom_dist = dist(left_bottom, right_bottom);
 int min_id = 0;
 auto min_dist = left_dist;
 if (top_dist < min_dist) { min_dist = top_dist; min_id = 1; }
 if (right_dist < min_dist) { min_dist = right_dist; min_id = 2; }
 if (bottom_dist < min_dist) { min_dist = bottom_dist; min_id = 3; }
auto d_update = [&](const Vector2f &p0, const Vector2f &p1,
 const Vector2f &d_closest_pt,
 Vector2f &d_p0, Vector2f &d_p1) {
 // project pt to line
 auto t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0);
 if (t < 0) {
 d_p0 += d_closest_pt;
 } else if (t > 1) {
 d_p1 += d_closest_pt;
 } else {
 // p = p0 + t * (p1 - p0)
 auto d_p = d_closest_pt;
 d_p0 += d_p * (1 - t);
 d_p1 += d_p * t;
 auto d_t = sum(d_p * (p1 - p0));
 // t = dot(pt - p0, p1 - p0) / dot(p1 - p0, p1 - p0)
 auto d_numerator = d_t / dot(p1 - p0, p1 - p0);
 auto d_denominator = d_t * (-t) / dot(p1 - p0, p1 - p0);
 // numerator = dot(pt - p0, p1 - p0)
 d_pt += (p1 - p0) * d_numerator;
 d_p1 += (pt - p0) * d_numerator;
 d_p0 += ((p0 - p1) + (p0 - pt)) * d_numerator;
 // denominator = dot(p1 - p0, p1 - p0)
 d_p1 += 2 * (p1 - p0) * d_denominator;
 d_p0 += 2 * (p0 - p1) * d_denominator;
 }
 };
 auto d_left_top = Vector2f{0, 0};
 auto d_right_top = Vector2f{0, 0};
 auto d_left_bottom = Vector2f{0, 0};
 auto d_right_bottom = Vector2f{0, 0};
 if (min_id == 0) {
 d_update(left_top, left_bottom, d_closest_pt, d_left_top, d_left_bottom);
 } else if (min_id == 1) {
 d_update(left_top, right_top, d_closest_pt, d_left_top, d_right_top);
 } else if (min_id == 2) {
 d_update(right_top, right_bottom, d_closest_pt, d_right_top, d_right_bottom);
 } else {
 assert(min_id == 3);
 d_update(left_bottom, right_bottom, d_closest_pt, d_left_bottom, d_right_bottom);
 }
 auto d_p_min = Vector2f{0, 0};
 auto d_p_max = Vector2f{0, 0};
 // left_top = rect.p_min
 // right_top = Vector2f{rect.p_max.x, rect.p_min.y}
 // left_bottom = Vector2f{rect.p_min.x, rect.p_max.y}
 // right_bottom = rect.p_max
 d_p_min += d_left_top;
 d_p_max.x += d_right_top.x;
 d_p_min.y += d_right_top.y;
 d_p_min.x += d_left_bottom.x;
 d_p_max.y += d_left_bottom.y;
 d_p_max += d_right_bottom;
 atomic_add(d_rect.p_min, d_p_min);
 atomic_add(d_rect.p_max, d_p_max);
}
DEVICE
inline
void d_closest_point(const Shape &shape,
 const Vector2f &pt,
 const Vector2f &d_closest_pt,
 const ClosestPointPathInfo &path_info,
 Shape &d_shape,
 Vector2f &d_pt) {
 switch (shape.type) {
 case ShapeType::Circle:
 d_closest_point(*(const Circle *)shape.ptr,
 pt,
 d_closest_pt,
 *(Circle *)d_shape.ptr,
 d_pt);
 break;
 case ShapeType::Ellipse:
 // https://www.geometrictools.com/Documentation/DistancePointEllipseEllipsoid.pdf
 assert(false);
 break;
 case ShapeType::Path:
 d_closest_point(*(const Path *)shape.ptr,
 pt,
 d_closest_pt,
 path_info,
 *(Path *)d_shape.ptr,
 d_pt);
 break;
 case ShapeType::Rect:
 d_closest_point(*(const Rect *)shape.ptr,
 pt,
 d_closest_pt,
 *(Rect *)d_shape.ptr,
 d_pt);
 break;
 }
}
DEVICE
inline
void d_compute_distance(const Matrix3x3f &canvas_to_shape,
 const Matrix3x3f &shape_to_canvas,
 const Shape &shape,
 const Vector2f &pt,
 const Vector2f &closest_pt,
 const ClosestPointPathInfo &path_info,
 float d_dist,
 Matrix3x3f &d_shape_to_canvas,
 Shape &d_shape,
 float *d_translation) {
 if (distance_squared(pt, closest_pt) < 1e-10f) {
 // The derivative at distance=0 is undefined
 return;
 }
 assert(isfinite(d_dist));
 // pt is in canvas space, transform it to shape's local space
 auto local_pt = xform_pt(canvas_to_shape, pt);
 auto local_closest_pt = xform_pt(canvas_to_shape, closest_pt);
 // auto local_closest_pt = closest_point(shape, local_pt);
 // auto closest_pt = xform_pt(shape_group.shape_to_canvas, local_closest_pt);
 // auto dist = distance(closest_pt, pt);
 auto d_pt = Vector2f{0, 0};
 auto d_closest_pt = Vector2f{0, 0};
 d_distance(closest_pt, pt, d_dist, d_closest_pt, d_pt);
 assert(isfinite(d_pt));
 assert(isfinite(d_closest_pt));
 // auto closest_pt = xform_pt(shape_group.shape_to_canvas, local_closest_pt);
 auto d_local_closest_pt = Vector2f{0, 0};
 auto d_shape_to_canvas_ = Matrix3x3f();
 d_xform_pt(shape_to_canvas, local_closest_pt, d_closest_pt,
 d_shape_to_canvas_, d_local_closest_pt);
 assert(isfinite(d_local_closest_pt));
 auto d_local_pt = Vector2f{0, 0};
 d_closest_point(shape, local_pt, d_local_closest_pt, path_info, d_shape, d_local_pt);
 assert(isfinite(d_local_pt));
 auto d_canvas_to_shape = Matrix3x3f();
 d_xform_pt(canvas_to_shape,
 pt,
 d_local_pt,
 d_canvas_to_shape,
 d_pt);
 // http://jack.valmadre.net/notes/2016/09/04/back-prop-differentials/#back-propagation-using-differentials
 auto tc2s = transpose(canvas_to_shape);
 d_shape_to_canvas_ += -tc2s * d_canvas_to_shape * tc2s;
 atomic_add(&d_shape_to_canvas(0, 0), d_shape_to_canvas_);
 if (d_translation != nullptr) {
 atomic_add(d_translation, -d_pt);
 }
}