src/hb-draw.cc - third_party/harfbuzz - Git at Google

 /*
  * Copyright © 2019-2020  Ebrahim Byagowi
  *
  *  This is part of HarfBuzz, a text shaping library.
  *
  * Permission is hereby granted, without written agreement and without
  * license or royalty fees, to use, copy, modify, and distribute this
  * software and its documentation for any purpose, provided that the
  * above copyright notice and the following two paragraphs appear in
  * all copies of this software.
  *
  * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
  * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
  * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
  * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
  * DAMAGE.
  *
  * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
  * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
  * FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
  * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
  * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
  */

 #include "hb.hh"

 #ifndef HB_NO_DRAW

 #include "hb-draw.hh"

 #include "hb-geometry.hh"

 #include "hb-machinery.hh"

 #include <cmath>


 /**
  * SECTION:hb-draw
  * @title: hb-draw
  * @short_description: Glyph drawing
  * @include: hb.h
  *
  * Functions for drawing (extracting) glyph shapes.
  *
  * The #hb_draw_funcs_t struct can be used with hb_font_draw_glyph().
  **/

 static void
 hb_draw_move_to_nil (hb_draw_funcs_t *dfuncs HB_UNUSED, void *draw_data HB_UNUSED,
 		     hb_draw_state_t *st HB_UNUSED,
 		     float to_x HB_UNUSED, float to_y HB_UNUSED,
 		     void *user_data HB_UNUSED) {}

 static void
 hb_draw_line_to_nil (hb_draw_funcs_t *dfuncs HB_UNUSED, void *draw_data HB_UNUSED,
 		     hb_draw_state_t *st HB_UNUSED,
 		     float to_x HB_UNUSED, float to_y HB_UNUSED,
 		     void *user_data HB_UNUSED) {}

 static void
 hb_draw_quadratic_to_nil (hb_draw_funcs_t *dfuncs, void *draw_data,
 			  hb_draw_state_t *st,
 			  float control_x, float control_y,
 			  float to_x, float to_y,
 			  void *user_data HB_UNUSED)
 {
 #define HB_TWO_THIRD 0.66666666666666666666666667f
   dfuncs->emit_cubic_to (draw_data, *st,
 			 st->current_x + (control_x - st->current_x) * HB_TWO_THIRD,
 			 st->current_y + (control_y - st->current_y) * HB_TWO_THIRD,
 			 to_x + (control_x - to_x) * HB_TWO_THIRD,
 			 to_y + (control_y - to_y) * HB_TWO_THIRD,
 			 to_x, to_y);
 #undef HB_TWO_THIRD
 }

 static void
 hb_draw_cubic_to_nil (hb_draw_funcs_t *dfuncs HB_UNUSED, void *draw_data HB_UNUSED,
 		      hb_draw_state_t *st HB_UNUSED,
 		      float control1_x HB_UNUSED, float control1_y HB_UNUSED,
 		      float control2_x HB_UNUSED, float control2_y HB_UNUSED,
 		      float to_x HB_UNUSED, float to_y HB_UNUSED,
 		      void *user_data HB_UNUSED) {}

 static void
 hb_draw_close_path_nil (hb_draw_funcs_t *dfuncs HB_UNUSED, void *draw_data HB_UNUSED,
 			hb_draw_state_t *st HB_UNUSED,
 			void *user_data HB_UNUSED) {}


 static bool
 _hb_draw_funcs_set_preamble (hb_draw_funcs_t    *dfuncs,
 			     bool                func_is_null,
 			     void              **user_data,
 			     hb_destroy_func_t  *destroy)
 {
   if (hb_object_is_immutable (dfuncs))
   {
     if (*destroy)
       (*destroy) (*user_data);
     return false;
   }

   if (func_is_null)
   {
     if (*destroy)
       (*destroy) (*user_data);
     *destroy = nullptr;
     *user_data = nullptr;
   }

   return true;
 }

 static bool
 _hb_draw_funcs_set_middle (hb_draw_funcs_t   *dfuncs,
 			   void              *user_data,
 			   hb_destroy_func_t  destroy)
 {
   auto destroy_guard = hb_make_scope_guard ([&]() {
     if (destroy) destroy (user_data);
   });

   if (user_data && !dfuncs->user_data)
   {
     dfuncs->user_data = (decltype (dfuncs->user_data)) hb_calloc (1, sizeof (*dfuncs->user_data));
     if (unlikely (!dfuncs->user_data))
       return false;
   }
   if (destroy && !dfuncs->destroy)
   {
     dfuncs->destroy = (decltype (dfuncs->destroy)) hb_calloc (1, sizeof (*dfuncs->destroy));
     if (unlikely (!dfuncs->destroy))
       return false;
   }

   destroy_guard.release ();
   return true;
 }

 #define HB_DRAW_FUNC_IMPLEMENT(name)						\
 										\
 void										\
 hb_draw_funcs_set_##name##_func (hb_draw_funcs_t	 *dfuncs,		\
 				 hb_draw_##name##_func_t  func,			\
 				 void			 *user_data,		\
 				 hb_destroy_func_t	  destroy)		\
 {										\
   if (!_hb_draw_funcs_set_preamble (dfuncs, !func, &user_data, &destroy))\
       return;                                                            \
 										\
   if (dfuncs->destroy && dfuncs->destroy->name)					\
     dfuncs->destroy->name (!dfuncs->user_data ? nullptr : dfuncs->user_data->name); \
 									 \
   if (!_hb_draw_funcs_set_middle (dfuncs, user_data, destroy))           \
       return;                                                            \
 									\
   if (func)								\
     dfuncs->func.name = func;						\
   else									\
     dfuncs->func.name = hb_draw_##name##_nil;				\
 									\
   if (dfuncs->user_data)						\
     dfuncs->user_data->name = user_data;				\
   if (dfuncs->destroy)							\
     dfuncs->destroy->name = destroy;					\
 }

 HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
 #undef HB_DRAW_FUNC_IMPLEMENT

 /**
  * hb_draw_funcs_create:
  *
  * Creates a new draw callbacks object.
  *
  * Return value: (transfer full):
  * A newly allocated #hb_draw_funcs_t with a reference count of 1. The initial
  * reference count should be released with hb_draw_funcs_destroy when you are
  * done using the #hb_draw_funcs_t. This function never returns `NULL`. If
  * memory cannot be allocated, a special singleton #hb_draw_funcs_t object will
  * be returned.
  *
  * Since: 4.0.0
  **/
 hb_draw_funcs_t *
 hb_draw_funcs_create ()
 {
   hb_draw_funcs_t *dfuncs;
   if (unlikely (!(dfuncs = hb_object_create<hb_draw_funcs_t> ())))
     return const_cast<hb_draw_funcs_t *> (&Null (hb_draw_funcs_t));

   dfuncs->func =  Null (hb_draw_funcs_t).func;

   return dfuncs;
 }

 DEFINE_NULL_INSTANCE (hb_draw_funcs_t) =
 {
   HB_OBJECT_HEADER_STATIC,

   {
 #define HB_DRAW_FUNC_IMPLEMENT(name) hb_draw_##name##_nil,
     HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
 #undef HB_DRAW_FUNC_IMPLEMENT
   }
 };

 /**
  * hb_draw_funcs_get_empty:
  *
  * Fetches the singleton empty draw-functions structure.
  *
  * Return value: (transfer full): The empty draw-functions structure
  *
  * Since: 7.0.0
  **/
 hb_draw_funcs_t *
 hb_draw_funcs_get_empty ()
 {
   return const_cast<hb_draw_funcs_t *> (&Null (hb_draw_funcs_t));
 }

 /**
  * hb_draw_funcs_reference: (skip)
  * @dfuncs: draw functions
  *
  * Increases the reference count on @dfuncs by one.
  *
  * This prevents @dfuncs from being destroyed until a matching
  * call to hb_draw_funcs_destroy() is made.
  *
  * Return value: (transfer full):
  * The referenced #hb_draw_funcs_t.
  *
  * Since: 4.0.0
  **/
 hb_draw_funcs_t *
 hb_draw_funcs_reference (hb_draw_funcs_t *dfuncs)
 {
   return hb_object_reference (dfuncs);
 }

 /**
  * hb_draw_funcs_destroy: (skip)
  * @dfuncs: draw functions
  *
  * Deallocate the @dfuncs.
  * Decreases the reference count on @dfuncs by one. If the result is zero, then
  * @dfuncs and all associated resources are freed. See hb_draw_funcs_reference().
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_funcs_destroy (hb_draw_funcs_t *dfuncs)
 {
   if (!hb_object_destroy (dfuncs)) return;

   if (dfuncs->destroy)
   {
 #define HB_DRAW_FUNC_IMPLEMENT(name) \
     if (dfuncs->destroy->name) dfuncs->destroy->name (!dfuncs->user_data ? nullptr : dfuncs->user_data->name);
       HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
 #undef HB_DRAW_FUNC_IMPLEMENT
   }

   hb_free (dfuncs->destroy);
   hb_free (dfuncs->user_data);

   hb_free (dfuncs);
 }

 /**
  * hb_draw_funcs_set_user_data: (skip)
  * @dfuncs: The draw-functions structure
  * @key: The user-data key
  * @data: A pointer to the user data
  * @destroy: (nullable): A callback to call when @data is not needed anymore
  * @replace: Whether to replace an existing data with the same key
  *
  * Attaches a user-data key/data pair to the specified draw-functions structure.
  *
  * Return value: `true` if success, `false` otherwise
  *
  * Since: 7.0.0
  **/
 hb_bool_t
 hb_draw_funcs_set_user_data (hb_draw_funcs_t *dfuncs,
 			     hb_user_data_key_t *key,
 			     void *              data,
 			     hb_destroy_func_t   destroy,
 			     hb_bool_t           replace)
 {
   return hb_object_set_user_data (dfuncs, key, data, destroy, replace);
 }

 /**
  * hb_draw_funcs_get_user_data: (skip)
  * @dfuncs: The draw-functions structure
  * @key: The user-data key to query
  *
  * Fetches the user-data associated with the specified key,
  * attached to the specified draw-functions structure.
  *
  * Return value: (transfer none): A pointer to the user data
  *
  * Since: 7.0.0
  **/
 void *
 hb_draw_funcs_get_user_data (const hb_draw_funcs_t *dfuncs,
 			     hb_user_data_key_t       *key)
 {
   return hb_object_get_user_data (dfuncs, key);
 }

 /**
  * hb_draw_funcs_make_immutable:
  * @dfuncs: draw functions
  *
  * Makes @dfuncs object immutable.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_funcs_make_immutable (hb_draw_funcs_t *dfuncs)
 {
   if (hb_object_is_immutable (dfuncs))
     return;

   hb_object_make_immutable (dfuncs);
 }

 /**
  * hb_draw_funcs_is_immutable:
  * @dfuncs: draw functions
  *
  * Checks whether @dfuncs is immutable.
  *
  * Return value: `true` if @dfuncs is immutable, `false` otherwise
  *
  * Since: 4.0.0
  **/
 hb_bool_t
 hb_draw_funcs_is_immutable (hb_draw_funcs_t *dfuncs)
 {
   return hb_object_is_immutable (dfuncs);
 }


 /**
  * hb_draw_move_to:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @to_x: X component of target point
  * @to_y: Y component of target point
  *
  * Perform a "move-to" draw operation.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_move_to (hb_draw_funcs_t *dfuncs, void *draw_data,
 		 hb_draw_state_t *st,
 		 float to_x, float to_y)
 {
   dfuncs->move_to (draw_data, *st,
 		   to_x, to_y);
 }

 /**
  * hb_draw_line_to:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @to_x: X component of target point
  * @to_y: Y component of target point
  *
  * Perform a "line-to" draw operation.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_line_to (hb_draw_funcs_t *dfuncs, void *draw_data,
 		 hb_draw_state_t *st,
 		 float to_x, float to_y)
 {
   dfuncs->line_to (draw_data, *st,
 		   to_x, to_y);
 }

 /**
  * hb_draw_quadratic_to:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @control_x: X component of control point
  * @control_y: Y component of control point
  * @to_x: X component of target point
  * @to_y: Y component of target point
  *
  * Perform a "quadratic-to" draw operation.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_quadratic_to (hb_draw_funcs_t *dfuncs, void *draw_data,
 		      hb_draw_state_t *st,
 		      float control_x, float control_y,
 		      float to_x, float to_y)
 {
   dfuncs->quadratic_to (draw_data, *st,
 			control_x, control_y,
 			to_x, to_y);
 }

 /**
  * hb_draw_cubic_to:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @control1_x: X component of first control point
  * @control1_y: Y component of first control point
  * @control2_x: X component of second control point
  * @control2_y: Y component of second control point
  * @to_x: X component of target point
  * @to_y: Y component of target point
  *
  * Perform a "cubic-to" draw operation.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_cubic_to (hb_draw_funcs_t *dfuncs, void *draw_data,
 		  hb_draw_state_t *st,
 		  float control1_x, float control1_y,
 		  float control2_x, float control2_y,
 		  float to_x, float to_y)
 {
   dfuncs->cubic_to (draw_data, *st,
 		    control1_x, control1_y,
 		    control2_x, control2_y,
 		    to_x, to_y);
 }

 /**
  * hb_draw_close_path:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  *
  * Perform a "close-path" draw operation.
  *
  * Since: 4.0.0
  **/
 void
 hb_draw_close_path (hb_draw_funcs_t *dfuncs, void *draw_data,
 		    hb_draw_state_t *st)
 {
   dfuncs->close_path (draw_data, *st);
 }


 /**
  * hb_draw_line:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @x0: start X coordinate
  * @y0: start Y coordinate
  * @w0: stroke width at the start
  * @x1: end X coordinate
  * @y1: end Y coordinate
  * @w1: stroke width at the end
  * @cap: end-cap shape (butt or square)
  *
  * Emits a tapered line segment as a filled trapezoid.  @w0 and
  * @w1 are the full stroke widths at the start and end points
  * respectively; they may differ for a tapered stroke or match
  * for a uniform one.  Pass `NaN` for @w1 to use @w0 (uniform
  * stroke) without repeating the value.
  *
  * With #HB_DRAW_LINE_CAP_SQUARE each endpoint is extended along
  * the line direction by half its local stroke width, so four
  * `hb_draw_line()` calls form a closed rectangle without gaps
  * at the corners.
  *
  * XSince: REPLACEME
  **/
 void
 hb_draw_line (hb_draw_funcs_t *dfuncs, void *draw_data,
 	      hb_draw_state_t *st,
 	      float x0, float y0, float w0,
 	      float x1, float y1, float w1,
 	      hb_draw_line_cap_t cap)
 {
   if (std::isnan (w1)) w1 = w0;
   float dx = x1 - x0, dy = y1 - y0;
   float len = sqrtf (dx * dx + dy * dy);
   if (len <= 0.f)
     return;
   /* Unit tangent and normal to the line direction. */
   float tx = dx / len;
   float ty = dy / len;
   float nx = -ty;
   float ny =  tx;
   float h0 = 0.5f * w0;
   float h1 = 0.5f * w1;
   /* Square caps: extend each endpoint outward along the line
    * tangent by half its local stroke width. */
   if (cap == HB_DRAW_LINE_CAP_SQUARE)
   {
     x0 -= tx * h0; y0 -= ty * h0;
     x1 += tx * h1; y1 += ty * h1;
   }
   /* Trapezoid corners (counter-clockwise). */
   float ax = x0 + nx * h0, ay = y0 + ny * h0;
   float bx = x1 + nx * h1, by = y1 + ny * h1;
   float cx = x1 - nx * h1, cy = y1 - ny * h1;
   float dx_ = x0 - nx * h0, dy_ = y0 - ny * h0;

   hb_draw_move_to   (dfuncs, draw_data, st, ax, ay);
   hb_draw_line_to   (dfuncs, draw_data, st, bx, by);
   hb_draw_line_to   (dfuncs, draw_data, st, cx, cy);
   hb_draw_line_to   (dfuncs, draw_data, st, dx_, dy_);
   hb_draw_close_path (dfuncs, draw_data, st);
 }

 /* Emit an axis-aligned rectangle as a single closed contour.
  * @ccw picks the winding direction (useful for cutting a hole
  * out of another rectangle in a stroked rect). */
 static void
 _hb_draw_rect_contour (hb_draw_funcs_t *dfuncs, void *draw_data,
 		       hb_draw_state_t *st,
 		       float x, float y, float w, float h,
 		       bool ccw)
 {
   hb_draw_move_to (dfuncs, draw_data, st, x, y);
   if (ccw)
   {
     hb_draw_line_to (dfuncs, draw_data, st, x + w, y);
     hb_draw_line_to (dfuncs, draw_data, st, x + w, y + h);
     hb_draw_line_to (dfuncs, draw_data, st, x,     y + h);
   }
   else
   {
     hb_draw_line_to (dfuncs, draw_data, st, x,     y + h);
     hb_draw_line_to (dfuncs, draw_data, st, x + w, y + h);
     hb_draw_line_to (dfuncs, draw_data, st, x + w, y);
   }
   hb_draw_close_path (dfuncs, draw_data, st);
 }

 /**
  * hb_draw_rectangle:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @x: top-left X coordinate
  * @y: top-left Y coordinate
  * @w: width (may be negative)
  * @h: height (may be negative)
  * @stroke_width: stroke width, or `NaN` for a filled rectangle
  *
  * Emits an axis-aligned rectangle.  If @stroke_width is a finite
  * positive value, the rectangle is rendered as an outlined ring
  * of that thickness centered on the edges; if @stroke_width is
  * `NaN`, the rectangle is rendered filled.
  *
  * Note: stroked rectangles produce a bounding box covering the
  * full outer rectangle, so if the pen is a GPU fragment-shader
  * backend, the shader runs for every interior pixel even though
  * only the outline contributes coverage.  For very thin
  * outlines where the interior is much larger than the stroke,
  * emitting four hb_draw_line() segments (one per edge) is
  * considerably cheaper per frame.
  *
  * XSince: REPLACEME
  **/
 void
 hb_draw_rectangle (hb_draw_funcs_t *dfuncs, void *draw_data,
 		   hb_draw_state_t *st,
 		   float x, float y,
 		   float w, float h,
 		   float stroke_width)
 {
   if (std::isnan (stroke_width))
   {
     /* Filled rectangle with zero area is nothing to draw. */
     if (w == 0.f || h == 0.f)
       return;
     _hb_draw_rect_contour (dfuncs, draw_data, st, x, y, w, h, /*ccw*/ true);
     return;
   }

   if (stroke_width <= 0.f || !std::isfinite (stroke_width))
     return;

   /* Normalize to non-negative width/height so the stroke math
    * below (outer grows by sw, inner shrinks by sw) produces the
    * expected outer-contains-inner ring regardless of w/h signs. */
   if (w < 0.f) { x += w; w = -w; }
   if (h < 0.f) { y += h; h = -h; }
   /* w or h == 0 is still meaningful when stroking: a stroked
    * zero-height rect is a horizontal line of length w; zero
    * width is a vertical line.  Both degenerate to a single
    * outer contour because the inner hole collapses. */

   /* Stroke is centered on the edge: outer contour grows by
    * stroke_width/2, inner contour shrinks by the same. */
   float s = 0.5f * stroke_width;
   /* Outer rectangle (CCW = adds coverage). */
   _hb_draw_rect_contour (dfuncs, draw_data, st,
 			 x - s, y - s,
 			 w + stroke_width, h + stroke_width,
 			 /*ccw*/ true);
   /* Inner rectangle (CW = removes coverage for the hole). */
   float iw = w - stroke_width;
   float ih = h - stroke_width;
   if (iw > 0.f && ih > 0.f)
     _hb_draw_rect_contour (dfuncs, draw_data, st,
 			   x + s, y + s, iw, ih,
 			   /*ccw*/ false);
 }

 /* Circle approximated by 4 cubic Beziers, one per quadrant.
  * The magic constant 0.5522847498307936 is
  *   (4/3) * (sqrt(2) - 1)
  * and minimizes the max radial error to ~2.7e-4 of r. */
 static void
 _hb_draw_circle_contour (hb_draw_funcs_t *dfuncs, void *draw_data,
 			 hb_draw_state_t *st,
 			 float cx, float cy, float r,
 			 bool ccw)
 {
   static const float k = 0.5522847498307936f;
   float ck = r * k;

   hb_draw_move_to (dfuncs, draw_data, st, cx + r, cy);
   if (ccw)
   {
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx + r, cy + ck,
 		      cx + ck, cy + r,
 		      cx,      cy + r);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx - ck, cy + r,
 		      cx - r,  cy + ck,
 		      cx - r,  cy);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx - r,  cy - ck,
 		      cx - ck, cy - r,
 		      cx,      cy - r);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx + ck, cy - r,
 		      cx + r,  cy - ck,
 		      cx + r,  cy);
   }
   else
   {
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx + r, cy - ck,
 		      cx + ck, cy - r,
 		      cx,      cy - r);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx - ck, cy - r,
 		      cx - r,  cy - ck,
 		      cx - r,  cy);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx - r,  cy + ck,
 		      cx - ck, cy + r,
 		      cx,      cy + r);
     hb_draw_cubic_to (dfuncs, draw_data, st,
 		      cx + ck, cy + r,
 		      cx + r,  cy + ck,
 		      cx + r,  cy);
   }
   hb_draw_close_path (dfuncs, draw_data, st);
 }

 /**
  * hb_draw_circle:
  * @dfuncs: draw functions
  * @draw_data: associated draw data passed by the caller
  * @st: current draw state
  * @cx: center X coordinate
  * @cy: center Y coordinate
  * @r: radius
  * @stroke_width: stroke width, or `NaN` for a filled disc
  *
  * Emits a circle approximated by four cubic Bezier curves.  If
  * @stroke_width is a finite positive value, the circle is
  * rendered as an outlined ring of that thickness centered on
  * the nominal radius; if @stroke_width is `NaN`, the circle is
  * rendered as a filled disc.
  *
  * XSince: REPLACEME
  **/
 void
 hb_draw_circle (hb_draw_funcs_t *dfuncs, void *draw_data,
 		hb_draw_state_t *st,
 		float cx, float cy,
 		float r,
 		float stroke_width)
 {
   if (r <= 0.f)
     return;

   if (std::isnan (stroke_width))
   {
     _hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, r, /*ccw*/ true);
     return;
   }

   if (stroke_width <= 0.f || !std::isfinite (stroke_width))
     return;

   float s = 0.5f * stroke_width;
   _hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, r + s, /*ccw*/ true);
   float ir = r - s;
   if (ir > 0.f)
     _hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, ir, /*ccw*/ false);
 }


 static void
 hb_draw_extents_move_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
 			 void *data,
 			 hb_draw_state_t *st,
 			 float to_x, float to_y,
 			 void *user_data HB_UNUSED)
 {
   hb_extents_t<> *extents = (hb_extents_t<> *) data;

   extents->add_point (to_x, to_y);
 }

 static void
 hb_draw_extents_line_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
 			 void *data,
 			 hb_draw_state_t *st,
 			 float to_x, float to_y,
 			 void *user_data HB_UNUSED)
 {
   hb_extents_t<> *extents = (hb_extents_t<> *) data;

   extents->add_point (to_x, to_y);
 }

 static void
 hb_draw_extents_quadratic_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
 			      void *data,
 			      hb_draw_state_t *st,
 			      float control_x, float control_y,
 			      float to_x, float to_y,
 			      void *user_data HB_UNUSED)
 {
   hb_extents_t<> *extents = (hb_extents_t<> *) data;

   extents->add_point (control_x, control_y);
   extents->add_point (to_x, to_y);
 }

 static void
 hb_draw_extents_cubic_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
 			  void *data,
 			  hb_draw_state_t *st,
 			  float control1_x, float control1_y,
 			  float control2_x, float control2_y,
 			  float to_x, float to_y,
 			  void *user_data HB_UNUSED)
 {
   hb_extents_t<> *extents = (hb_extents_t<> *) data;

   extents->add_point (control1_x, control1_y);
   extents->add_point (control2_x, control2_y);
   extents->add_point (to_x, to_y);
 }

 static inline void free_static_draw_extents_funcs ();

 static struct hb_draw_extents_funcs_lazy_loader_t : hb_draw_funcs_lazy_loader_t<hb_draw_extents_funcs_lazy_loader_t>
 {
   static hb_draw_funcs_t *create ()
   {
     hb_draw_funcs_t *funcs = hb_draw_funcs_create ();

     hb_draw_funcs_set_move_to_func (funcs, hb_draw_extents_move_to, nullptr, nullptr);
     hb_draw_funcs_set_line_to_func (funcs, hb_draw_extents_line_to, nullptr, nullptr);
     hb_draw_funcs_set_quadratic_to_func (funcs, hb_draw_extents_quadratic_to, nullptr, nullptr);
     hb_draw_funcs_set_cubic_to_func (funcs, hb_draw_extents_cubic_to, nullptr, nullptr);

     hb_draw_funcs_make_immutable (funcs);

     hb_atexit (free_static_draw_extents_funcs);

     return funcs;
   }
 } static_draw_extents_funcs;

 static inline
 void free_static_draw_extents_funcs ()
 {
   static_draw_extents_funcs.free_instance ();
 }

 hb_draw_funcs_t *
 hb_draw_extents_get_funcs ()
 {
   return static_draw_extents_funcs.get_unconst ();
 }


 #endif
	/*
	* Copyright © 2019-2020 Ebrahim Byagowi
	*
	* This is part of HarfBuzz, a text shaping library.
	*
	* Permission is hereby granted, without written agreement and without
	* license or royalty fees, to use, copy, modify, and distribute this
	* software and its documentation for any purpose, provided that the
	* above copyright notice and the following two paragraphs appear in
	* all copies of this software.
	*
	* IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
	* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
	* ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
	* IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
	* DAMAGE.
	*
	* THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
	* BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
	* FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS
	* ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
	* PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
	*/

	#include "hb.hh"

	#ifndef HB_NO_DRAW

	#include "hb-draw.hh"

	#include "hb-geometry.hh"

	#include "hb-machinery.hh"

	#include <cmath>


	/**
	* SECTION:hb-draw
	* @title: hb-draw
	* @short_description: Glyph drawing
	* @include: hb.h
	*
	* Functions for drawing (extracting) glyph shapes.
	*
	* The #hb_draw_funcs_t struct can be used with hb_font_draw_glyph().
	**/

	static void
	hb_draw_move_to_nil (hb_draw_funcs_t dfuncs HB_UNUSED, void draw_data HB_UNUSED,
	hb_draw_state_t *st HB_UNUSED,
	float to_x HB_UNUSED, float to_y HB_UNUSED,
	void *user_data HB_UNUSED) {}

	static void
	hb_draw_line_to_nil (hb_draw_funcs_t dfuncs HB_UNUSED, void draw_data HB_UNUSED,
	hb_draw_state_t *st HB_UNUSED,
	float to_x HB_UNUSED, float to_y HB_UNUSED,
	void *user_data HB_UNUSED) {}

	static void
	hb_draw_quadratic_to_nil (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float control_x, float control_y,
	float to_x, float to_y,
	void *user_data HB_UNUSED)
	{
	#define HB_TWO_THIRD 0.66666666666666666666666667f
	dfuncs->emit_cubic_to (draw_data, *st,
	st->current_x + (control_x - st->current_x) * HB_TWO_THIRD,
	st->current_y + (control_y - st->current_y) * HB_TWO_THIRD,
	to_x + (control_x - to_x) * HB_TWO_THIRD,
	to_y + (control_y - to_y) * HB_TWO_THIRD,
	to_x, to_y);
	#undef HB_TWO_THIRD
	}

	static void
	hb_draw_cubic_to_nil (hb_draw_funcs_t dfuncs HB_UNUSED, void draw_data HB_UNUSED,
	hb_draw_state_t *st HB_UNUSED,
	float control1_x HB_UNUSED, float control1_y HB_UNUSED,
	float control2_x HB_UNUSED, float control2_y HB_UNUSED,
	float to_x HB_UNUSED, float to_y HB_UNUSED,
	void *user_data HB_UNUSED) {}

	static void
	hb_draw_close_path_nil (hb_draw_funcs_t dfuncs HB_UNUSED, void draw_data HB_UNUSED,
	hb_draw_state_t *st HB_UNUSED,
	void *user_data HB_UNUSED) {}


	static bool
	_hb_draw_funcs_set_preamble (hb_draw_funcs_t *dfuncs,
	bool func_is_null,
	void **user_data,
	hb_destroy_func_t *destroy)
	{
	if (hb_object_is_immutable (dfuncs))
	{
	if (*destroy)
	(destroy) (user_data);
	return false;
	}

	if (func_is_null)
	{
	if (*destroy)
	(destroy) (user_data);
	*destroy = nullptr;
	*user_data = nullptr;
	}

	return true;
	}

	static bool
	_hb_draw_funcs_set_middle (hb_draw_funcs_t *dfuncs,
	void *user_data,
	hb_destroy_func_t destroy)
	{
	auto destroy_guard = hb_make_scope_guard ([&]() {
	if (destroy) destroy (user_data);
	});

	if (user_data && !dfuncs->user_data)
	{
	dfuncs->user_data = (decltype (dfuncs->user_data)) hb_calloc (1, sizeof (*dfuncs->user_data));
	if (unlikely (!dfuncs->user_data))
	return false;
	}
	if (destroy && !dfuncs->destroy)
	{
	dfuncs->destroy = (decltype (dfuncs->destroy)) hb_calloc (1, sizeof (*dfuncs->destroy));
	if (unlikely (!dfuncs->destroy))
	return false;
	}

	destroy_guard.release ();
	return true;
	}

	#define HB_DRAW_FUNC_IMPLEMENT(name) \
	\
	void \
	hb_draw_funcs_set_##name##_func (hb_draw_funcs_t *dfuncs, \
	hb_draw_##name##_func_t func, \
	void *user_data, \
	hb_destroy_func_t destroy) \
	{ \
	if (!_hb_draw_funcs_set_preamble (dfuncs, !func, &user_data, &destroy))\
	return; \
	\
	if (dfuncs->destroy && dfuncs->destroy->name) \
	dfuncs->destroy->name (!dfuncs->user_data ? nullptr : dfuncs->user_data->name); \
	\
	if (!_hb_draw_funcs_set_middle (dfuncs, user_data, destroy)) \
	return; \
	\
	if (func) \
	dfuncs->func.name = func; \
	else \
	dfuncs->func.name = hb_draw_##name##_nil; \
	\
	if (dfuncs->user_data) \
	dfuncs->user_data->name = user_data; \
	if (dfuncs->destroy) \
	dfuncs->destroy->name = destroy; \
	}

	HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
	#undef HB_DRAW_FUNC_IMPLEMENT

	/**
	* hb_draw_funcs_create:
	*
	* Creates a new draw callbacks object.
	*
	* Return value: (transfer full):
	* A newly allocated #hb_draw_funcs_t with a reference count of 1. The initial
	* reference count should be released with hb_draw_funcs_destroy when you are
	* done using the #hb_draw_funcs_t. This function never returns `NULL`. If
	* memory cannot be allocated, a special singleton #hb_draw_funcs_t object will
	* be returned.
	*
	* Since: 4.0.0
	**/
	hb_draw_funcs_t *
	hb_draw_funcs_create ()
	{
	hb_draw_funcs_t *dfuncs;
	if (unlikely (!(dfuncs = hb_object_create<hb_draw_funcs_t> ())))
	return const_cast<hb_draw_funcs_t *> (&Null (hb_draw_funcs_t));

	dfuncs->func = Null (hb_draw_funcs_t).func;

	return dfuncs;
	}

	DEFINE_NULL_INSTANCE (hb_draw_funcs_t) =
	{
	HB_OBJECT_HEADER_STATIC,

	{
	#define HB_DRAW_FUNC_IMPLEMENT(name) hb_draw_##name##_nil,
	HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
	#undef HB_DRAW_FUNC_IMPLEMENT
	}
	};

	/**
	* hb_draw_funcs_get_empty:
	*
	* Fetches the singleton empty draw-functions structure.
	*
	* Return value: (transfer full): The empty draw-functions structure
	*
	* Since: 7.0.0
	**/
	hb_draw_funcs_t *
	hb_draw_funcs_get_empty ()
	{
	return const_cast<hb_draw_funcs_t *> (&Null (hb_draw_funcs_t));
	}

	/**
	* hb_draw_funcs_reference: (skip)
	* @dfuncs: draw functions
	*
	* Increases the reference count on @dfuncs by one.
	*
	* This prevents @dfuncs from being destroyed until a matching
	* call to hb_draw_funcs_destroy() is made.
	*
	* Return value: (transfer full):
	* The referenced #hb_draw_funcs_t.
	*
	* Since: 4.0.0
	**/
	hb_draw_funcs_t *
	hb_draw_funcs_reference (hb_draw_funcs_t *dfuncs)
	{
	return hb_object_reference (dfuncs);
	}

	/**
	* hb_draw_funcs_destroy: (skip)
	* @dfuncs: draw functions
	*
	* Deallocate the @dfuncs.
	* Decreases the reference count on @dfuncs by one. If the result is zero, then
	* @dfuncs and all associated resources are freed. See hb_draw_funcs_reference().
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_funcs_destroy (hb_draw_funcs_t *dfuncs)
	{
	if (!hb_object_destroy (dfuncs)) return;

	if (dfuncs->destroy)
	{
	#define HB_DRAW_FUNC_IMPLEMENT(name) \
	if (dfuncs->destroy->name) dfuncs->destroy->name (!dfuncs->user_data ? nullptr : dfuncs->user_data->name);
	HB_DRAW_FUNCS_IMPLEMENT_CALLBACKS
	#undef HB_DRAW_FUNC_IMPLEMENT
	}

	hb_free (dfuncs->destroy);
	hb_free (dfuncs->user_data);

	hb_free (dfuncs);
	}

	/**
	* hb_draw_funcs_set_user_data: (skip)
	* @dfuncs: The draw-functions structure
	* @key: The user-data key
	* @data: A pointer to the user data
	* @destroy: (nullable): A callback to call when @data is not needed anymore
	* @replace: Whether to replace an existing data with the same key
	*
	* Attaches a user-data key/data pair to the specified draw-functions structure.
	*
	* Return value: `true` if success, `false` otherwise
	*
	* Since: 7.0.0
	**/
	hb_bool_t
	hb_draw_funcs_set_user_data (hb_draw_funcs_t *dfuncs,
	hb_user_data_key_t *key,
	void * data,
	hb_destroy_func_t destroy,
	hb_bool_t replace)
	{
	return hb_object_set_user_data (dfuncs, key, data, destroy, replace);
	}

	/**
	* hb_draw_funcs_get_user_data: (skip)
	* @dfuncs: The draw-functions structure
	* @key: The user-data key to query
	*
	* Fetches the user-data associated with the specified key,
	* attached to the specified draw-functions structure.
	*
	* Return value: (transfer none): A pointer to the user data
	*
	* Since: 7.0.0
	**/
	void *
	hb_draw_funcs_get_user_data (const hb_draw_funcs_t *dfuncs,
	hb_user_data_key_t *key)
	{
	return hb_object_get_user_data (dfuncs, key);
	}

	/**
	* hb_draw_funcs_make_immutable:
	* @dfuncs: draw functions
	*
	* Makes @dfuncs object immutable.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_funcs_make_immutable (hb_draw_funcs_t *dfuncs)
	{
	if (hb_object_is_immutable (dfuncs))
	return;

	hb_object_make_immutable (dfuncs);
	}

	/**
	* hb_draw_funcs_is_immutable:
	* @dfuncs: draw functions
	*
	* Checks whether @dfuncs is immutable.
	*
	* Return value: `true` if @dfuncs is immutable, `false` otherwise
	*
	* Since: 4.0.0
	**/
	hb_bool_t
	hb_draw_funcs_is_immutable (hb_draw_funcs_t *dfuncs)
	{
	return hb_object_is_immutable (dfuncs);
	}


	/**
	* hb_draw_move_to:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @to_x: X component of target point
	* @to_y: Y component of target point
	*
	* Perform a "move-to" draw operation.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_move_to (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float to_x, float to_y)
	{
	dfuncs->move_to (draw_data, *st,
	to_x, to_y);
	}

	/**
	* hb_draw_line_to:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @to_x: X component of target point
	* @to_y: Y component of target point
	*
	* Perform a "line-to" draw operation.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_line_to (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float to_x, float to_y)
	{
	dfuncs->line_to (draw_data, *st,
	to_x, to_y);
	}

	/**
	* hb_draw_quadratic_to:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @control_x: X component of control point
	* @control_y: Y component of control point
	* @to_x: X component of target point
	* @to_y: Y component of target point
	*
	* Perform a "quadratic-to" draw operation.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_quadratic_to (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float control_x, float control_y,
	float to_x, float to_y)
	{
	dfuncs->quadratic_to (draw_data, *st,
	control_x, control_y,
	to_x, to_y);
	}

	/**
	* hb_draw_cubic_to:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @control1_x: X component of first control point
	* @control1_y: Y component of first control point
	* @control2_x: X component of second control point
	* @control2_y: Y component of second control point
	* @to_x: X component of target point
	* @to_y: Y component of target point
	*
	* Perform a "cubic-to" draw operation.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_cubic_to (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float control1_x, float control1_y,
	float control2_x, float control2_y,
	float to_x, float to_y)
	{
	dfuncs->cubic_to (draw_data, *st,
	control1_x, control1_y,
	control2_x, control2_y,
	to_x, to_y);
	}

	/**
	* hb_draw_close_path:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	*
	* Perform a "close-path" draw operation.
	*
	* Since: 4.0.0
	**/
	void
	hb_draw_close_path (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st)
	{
	dfuncs->close_path (draw_data, *st);
	}


	/**
	* hb_draw_line:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @x0: start X coordinate
	* @y0: start Y coordinate
	* @w0: stroke width at the start
	* @x1: end X coordinate
	* @y1: end Y coordinate
	* @w1: stroke width at the end
	* @cap: end-cap shape (butt or square)
	*
	* Emits a tapered line segment as a filled trapezoid. @w0 and
	* @w1 are the full stroke widths at the start and end points
	* respectively; they may differ for a tapered stroke or match
	* for a uniform one. Pass `NaN` for @w1 to use @w0 (uniform
	* stroke) without repeating the value.
	*
	* With #HB_DRAW_LINE_CAP_SQUARE each endpoint is extended along
	* the line direction by half its local stroke width, so four
	* `hb_draw_line()` calls form a closed rectangle without gaps
	* at the corners.
	*
	* XSince: REPLACEME
	**/
	void
	hb_draw_line (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float x0, float y0, float w0,
	float x1, float y1, float w1,
	hb_draw_line_cap_t cap)
	{
	if (std::isnan (w1)) w1 = w0;
	float dx = x1 - x0, dy = y1 - y0;
	float len = sqrtf (dx * dx + dy * dy);
	if (len <= 0.f)
	return;
	/* Unit tangent and normal to the line direction. */
	float tx = dx / len;
	float ty = dy / len;
	float nx = -ty;
	float ny = tx;
	float h0 = 0.5f * w0;
	float h1 = 0.5f * w1;
	/* Square caps: extend each endpoint outward along the line
	* tangent by half its local stroke width. */
	if (cap == HB_DRAW_LINE_CAP_SQUARE)
	{
	x0 -= tx * h0; y0 -= ty * h0;
	x1 += tx * h1; y1 += ty * h1;
	}
	/* Trapezoid corners (counter-clockwise). */
	float ax = x0 + nx * h0, ay = y0 + ny * h0;
	float bx = x1 + nx * h1, by = y1 + ny * h1;
	float cx = x1 - nx * h1, cy = y1 - ny * h1;
	float dx_ = x0 - nx * h0, dy_ = y0 - ny * h0;

	hb_draw_move_to (dfuncs, draw_data, st, ax, ay);
	hb_draw_line_to (dfuncs, draw_data, st, bx, by);
	hb_draw_line_to (dfuncs, draw_data, st, cx, cy);
	hb_draw_line_to (dfuncs, draw_data, st, dx_, dy_);
	hb_draw_close_path (dfuncs, draw_data, st);
	}

	/* Emit an axis-aligned rectangle as a single closed contour.
	* @ccw picks the winding direction (useful for cutting a hole
	* out of another rectangle in a stroked rect). */
	static void
	_hb_draw_rect_contour (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float x, float y, float w, float h,
	bool ccw)
	{
	hb_draw_move_to (dfuncs, draw_data, st, x, y);
	if (ccw)
	{
	hb_draw_line_to (dfuncs, draw_data, st, x + w, y);
	hb_draw_line_to (dfuncs, draw_data, st, x + w, y + h);
	hb_draw_line_to (dfuncs, draw_data, st, x, y + h);
	}
	else
	{
	hb_draw_line_to (dfuncs, draw_data, st, x, y + h);
	hb_draw_line_to (dfuncs, draw_data, st, x + w, y + h);
	hb_draw_line_to (dfuncs, draw_data, st, x + w, y);
	}
	hb_draw_close_path (dfuncs, draw_data, st);
	}

	/**
	* hb_draw_rectangle:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @x: top-left X coordinate
	* @y: top-left Y coordinate
	* @w: width (may be negative)
	* @h: height (may be negative)
	* @stroke_width: stroke width, or `NaN` for a filled rectangle
	*
	* Emits an axis-aligned rectangle. If @stroke_width is a finite
	* positive value, the rectangle is rendered as an outlined ring
	* of that thickness centered on the edges; if @stroke_width is
	* `NaN`, the rectangle is rendered filled.
	*
	* Note: stroked rectangles produce a bounding box covering the
	* full outer rectangle, so if the pen is a GPU fragment-shader
	* backend, the shader runs for every interior pixel even though
	* only the outline contributes coverage. For very thin
	* outlines where the interior is much larger than the stroke,
	* emitting four hb_draw_line() segments (one per edge) is
	* considerably cheaper per frame.
	*
	* XSince: REPLACEME
	**/
	void
	hb_draw_rectangle (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float x, float y,
	float w, float h,
	float stroke_width)
	{
	if (std::isnan (stroke_width))
	{
	/* Filled rectangle with zero area is nothing to draw. */
	if (w == 0.f \|\| h == 0.f)
	return;
	_hb_draw_rect_contour (dfuncs, draw_data, st, x, y, w, h, /ccw/ true);
	return;
	}

	if (stroke_width <= 0.f \|\| !std::isfinite (stroke_width))
	return;

	/* Normalize to non-negative width/height so the stroke math
	* below (outer grows by sw, inner shrinks by sw) produces the
	* expected outer-contains-inner ring regardless of w/h signs. */
	if (w < 0.f) { x += w; w = -w; }
	if (h < 0.f) { y += h; h = -h; }
	/* w or h == 0 is still meaningful when stroking: a stroked
	* zero-height rect is a horizontal line of length w; zero
	* width is a vertical line. Both degenerate to a single
	* outer contour because the inner hole collapses. */

	/* Stroke is centered on the edge: outer contour grows by
	* stroke_width/2, inner contour shrinks by the same. */
	float s = 0.5f * stroke_width;
	/* Outer rectangle (CCW = adds coverage). */
	_hb_draw_rect_contour (dfuncs, draw_data, st,
	x - s, y - s,
	w + stroke_width, h + stroke_width,
	/ccw/ true);
	/* Inner rectangle (CW = removes coverage for the hole). */
	float iw = w - stroke_width;
	float ih = h - stroke_width;
	if (iw > 0.f && ih > 0.f)
	_hb_draw_rect_contour (dfuncs, draw_data, st,
	x + s, y + s, iw, ih,
	/ccw/ false);
	}

	/* Circle approximated by 4 cubic Beziers, one per quadrant.
	* The magic constant 0.5522847498307936 is
	* (4/3) * (sqrt(2) - 1)
	* and minimizes the max radial error to ~2.7e-4 of r. */
	static void
	_hb_draw_circle_contour (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float cx, float cy, float r,
	bool ccw)
	{
	static const float k = 0.5522847498307936f;
	float ck = r * k;

	hb_draw_move_to (dfuncs, draw_data, st, cx + r, cy);
	if (ccw)
	{
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx + r, cy + ck,
	cx + ck, cy + r,
	cx, cy + r);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx - ck, cy + r,
	cx - r, cy + ck,
	cx - r, cy);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx - r, cy - ck,
	cx - ck, cy - r,
	cx, cy - r);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx + ck, cy - r,
	cx + r, cy - ck,
	cx + r, cy);
	}
	else
	{
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx + r, cy - ck,
	cx + ck, cy - r,
	cx, cy - r);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx - ck, cy - r,
	cx - r, cy - ck,
	cx - r, cy);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx - r, cy + ck,
	cx - ck, cy + r,
	cx, cy + r);
	hb_draw_cubic_to (dfuncs, draw_data, st,
	cx + ck, cy + r,
	cx + r, cy + ck,
	cx + r, cy);
	}
	hb_draw_close_path (dfuncs, draw_data, st);
	}

	/**
	* hb_draw_circle:
	* @dfuncs: draw functions
	* @draw_data: associated draw data passed by the caller
	* @st: current draw state
	* @cx: center X coordinate
	* @cy: center Y coordinate
	* @r: radius
	* @stroke_width: stroke width, or `NaN` for a filled disc
	*
	* Emits a circle approximated by four cubic Bezier curves. If
	* @stroke_width is a finite positive value, the circle is
	* rendered as an outlined ring of that thickness centered on
	* the nominal radius; if @stroke_width is `NaN`, the circle is
	* rendered as a filled disc.
	*
	* XSince: REPLACEME
	**/
	void
	hb_draw_circle (hb_draw_funcs_t dfuncs, void draw_data,
	hb_draw_state_t *st,
	float cx, float cy,
	float r,
	float stroke_width)
	{
	if (r <= 0.f)
	return;

	if (std::isnan (stroke_width))
	{
	_hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, r, /ccw/ true);
	return;
	}

	if (stroke_width <= 0.f \|\| !std::isfinite (stroke_width))
	return;

	float s = 0.5f * stroke_width;
	_hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, r + s, /ccw/ true);
	float ir = r - s;
	if (ir > 0.f)
	_hb_draw_circle_contour (dfuncs, draw_data, st, cx, cy, ir, /ccw/ false);
	}


	static void
	hb_draw_extents_move_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
	void *data,
	hb_draw_state_t *st,
	float to_x, float to_y,
	void *user_data HB_UNUSED)
	{
	hb_extents_t<> extents = (hb_extents_t<> ) data;

	extents->add_point (to_x, to_y);
	}

	static void
	hb_draw_extents_line_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
	void *data,
	hb_draw_state_t *st,
	float to_x, float to_y,
	void *user_data HB_UNUSED)
	{
	hb_extents_t<> extents = (hb_extents_t<> ) data;

	extents->add_point (to_x, to_y);
	}

	static void
	hb_draw_extents_quadratic_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
	void *data,
	hb_draw_state_t *st,
	float control_x, float control_y,
	float to_x, float to_y,
	void *user_data HB_UNUSED)
	{
	hb_extents_t<> extents = (hb_extents_t<> ) data;

	extents->add_point (control_x, control_y);
	extents->add_point (to_x, to_y);
	}

	static void
	hb_draw_extents_cubic_to (hb_draw_funcs_t *dfuncs HB_UNUSED,
	void *data,
	hb_draw_state_t *st,
	float control1_x, float control1_y,
	float control2_x, float control2_y,
	float to_x, float to_y,
	void *user_data HB_UNUSED)
	{
	hb_extents_t<> extents = (hb_extents_t<> ) data;

	extents->add_point (control1_x, control1_y);
	extents->add_point (control2_x, control2_y);
	extents->add_point (to_x, to_y);
	}

	static inline void free_static_draw_extents_funcs ();

	static struct hb_draw_extents_funcs_lazy_loader_t : hb_draw_funcs_lazy_loader_t<hb_draw_extents_funcs_lazy_loader_t>
	{
	static hb_draw_funcs_t *create ()
	{
	hb_draw_funcs_t *funcs = hb_draw_funcs_create ();

	hb_draw_funcs_set_move_to_func (funcs, hb_draw_extents_move_to, nullptr, nullptr);
	hb_draw_funcs_set_line_to_func (funcs, hb_draw_extents_line_to, nullptr, nullptr);
	hb_draw_funcs_set_quadratic_to_func (funcs, hb_draw_extents_quadratic_to, nullptr, nullptr);
	hb_draw_funcs_set_cubic_to_func (funcs, hb_draw_extents_cubic_to, nullptr, nullptr);

	hb_draw_funcs_make_immutable (funcs);

	hb_atexit (free_static_draw_extents_funcs);

	return funcs;
	}
	} static_draw_extents_funcs;

	static inline
	void free_static_draw_extents_funcs ()
	{
	static_draw_extents_funcs.free_instance ();
	}

	hb_draw_funcs_t *
	hb_draw_extents_get_funcs ()
	{
	return static_draw_extents_funcs.get_unconst ();
	}


	#endif