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

 /*
  * Copyright © 1998-2004  David Turner and Werner Lemberg
  * Copyright © 2004,2007,2009,2010  Red Hat, Inc.
  * Copyright © 2011  Google, Inc.
  *
  *  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.
  *
  * Red Hat Author(s): Owen Taylor, Behdad Esfahbod
  * Google Author(s): Behdad Esfahbod
  */

 #include "hb-buffer-private.hh"

 #include <string.h>


 #ifndef HB_DEBUG_BUFFER
 #define HB_DEBUG_BUFFER (HB_DEBUG+0)
 #endif

 /* Here is how the buffer works internally:
  *
  * There are two info pointers: info and out_info.  They always have
  * the same allocated size, but different lengths.
  *
  * As an optimization, both info and out_info may point to the
  * same piece of memory, which is owned by info.  This remains the
  * case as long as out_len doesn't exceed i at any time.
  * In that case, swap_buffers() is no-op and the glyph operations operate
  * mostly in-place.
  *
  * As soon as out_info gets longer than info, out_info is moved over
  * to an alternate buffer (which we reuse the pos buffer for!), and its
  * current contents (out_len entries) are copied to the new place.
  * This should all remain transparent to the user.  swap_buffers() then
  * switches info and out_info.
  */


 /* Internal API */

 bool
 hb_buffer_t::enlarge (unsigned int size)
 {
   if (unlikely (in_error))
     return false;

   unsigned int new_allocated = allocated;
   hb_glyph_position_t *new_pos = NULL;
   hb_glyph_info_t *new_info = NULL;
   bool separate_out = out_info != info;

   if (unlikely (_hb_unsigned_int_mul_overflows (size, sizeof (info[0]))))
     goto done;

   while (size > new_allocated)
     new_allocated += (new_allocated >> 1) + 32;

   ASSERT_STATIC (sizeof (info[0]) == sizeof (pos[0]));
   if (unlikely (_hb_unsigned_int_mul_overflows (new_allocated, sizeof (info[0]))))
     goto done;

   new_pos = (hb_glyph_position_t *) realloc (pos, new_allocated * sizeof (pos[0]));
   new_info = (hb_glyph_info_t *) realloc (info, new_allocated * sizeof (info[0]));

 done:
   if (unlikely (!new_pos || !new_info))
     in_error = true;

   if (likely (new_pos))
     pos = new_pos;

   if (likely (new_info))
     info = new_info;

   out_info = separate_out ? (hb_glyph_info_t *) pos : info;
   if (likely (!in_error))
     allocated = new_allocated;

   return likely (!in_error);
 }

 bool
 hb_buffer_t::make_room_for (unsigned int num_in,
 			    unsigned int num_out)
 {
   if (unlikely (!ensure (out_len + num_out))) return false;

   if (out_info == info &&
       out_len + num_out > idx + num_in)
   {
     assert (have_output);

     out_info = (hb_glyph_info_t *) pos;
     memcpy (out_info, info, out_len * sizeof (out_info[0]));
   }

   return true;
 }

 void *
 hb_buffer_t::get_scratch_buffer (unsigned int *size)
 {
   have_output = false;
   have_positions = false;

   out_len = 0;
   out_info = info;

   *size = allocated * sizeof (pos[0]);
   return pos;
 }


 /* HarfBuzz-Internal API */

 void
 hb_buffer_t::reset (void)
 {
   if (unlikely (hb_object_is_inert (this)))
     return;

   hb_unicode_funcs_destroy (unicode);
   unicode = hb_unicode_funcs_get_default ();

   hb_segment_properties_t default_props = _HB_BUFFER_PROPS_DEFAULT;
   props = default_props;

   in_error = false;
   have_output = false;
   have_positions = false;

   idx = 0;
   len = 0;
   out_len = 0;
   out_info = info;

   serial = 0;
   memset (allocated_var_bytes, 0, sizeof allocated_var_bytes);
   memset (allocated_var_owner, 0, sizeof allocated_var_owner);
 }

 void
 hb_buffer_t::add (hb_codepoint_t  codepoint,
 		  hb_mask_t       mask,
 		  unsigned int    cluster)
 {
   hb_glyph_info_t *glyph;

   if (unlikely (!ensure (len + 1))) return;

   glyph = &info[len];

   memset (glyph, 0, sizeof (*glyph));
   glyph->codepoint = codepoint;
   glyph->mask = mask;
   glyph->cluster = cluster;

   len++;
 }

 void
 hb_buffer_t::clear_output (void)
 {
   if (unlikely (hb_object_is_inert (this)))
     return;

   have_output = true;
   have_positions = false;

   out_len = 0;
   out_info = info;
 }

 void
 hb_buffer_t::clear_positions (void)
 {
   if (unlikely (hb_object_is_inert (this)))
     return;

   have_output = false;
   have_positions = true;

   out_len = 0;
   out_info = info;

   memset (pos, 0, sizeof (pos[0]) * len);
 }

 void
 hb_buffer_t::swap_buffers (void)
 {
   if (unlikely (in_error)) return;

   assert (have_output);
   have_output = false;

   if (out_info != info)
   {
     hb_glyph_info_t *tmp_string;
     tmp_string = info;
     info = out_info;
     out_info = tmp_string;
     pos = (hb_glyph_position_t *) out_info;
   }

   unsigned int tmp;
   tmp = len;
   len = out_len;
   out_len = tmp;

   idx = 0;
 }


 void
 hb_buffer_t::replace_glyphs (unsigned int num_in,
 			     unsigned int num_out,
 			     const uint32_t *glyph_data)
 {
   if (unlikely (!make_room_for (num_in, num_out))) return;

   merge_clusters (idx, idx + num_in);

   hb_glyph_info_t orig_info = info[idx];
   hb_glyph_info_t *pinfo = &out_info[out_len];
   for (unsigned int i = 0; i < num_out; i++)
   {
     *pinfo = orig_info;
     pinfo->codepoint = glyph_data[i];
     pinfo++;
   }

   idx  += num_in;
   out_len += num_out;
 }

 void
 hb_buffer_t::output_glyph (hb_codepoint_t glyph_index)
 {
   if (unlikely (!make_room_for (0, 1))) return;

   out_info[out_len] = info[idx];
   out_info[out_len].codepoint = glyph_index;

   out_len++;
 }

 void
 hb_buffer_t::copy_glyph (void)
 {
   if (unlikely (!make_room_for (0, 1))) return;

   out_info[out_len] = info[idx];

   out_len++;
 }

 void
 hb_buffer_t::replace_glyph (hb_codepoint_t glyph_index)
 {
   if (unlikely (out_info != info || out_len != idx)) {
     if (unlikely (!make_room_for (1, 1))) return;
     out_info[out_len] = info[idx];
   }
   out_info[out_len].codepoint = glyph_index;

   idx++;
   out_len++;
 }

 void
 hb_buffer_t::next_glyph (void)
 {
   if (have_output)
   {
     if (unlikely (out_info != info || out_len != idx)) {
       if (unlikely (!make_room_for (1, 1))) return;
       out_info[out_len] = info[idx];
     }
     out_len++;
   }

   idx++;
 }


 void
 hb_buffer_t::set_masks (hb_mask_t    value,
 			hb_mask_t    mask,
 			unsigned int cluster_start,
 			unsigned int cluster_end)
 {
   hb_mask_t not_mask = ~mask;
   value &= mask;

   if (!mask)
     return;

   if (cluster_start == 0 && cluster_end == (unsigned int)-1) {
     unsigned int count = len;
     for (unsigned int i = 0; i < count; i++)
       info[i].mask = (info[i].mask & not_mask) | value;
     return;
   }

   unsigned int count = len;
   for (unsigned int i = 0; i < count; i++)
     if (cluster_start <= info[i].cluster && info[i].cluster < cluster_end)
       info[i].mask = (info[i].mask & not_mask) | value;
 }

 void
 hb_buffer_t::reverse_range (unsigned int start,
 			    unsigned int end)
 {
   unsigned int i, j;

   if (start == end - 1)
     return;

   for (i = start, j = end - 1; i < j; i++, j--) {
     hb_glyph_info_t t;

     t = info[i];
     info[i] = info[j];
     info[j] = t;
   }

   if (pos) {
     for (i = start, j = end - 1; i < j; i++, j--) {
       hb_glyph_position_t t;

       t = pos[i];
       pos[i] = pos[j];
       pos[j] = t;
     }
   }
 }

 void
 hb_buffer_t::reverse (void)
 {
   if (unlikely (!len))
     return;

   reverse_range (0, len);
 }

 void
 hb_buffer_t::reverse_clusters (void)
 {
   unsigned int i, start, count, last_cluster;

   if (unlikely (!len))
     return;

   reverse ();

   count = len;
   start = 0;
   last_cluster = info[0].cluster;
   for (i = 1; i < count; i++) {
     if (last_cluster != info[i].cluster) {
       reverse_range (start, i);
       start = i;
       last_cluster = info[i].cluster;
     }
   }
   reverse_range (start, i);
 }

 void
 hb_buffer_t::merge_clusters (unsigned int start,
 			     unsigned int end)
 {
   if (unlikely (end - start < 2))
     return;

   unsigned int cluster = info[start].cluster;

   for (unsigned int i = start + 1; i < end; i++)
     cluster = MIN (cluster, info[i].cluster);

   /* Extend end */
   while (end < len && info[end - 1].cluster == info[end].cluster)
     end++;

   /* Extend start */
   while (idx < start && info[start - 1].cluster == info[start].cluster)
     start--;

   /* If we hit the start of buffer, continue in out-buffer. */
   if (idx == start)
     for (unsigned i = out_len; i && out_info[i - 1].cluster == info[start].cluster; i--)
       out_info[i - 1].cluster = cluster;

   for (unsigned int i = start; i < end; i++)
     info[i].cluster = cluster;
 }
 void
 hb_buffer_t::merge_out_clusters (unsigned int start,
 				 unsigned int end)
 {
   if (unlikely (end - start < 2))
     return;

   unsigned int cluster = out_info[start].cluster;

   for (unsigned int i = start + 1; i < end; i++)
     cluster = MIN (cluster, out_info[i].cluster);

   /* Extend start */
   while (start && out_info[start - 1].cluster == out_info[start].cluster)
     start--;

   /* Extend end */
   while (end < out_len && out_info[end - 1].cluster == out_info[end].cluster)
     end++;

   /* If we hit the end of out-buffer, continue in buffer. */
   if (end == out_len)
     for (unsigned i = idx; i < len && info[i].cluster == out_info[end - 1].cluster; i++)
       info[i].cluster = cluster;

   for (unsigned int i = start; i < end; i++)
     out_info[i].cluster = cluster;
 }

 void
 hb_buffer_t::guess_properties (void)
 {
   /* If script is set to INVALID, guess from buffer contents */
   if (props.script == HB_SCRIPT_INVALID) {
     for (unsigned int i = 0; i < len; i++) {
       hb_script_t script = unicode->script (info[i].codepoint);
       if (likely (script != HB_SCRIPT_COMMON &&
 		  script != HB_SCRIPT_INHERITED &&
 		  script != HB_SCRIPT_UNKNOWN)) {
         props.script = script;
         break;
       }
     }
   }

   /* If direction is set to INVALID, guess from script */
   if (props.direction == HB_DIRECTION_INVALID) {
     props.direction = hb_script_get_horizontal_direction (props.script);
   }

   /* If language is not set, use default language from locale */
   if (props.language == HB_LANGUAGE_INVALID) {
     /* TODO get_default_for_script? using $LANGUAGE */
     props.language = hb_language_get_default ();
   }
 }


 static inline void
 dump_var_allocation (const hb_buffer_t *buffer)
 {
   char buf[80];
   for (unsigned int i = 0; i < 8; i++)
     buf[i] = '0' + buffer->allocated_var_bytes[7 - i];
   buf[8] = '\0';
   DEBUG_MSG (BUFFER, buffer,
 	     "Current var allocation: %s",
 	     buf);
 }

 void hb_buffer_t::allocate_var (unsigned int byte_i, unsigned int count, const char *owner)
 {
   assert (byte_i < 8 && byte_i + count <= 8);

   if (DEBUG (BUFFER))
     dump_var_allocation (this);
   DEBUG_MSG (BUFFER, this,
 	     "Allocating var bytes %d..%d for %s",
 	     byte_i, byte_i + count - 1, owner);

   for (unsigned int i = byte_i; i < byte_i + count; i++) {
     assert (!allocated_var_bytes[i]);
     allocated_var_bytes[i]++;
     allocated_var_owner[i] = owner;
   }
 }

 void hb_buffer_t::deallocate_var (unsigned int byte_i, unsigned int count, const char *owner)
 {
   if (DEBUG (BUFFER))
     dump_var_allocation (this);

   DEBUG_MSG (BUFFER, this,
 	     "Deallocating var bytes %d..%d for %s",
 	     byte_i, byte_i + count - 1, owner);

   assert (byte_i < 8 && byte_i + count <= 8);
   for (unsigned int i = byte_i; i < byte_i + count; i++) {
     assert (allocated_var_bytes[i]);
     assert (0 == strcmp (allocated_var_owner[i], owner));
     allocated_var_bytes[i]--;
   }
 }

 void hb_buffer_t::deallocate_var_all (void)
 {
   memset (allocated_var_bytes, 0, sizeof (allocated_var_bytes));
   memset (allocated_var_owner, 0, sizeof (allocated_var_owner));
 }

 /* Public API */

 hb_buffer_t *
 hb_buffer_create ()
 {
   hb_buffer_t *buffer;

   if (!(buffer = hb_object_create<hb_buffer_t> ()))
     return hb_buffer_get_empty ();

   buffer->reset ();

   return buffer;
 }

 hb_buffer_t *
 hb_buffer_get_empty (void)
 {
   static const hb_buffer_t _hb_buffer_nil = {
     HB_OBJECT_HEADER_STATIC,

     const_cast<hb_unicode_funcs_t *> (&_hb_unicode_funcs_nil),
     _HB_BUFFER_PROPS_DEFAULT,

     true, /* in_error */
     true, /* have_output */
     true  /* have_positions */
   };

   return const_cast<hb_buffer_t *> (&_hb_buffer_nil);
 }

 hb_buffer_t *
 hb_buffer_reference (hb_buffer_t *buffer)
 {
   return hb_object_reference (buffer);
 }

 void
 hb_buffer_destroy (hb_buffer_t *buffer)
 {
   if (!hb_object_destroy (buffer)) return;

   hb_unicode_funcs_destroy (buffer->unicode);

   free (buffer->info);
   free (buffer->pos);

   free (buffer);
 }

 hb_bool_t
 hb_buffer_set_user_data (hb_buffer_t        *buffer,
 			 hb_user_data_key_t *key,
 			 void *              data,
 			 hb_destroy_func_t   destroy,
 			 hb_bool_t           replace)
 {
   return hb_object_set_user_data (buffer, key, data, destroy, replace);
 }

 void *
 hb_buffer_get_user_data (hb_buffer_t        *buffer,
 			 hb_user_data_key_t *key)
 {
   return hb_object_get_user_data (buffer, key);
 }


 void
 hb_buffer_set_unicode_funcs (hb_buffer_t        *buffer,
 			     hb_unicode_funcs_t *unicode)
 {
   if (unlikely (hb_object_is_inert (buffer)))
     return;

   if (!unicode)
     unicode = hb_unicode_funcs_get_default ();


   hb_unicode_funcs_reference (unicode);
   hb_unicode_funcs_destroy (buffer->unicode);
   buffer->unicode = unicode;
 }

 hb_unicode_funcs_t *
 hb_buffer_get_unicode_funcs (hb_buffer_t        *buffer)
 {
   return buffer->unicode;
 }

 void
 hb_buffer_set_direction (hb_buffer_t    *buffer,
 			 hb_direction_t  direction)

 {
   if (unlikely (hb_object_is_inert (buffer)))
     return;

   buffer->props.direction = direction;
 }

 hb_direction_t
 hb_buffer_get_direction (hb_buffer_t    *buffer)
 {
   return buffer->props.direction;
 }

 void
 hb_buffer_set_script (hb_buffer_t *buffer,
 		      hb_script_t  script)
 {
   if (unlikely (hb_object_is_inert (buffer)))
     return;

   buffer->props.script = script;
 }

 hb_script_t
 hb_buffer_get_script (hb_buffer_t *buffer)
 {
   return buffer->props.script;
 }

 void
 hb_buffer_set_language (hb_buffer_t   *buffer,
 			hb_language_t  language)
 {
   if (unlikely (hb_object_is_inert (buffer)))
     return;

   buffer->props.language = language;
 }

 hb_language_t
 hb_buffer_get_language (hb_buffer_t *buffer)
 {
   return buffer->props.language;
 }


 void
 hb_buffer_reset (hb_buffer_t *buffer)
 {
   buffer->reset ();
 }

 hb_bool_t
 hb_buffer_pre_allocate (hb_buffer_t *buffer, unsigned int size)
 {
   return buffer->ensure (size);
 }

 hb_bool_t
 hb_buffer_allocation_successful (hb_buffer_t  *buffer)
 {
   return !buffer->in_error;
 }

 void
 hb_buffer_add (hb_buffer_t    *buffer,
 	       hb_codepoint_t  codepoint,
 	       hb_mask_t       mask,
 	       unsigned int    cluster)
 {
   buffer->add (codepoint, mask, cluster);
 }

 hb_bool_t
 hb_buffer_set_length (hb_buffer_t  *buffer,
 		      unsigned int  length)
 {
   if (unlikely (hb_object_is_inert (buffer)))
     return length == 0;

   if (!buffer->ensure (length))
     return false;

   /* Wipe the new space */
   if (length > buffer->len) {
     memset (buffer->info + buffer->len, 0, sizeof (buffer->info[0]) * (length - buffer->len));
     if (buffer->have_positions)
       memset (buffer->pos + buffer->len, 0, sizeof (buffer->pos[0]) * (length - buffer->len));
   }

   buffer->len = length;
   return true;
 }

 unsigned int
 hb_buffer_get_length (hb_buffer_t *buffer)
 {
   return buffer->len;
 }

 /* Return value valid as long as buffer not modified */
 hb_glyph_info_t *
 hb_buffer_get_glyph_infos (hb_buffer_t  *buffer,
                            unsigned int *length)
 {
   if (length)
     *length = buffer->len;

   return (hb_glyph_info_t *) buffer->info;
 }

 /* Return value valid as long as buffer not modified */
 hb_glyph_position_t *
 hb_buffer_get_glyph_positions (hb_buffer_t  *buffer,
                                unsigned int *length)
 {
   if (!buffer->have_positions)
     buffer->clear_positions ();

   if (length)
     *length = buffer->len;

   return (hb_glyph_position_t *) buffer->pos;
 }

 void
 hb_buffer_reverse (hb_buffer_t *buffer)
 {
   buffer->reverse ();
 }

 void
 hb_buffer_reverse_clusters (hb_buffer_t *buffer)
 {
   buffer->reverse_clusters ();
 }

 void
 hb_buffer_guess_properties (hb_buffer_t *buffer)
 {
   buffer->guess_properties ();
 }

 #define ADD_UTF(T) \
 	HB_STMT_START { \
 	  if (text_length == -1) { \
 	    text_length = 0; \
 	    const T *p = (const T *) text; \
 	    while (*p) { \
 	      text_length++; \
 	      p++; \
 	    } \
 	  } \
 	  if (item_length == -1) \
 	    item_length = text_length - item_offset; \
 	  buffer->ensure (buffer->len + item_length * sizeof (T) / 4); \
 	  const T *next = (const T *) text + item_offset; \
 	  const T *end = next + item_length; \
 	  while (next < end) { \
 	    hb_codepoint_t u; \
 	    const T *old_next = next; \
 	    next = UTF_NEXT (next, end, u); \
 	    hb_buffer_add (buffer, u, 1,  old_next - (const T *) text); \
 	  } \
 	} HB_STMT_END


 #define UTF8_COMPUTE(Char, Mask, Len) \
   if (Char < 128) { Len = 1; Mask = 0x7f; } \
   else if ((Char & 0xe0) == 0xc0) { Len = 2; Mask = 0x1f; } \
   else if ((Char & 0xf0) == 0xe0) { Len = 3; Mask = 0x0f; } \
   else if ((Char & 0xf8) == 0xf0) { Len = 4; Mask = 0x07; } \
   else Len = 0;

 static inline const uint8_t *
 hb_utf8_next (const uint8_t *text,
 	      const uint8_t *end,
 	      hb_codepoint_t *unicode)
 {
   uint8_t c = *text;
   unsigned int mask, len;

   /* TODO check for overlong sequences? */

   UTF8_COMPUTE (c, mask, len);
   if (unlikely (!len || (unsigned int) (end - text) < len)) {
     *unicode = -1;
     return text + 1;
   } else {
     hb_codepoint_t result;
     unsigned int i;
     result = c & mask;
     for (i = 1; i < len; i++)
       {
 	if (unlikely ((text[i] & 0xc0) != 0x80))
 	  {
 	    *unicode = -1;
 	    return text + 1;
 	  }
 	result <<= 6;
 	result |= (text[i] & 0x3f);
       }
     *unicode = result;
     return text + len;
   }
 }

 void
 hb_buffer_add_utf8 (hb_buffer_t  *buffer,
 		    const char   *text,
 		    int           text_length,
 		    unsigned int  item_offset,
 		    int           item_length)
 {
 #define UTF_NEXT(S, E, U)	hb_utf8_next (S, E, &(U))
   ADD_UTF (uint8_t);
 #undef UTF_NEXT
 }

 static inline const uint16_t *
 hb_utf16_next (const uint16_t *text,
 	       const uint16_t *end,
 	       hb_codepoint_t *unicode)
 {
   uint16_t c = *text++;

   if (unlikely (c >= 0xd800 && c < 0xdc00)) {
     /* high surrogate */
     uint16_t l;
     if (text < end && ((l = *text), likely (l >= 0xdc00 && l < 0xe000))) {
       /* low surrogate */
       *unicode = ((hb_codepoint_t) ((c) - 0xd800) * 0x400 + (l) - 0xdc00 + 0x10000);
        text++;
     } else
       *unicode = -1;
   } else
     *unicode = c;

   return text;
 }

 void
 hb_buffer_add_utf16 (hb_buffer_t    *buffer,
 		     const uint16_t *text,
 		     int             text_length,
 		     unsigned int    item_offset,
 		     int            item_length)
 {
 #define UTF_NEXT(S, E, U)	hb_utf16_next (S, E, &(U))
   ADD_UTF (uint16_t);
 #undef UTF_NEXT
 }

 void
 hb_buffer_add_utf32 (hb_buffer_t    *buffer,
 		     const uint32_t *text,
 		     int             text_length,
 		     unsigned int    item_offset,
 		     int             item_length)
 {
 #define UTF_NEXT(S, E, U)	((U) = *(S), (S)+1)
   ADD_UTF (uint32_t);
 #undef UTF_NEXT
 }


 static int
 compare_info_codepoint (const hb_glyph_info_t *pa,
 			const hb_glyph_info_t *pb)
 {
   return (int) pb->codepoint - (int) pa->codepoint;
 }

 static inline void
 normalize_glyphs_cluster (hb_buffer_t *buffer,
 			  unsigned int start,
 			  unsigned int end,
 			  bool backward)
 {
   hb_glyph_position_t *pos = buffer->pos;

   /* Total cluster advance */
   hb_position_t total_x_advance = 0, total_y_advance = 0;
   for (unsigned int i = start; i < end; i++)
   {
     total_x_advance += pos[i].x_advance;
     total_y_advance += pos[i].y_advance;
   }

   hb_position_t x_advance = 0, y_advance = 0;
   for (unsigned int i = start; i < end; i++)
   {
     pos[i].x_offset += x_advance;
     pos[i].y_offset += y_advance;

     x_advance += pos[i].x_advance;
     y_advance += pos[i].y_advance;

     pos[i].x_advance = 0;
     pos[i].y_advance = 0;
   }

   if (backward)
   {
     /* Transfer all cluster advance to the last glyph. */
     pos[end - 1].x_advance = total_x_advance;
     pos[end - 1].y_advance = total_y_advance;

     hb_bubble_sort (buffer->info + start, end - start - 1, compare_info_codepoint, buffer->pos + start);
   } else {
     /* Transfer all cluster advance to the first glyph. */
     pos[start].x_advance += total_x_advance;
     pos[start].y_advance += total_y_advance;
     for (unsigned int i = start + 1; i < end; i++) {
       pos[i].x_offset -= total_x_advance;
       pos[i].y_offset -= total_y_advance;
     }
     hb_bubble_sort (buffer->info + start + 1, end - start - 1, compare_info_codepoint, buffer->pos + start + 1);
   }
 }

 void
 hb_buffer_normalize_glyphs (hb_buffer_t *buffer)
 {
   assert (buffer->have_positions);
   /* XXX assert (buffer->have_glyphs); */

   bool backward = HB_DIRECTION_IS_BACKWARD (buffer->props.direction);

   unsigned int count = buffer->len;
   if (unlikely (!count)) return;
   hb_glyph_info_t *info = buffer->info;

   unsigned int start = 0;
   unsigned int end;
   for (end = start + 1; end < count; end++)
     if (info[start].cluster != info[end].cluster) {
       normalize_glyphs_cluster (buffer, start, end, backward);
       start = end;
     }
   normalize_glyphs_cluster (buffer, start, end, backward);
 }
	/*
	* Copyright © 1998-2004 David Turner and Werner Lemberg
	* Copyright © 2004,2007,2009,2010 Red Hat, Inc.
	* Copyright © 2011 Google, Inc.
	*
	* 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.
	*
	* Red Hat Author(s): Owen Taylor, Behdad Esfahbod
	* Google Author(s): Behdad Esfahbod
	*/

	#include "hb-buffer-private.hh"

	#include <string.h>



	#ifndef HB_DEBUG_BUFFER
	#define HB_DEBUG_BUFFER (HB_DEBUG+0)
	#endif

	/* Here is how the buffer works internally:
	*
	* There are two info pointers: info and out_info. They always have
	* the same allocated size, but different lengths.
	*
	* As an optimization, both info and out_info may point to the
	* same piece of memory, which is owned by info. This remains the
	* case as long as out_len doesn't exceed i at any time.
	* In that case, swap_buffers() is no-op and the glyph operations operate
	* mostly in-place.
	*
	* As soon as out_info gets longer than info, out_info is moved over
	* to an alternate buffer (which we reuse the pos buffer for!), and its
	* current contents (out_len entries) are copied to the new place.
	* This should all remain transparent to the user. swap_buffers() then
	* switches info and out_info.
	*/



	/* Internal API */

	bool
	hb_buffer_t::enlarge (unsigned int size)
	{
	if (unlikely (in_error))
	return false;

	unsigned int new_allocated = allocated;
	hb_glyph_position_t *new_pos = NULL;
	hb_glyph_info_t *new_info = NULL;
	bool separate_out = out_info != info;

	if (unlikely (_hb_unsigned_int_mul_overflows (size, sizeof (info[0]))))
	goto done;

	while (size > new_allocated)
	new_allocated += (new_allocated >> 1) + 32;

	ASSERT_STATIC (sizeof (info[0]) == sizeof (pos[0]));
	if (unlikely (_hb_unsigned_int_mul_overflows (new_allocated, sizeof (info[0]))))
	goto done;

	new_pos = (hb_glyph_position_t ) realloc (pos, new_allocated sizeof (pos[0]));
	new_info = (hb_glyph_info_t ) realloc (info, new_allocated sizeof (info[0]));

	done:
	if (unlikely (!new_pos \|\| !new_info))
	in_error = true;

	if (likely (new_pos))
	pos = new_pos;

	if (likely (new_info))
	info = new_info;

	out_info = separate_out ? (hb_glyph_info_t *) pos : info;
	if (likely (!in_error))
	allocated = new_allocated;

	return likely (!in_error);
	}

	bool
	hb_buffer_t::make_room_for (unsigned int num_in,
	unsigned int num_out)
	{
	if (unlikely (!ensure (out_len + num_out))) return false;

	if (out_info == info &&
	out_len + num_out > idx + num_in)
	{
	assert (have_output);

	out_info = (hb_glyph_info_t *) pos;
	memcpy (out_info, info, out_len * sizeof (out_info[0]));
	}

	return true;
	}

	void *
	hb_buffer_t::get_scratch_buffer (unsigned int *size)
	{
	have_output = false;
	have_positions = false;

	out_len = 0;
	out_info = info;

	size = allocated sizeof (pos[0]);
	return pos;
	}



	/* HarfBuzz-Internal API */

	void
	hb_buffer_t::reset (void)
	{
	if (unlikely (hb_object_is_inert (this)))
	return;

	hb_unicode_funcs_destroy (unicode);
	unicode = hb_unicode_funcs_get_default ();

	hb_segment_properties_t default_props = _HB_BUFFER_PROPS_DEFAULT;
	props = default_props;

	in_error = false;
	have_output = false;
	have_positions = false;

	idx = 0;
	len = 0;
	out_len = 0;
	out_info = info;

	serial = 0;
	memset (allocated_var_bytes, 0, sizeof allocated_var_bytes);
	memset (allocated_var_owner, 0, sizeof allocated_var_owner);
	}

	void
	hb_buffer_t::add (hb_codepoint_t codepoint,
	hb_mask_t mask,
	unsigned int cluster)
	{
	hb_glyph_info_t *glyph;

	if (unlikely (!ensure (len + 1))) return;

	glyph = &info[len];

	memset (glyph, 0, sizeof (*glyph));
	glyph->codepoint = codepoint;
	glyph->mask = mask;
	glyph->cluster = cluster;

	len++;
	}

	void
	hb_buffer_t::clear_output (void)
	{
	if (unlikely (hb_object_is_inert (this)))
	return;

	have_output = true;
	have_positions = false;

	out_len = 0;
	out_info = info;
	}

	void
	hb_buffer_t::clear_positions (void)
	{
	if (unlikely (hb_object_is_inert (this)))
	return;

	have_output = false;
	have_positions = true;

	out_len = 0;
	out_info = info;

	memset (pos, 0, sizeof (pos[0]) * len);
	}

	void
	hb_buffer_t::swap_buffers (void)
	{
	if (unlikely (in_error)) return;

	assert (have_output);
	have_output = false;

	if (out_info != info)
	{
	hb_glyph_info_t *tmp_string;
	tmp_string = info;
	info = out_info;
	out_info = tmp_string;
	pos = (hb_glyph_position_t *) out_info;
	}

	unsigned int tmp;
	tmp = len;
	len = out_len;
	out_len = tmp;

	idx = 0;
	}


	void
	hb_buffer_t::replace_glyphs (unsigned int num_in,
	unsigned int num_out,
	const uint32_t *glyph_data)
	{
	if (unlikely (!make_room_for (num_in, num_out))) return;

	merge_clusters (idx, idx + num_in);

	hb_glyph_info_t orig_info = info[idx];
	hb_glyph_info_t *pinfo = &out_info[out_len];
	for (unsigned int i = 0; i < num_out; i++)
	{
	*pinfo = orig_info;
	pinfo->codepoint = glyph_data[i];
	pinfo++;
	}

	idx += num_in;
	out_len += num_out;
	}

	void
	hb_buffer_t::output_glyph (hb_codepoint_t glyph_index)
	{
	if (unlikely (!make_room_for (0, 1))) return;

	out_info[out_len] = info[idx];
	out_info[out_len].codepoint = glyph_index;

	out_len++;
	}

	void
	hb_buffer_t::copy_glyph (void)
	{
	if (unlikely (!make_room_for (0, 1))) return;

	out_info[out_len] = info[idx];

	out_len++;
	}

	void
	hb_buffer_t::replace_glyph (hb_codepoint_t glyph_index)
	{
	if (unlikely (out_info != info \|\| out_len != idx)) {
	if (unlikely (!make_room_for (1, 1))) return;
	out_info[out_len] = info[idx];
	}
	out_info[out_len].codepoint = glyph_index;

	idx++;
	out_len++;
	}

	void
	hb_buffer_t::next_glyph (void)
	{
	if (have_output)
	{
	if (unlikely (out_info != info \|\| out_len != idx)) {
	if (unlikely (!make_room_for (1, 1))) return;
	out_info[out_len] = info[idx];
	}
	out_len++;
	}

	idx++;
	}


	void
	hb_buffer_t::set_masks (hb_mask_t value,
	hb_mask_t mask,
	unsigned int cluster_start,
	unsigned int cluster_end)
	{
	hb_mask_t not_mask = ~mask;
	value &= mask;

	if (!mask)
	return;

	if (cluster_start == 0 && cluster_end == (unsigned int)-1) {
	unsigned int count = len;
	for (unsigned int i = 0; i < count; i++)
	info[i].mask = (info[i].mask & not_mask) \| value;
	return;
	}

	unsigned int count = len;
	for (unsigned int i = 0; i < count; i++)
	if (cluster_start <= info[i].cluster && info[i].cluster < cluster_end)
	info[i].mask = (info[i].mask & not_mask) \| value;
	}

	void
	hb_buffer_t::reverse_range (unsigned int start,
	unsigned int end)
	{
	unsigned int i, j;

	if (start == end - 1)
	return;

	for (i = start, j = end - 1; i < j; i++, j--) {
	hb_glyph_info_t t;

	t = info[i];
	info[i] = info[j];
	info[j] = t;
	}

	if (pos) {
	for (i = start, j = end - 1; i < j; i++, j--) {
	hb_glyph_position_t t;

	t = pos[i];
	pos[i] = pos[j];
	pos[j] = t;
	}
	}
	}

	void
	hb_buffer_t::reverse (void)
	{
	if (unlikely (!len))
	return;

	reverse_range (0, len);
	}

	void
	hb_buffer_t::reverse_clusters (void)
	{
	unsigned int i, start, count, last_cluster;

	if (unlikely (!len))
	return;

	reverse ();

	count = len;
	start = 0;
	last_cluster = info[0].cluster;
	for (i = 1; i < count; i++) {
	if (last_cluster != info[i].cluster) {
	reverse_range (start, i);
	start = i;
	last_cluster = info[i].cluster;
	}
	}
	reverse_range (start, i);
	}

	void
	hb_buffer_t::merge_clusters (unsigned int start,
	unsigned int end)
	{
	if (unlikely (end - start < 2))
	return;

	unsigned int cluster = info[start].cluster;

	for (unsigned int i = start + 1; i < end; i++)
	cluster = MIN (cluster, info[i].cluster);

	/* Extend end */
	while (end < len && info[end - 1].cluster == info[end].cluster)
	end++;

	/* Extend start */
	while (idx < start && info[start - 1].cluster == info[start].cluster)
	start--;

	/* If we hit the start of buffer, continue in out-buffer. */
	if (idx == start)
	for (unsigned i = out_len; i && out_info[i - 1].cluster == info[start].cluster; i--)
	out_info[i - 1].cluster = cluster;

	for (unsigned int i = start; i < end; i++)
	info[i].cluster = cluster;
	}
	void
	hb_buffer_t::merge_out_clusters (unsigned int start,
	unsigned int end)
	{
	if (unlikely (end - start < 2))
	return;

	unsigned int cluster = out_info[start].cluster;

	for (unsigned int i = start + 1; i < end; i++)
	cluster = MIN (cluster, out_info[i].cluster);

	/* Extend start */
	while (start && out_info[start - 1].cluster == out_info[start].cluster)
	start--;

	/* Extend end */
	while (end < out_len && out_info[end - 1].cluster == out_info[end].cluster)
	end++;

	/* If we hit the end of out-buffer, continue in buffer. */
	if (end == out_len)
	for (unsigned i = idx; i < len && info[i].cluster == out_info[end - 1].cluster; i++)
	info[i].cluster = cluster;

	for (unsigned int i = start; i < end; i++)
	out_info[i].cluster = cluster;
	}

	void
	hb_buffer_t::guess_properties (void)
	{
	/* If script is set to INVALID, guess from buffer contents */
	if (props.script == HB_SCRIPT_INVALID) {
	for (unsigned int i = 0; i < len; i++) {
	hb_script_t script = unicode->script (info[i].codepoint);
	if (likely (script != HB_SCRIPT_COMMON &&
	script != HB_SCRIPT_INHERITED &&
	script != HB_SCRIPT_UNKNOWN)) {
	props.script = script;
	break;
	}
	}
	}

	/* If direction is set to INVALID, guess from script */
	if (props.direction == HB_DIRECTION_INVALID) {
	props.direction = hb_script_get_horizontal_direction (props.script);
	}

	/* If language is not set, use default language from locale */
	if (props.language == HB_LANGUAGE_INVALID) {
	/* TODO get_default_for_script? using $LANGUAGE */
	props.language = hb_language_get_default ();
	}
	}


	static inline void
	dump_var_allocation (const hb_buffer_t *buffer)
	{
	char buf[80];
	for (unsigned int i = 0; i < 8; i++)
	buf[i] = '0' + buffer->allocated_var_bytes[7 - i];
	buf[8] = '\0';
	DEBUG_MSG (BUFFER, buffer,
	"Current var allocation: %s",
	buf);
	}

	void hb_buffer_t::allocate_var (unsigned int byte_i, unsigned int count, const char *owner)
	{
	assert (byte_i < 8 && byte_i + count <= 8);

	if (DEBUG (BUFFER))
	dump_var_allocation (this);
	DEBUG_MSG (BUFFER, this,
	"Allocating var bytes %d..%d for %s",
	byte_i, byte_i + count - 1, owner);

	for (unsigned int i = byte_i; i < byte_i + count; i++) {
	assert (!allocated_var_bytes[i]);
	allocated_var_bytes[i]++;
	allocated_var_owner[i] = owner;
	}
	}

	void hb_buffer_t::deallocate_var (unsigned int byte_i, unsigned int count, const char *owner)
	{
	if (DEBUG (BUFFER))
	dump_var_allocation (this);

	DEBUG_MSG (BUFFER, this,
	"Deallocating var bytes %d..%d for %s",
	byte_i, byte_i + count - 1, owner);

	assert (byte_i < 8 && byte_i + count <= 8);
	for (unsigned int i = byte_i; i < byte_i + count; i++) {
	assert (allocated_var_bytes[i]);
	assert (0 == strcmp (allocated_var_owner[i], owner));
	allocated_var_bytes[i]--;
	}
	}

	void hb_buffer_t::deallocate_var_all (void)
	{
	memset (allocated_var_bytes, 0, sizeof (allocated_var_bytes));
	memset (allocated_var_owner, 0, sizeof (allocated_var_owner));
	}

	/* Public API */

	hb_buffer_t *
	hb_buffer_create ()
	{
	hb_buffer_t *buffer;

	if (!(buffer = hb_object_create<hb_buffer_t> ()))
	return hb_buffer_get_empty ();

	buffer->reset ();

	return buffer;
	}

	hb_buffer_t *
	hb_buffer_get_empty (void)
	{
	static const hb_buffer_t _hb_buffer_nil = {
	HB_OBJECT_HEADER_STATIC,

	const_cast<hb_unicode_funcs_t *> (&_hb_unicode_funcs_nil),
	_HB_BUFFER_PROPS_DEFAULT,

	true, /* in_error */
	true, /* have_output */
	true /* have_positions */
	};

	return const_cast<hb_buffer_t *> (&_hb_buffer_nil);
	}

	hb_buffer_t *
	hb_buffer_reference (hb_buffer_t *buffer)
	{
	return hb_object_reference (buffer);
	}

	void
	hb_buffer_destroy (hb_buffer_t *buffer)
	{
	if (!hb_object_destroy (buffer)) return;

	hb_unicode_funcs_destroy (buffer->unicode);

	free (buffer->info);
	free (buffer->pos);

	free (buffer);
	}

	hb_bool_t
	hb_buffer_set_user_data (hb_buffer_t *buffer,
	hb_user_data_key_t *key,
	void * data,
	hb_destroy_func_t destroy,
	hb_bool_t replace)
	{
	return hb_object_set_user_data (buffer, key, data, destroy, replace);
	}

	void *
	hb_buffer_get_user_data (hb_buffer_t *buffer,
	hb_user_data_key_t *key)
	{
	return hb_object_get_user_data (buffer, key);
	}


	void
	hb_buffer_set_unicode_funcs (hb_buffer_t *buffer,
	hb_unicode_funcs_t *unicode)
	{
	if (unlikely (hb_object_is_inert (buffer)))
	return;

	if (!unicode)
	unicode = hb_unicode_funcs_get_default ();


	hb_unicode_funcs_reference (unicode);
	hb_unicode_funcs_destroy (buffer->unicode);
	buffer->unicode = unicode;
	}

	hb_unicode_funcs_t *
	hb_buffer_get_unicode_funcs (hb_buffer_t *buffer)
	{
	return buffer->unicode;
	}

	void
	hb_buffer_set_direction (hb_buffer_t *buffer,
	hb_direction_t direction)

	{
	if (unlikely (hb_object_is_inert (buffer)))
	return;

	buffer->props.direction = direction;
	}

	hb_direction_t
	hb_buffer_get_direction (hb_buffer_t *buffer)
	{
	return buffer->props.direction;
	}

	void
	hb_buffer_set_script (hb_buffer_t *buffer,
	hb_script_t script)
	{
	if (unlikely (hb_object_is_inert (buffer)))
	return;

	buffer->props.script = script;
	}

	hb_script_t
	hb_buffer_get_script (hb_buffer_t *buffer)
	{
	return buffer->props.script;
	}

	void
	hb_buffer_set_language (hb_buffer_t *buffer,
	hb_language_t language)
	{
	if (unlikely (hb_object_is_inert (buffer)))
	return;

	buffer->props.language = language;
	}

	hb_language_t
	hb_buffer_get_language (hb_buffer_t *buffer)
	{
	return buffer->props.language;
	}


	void
	hb_buffer_reset (hb_buffer_t *buffer)
	{
	buffer->reset ();
	}

	hb_bool_t
	hb_buffer_pre_allocate (hb_buffer_t *buffer, unsigned int size)
	{
	return buffer->ensure (size);
	}

	hb_bool_t
	hb_buffer_allocation_successful (hb_buffer_t *buffer)
	{
	return !buffer->in_error;
	}

	void
	hb_buffer_add (hb_buffer_t *buffer,
	hb_codepoint_t codepoint,
	hb_mask_t mask,
	unsigned int cluster)
	{
	buffer->add (codepoint, mask, cluster);
	}

	hb_bool_t
	hb_buffer_set_length (hb_buffer_t *buffer,
	unsigned int length)
	{
	if (unlikely (hb_object_is_inert (buffer)))
	return length == 0;

	if (!buffer->ensure (length))
	return false;

	/* Wipe the new space */
	if (length > buffer->len) {
	memset (buffer->info + buffer->len, 0, sizeof (buffer->info[0]) * (length - buffer->len));
	if (buffer->have_positions)
	memset (buffer->pos + buffer->len, 0, sizeof (buffer->pos[0]) * (length - buffer->len));
	}

	buffer->len = length;
	return true;
	}

	unsigned int
	hb_buffer_get_length (hb_buffer_t *buffer)
	{
	return buffer->len;
	}

	/* Return value valid as long as buffer not modified */
	hb_glyph_info_t *
	hb_buffer_get_glyph_infos (hb_buffer_t *buffer,
	unsigned int *length)
	{
	if (length)
	*length = buffer->len;

	return (hb_glyph_info_t *) buffer->info;
	}

	/* Return value valid as long as buffer not modified */
	hb_glyph_position_t *
	hb_buffer_get_glyph_positions (hb_buffer_t *buffer,
	unsigned int *length)
	{
	if (!buffer->have_positions)
	buffer->clear_positions ();

	if (length)
	*length = buffer->len;

	return (hb_glyph_position_t *) buffer->pos;
	}

	void
	hb_buffer_reverse (hb_buffer_t *buffer)
	{
	buffer->reverse ();
	}

	void
	hb_buffer_reverse_clusters (hb_buffer_t *buffer)
	{
	buffer->reverse_clusters ();
	}

	void
	hb_buffer_guess_properties (hb_buffer_t *buffer)
	{
	buffer->guess_properties ();
	}

	#define ADD_UTF(T) \
	HB_STMT_START { \
	if (text_length == -1) { \
	text_length = 0; \
	const T p = (const T ) text; \
	while (*p) { \
	text_length++; \
	p++; \
	} \
	} \
	if (item_length == -1) \
	item_length = text_length - item_offset; \
	buffer->ensure (buffer->len + item_length * sizeof (T) / 4); \
	const T next = (const T ) text + item_offset; \
	const T *end = next + item_length; \
	while (next < end) { \
	hb_codepoint_t u; \
	const T *old_next = next; \
	next = UTF_NEXT (next, end, u); \
	hb_buffer_add (buffer, u, 1, old_next - (const T *) text); \
	} \
	} HB_STMT_END


	#define UTF8_COMPUTE(Char, Mask, Len) \
	if (Char < 128) { Len = 1; Mask = 0x7f; } \
	else if ((Char & 0xe0) == 0xc0) { Len = 2; Mask = 0x1f; } \
	else if ((Char & 0xf0) == 0xe0) { Len = 3; Mask = 0x0f; } \
	else if ((Char & 0xf8) == 0xf0) { Len = 4; Mask = 0x07; } \
	else Len = 0;

	static inline const uint8_t *
	hb_utf8_next (const uint8_t *text,
	const uint8_t *end,
	hb_codepoint_t *unicode)
	{
	uint8_t c = *text;
	unsigned int mask, len;

	/* TODO check for overlong sequences? */

	UTF8_COMPUTE (c, mask, len);
	if (unlikely (!len \|\| (unsigned int) (end - text) < len)) {
	*unicode = -1;
	return text + 1;
	} else {
	hb_codepoint_t result;
	unsigned int i;
	result = c & mask;
	for (i = 1; i < len; i++)
	{
	if (unlikely ((text[i] & 0xc0) != 0x80))
	{
	*unicode = -1;
	return text + 1;
	}
	result <<= 6;
	result \|= (text[i] & 0x3f);
	}
	*unicode = result;
	return text + len;
	}
	}

	void
	hb_buffer_add_utf8 (hb_buffer_t *buffer,
	const char *text,
	int text_length,
	unsigned int item_offset,
	int item_length)
	{
	#define UTF_NEXT(S, E, U) hb_utf8_next (S, E, &(U))
	ADD_UTF (uint8_t);
	#undef UTF_NEXT
	}

	static inline const uint16_t *
	hb_utf16_next (const uint16_t *text,
	const uint16_t *end,
	hb_codepoint_t *unicode)
	{
	uint16_t c = *text++;

	if (unlikely (c >= 0xd800 && c < 0xdc00)) {
	/* high surrogate */
	uint16_t l;
	if (text < end && ((l = *text), likely (l >= 0xdc00 && l < 0xe000))) {
	/* low surrogate */
	unicode = ((hb_codepoint_t) ((c) - 0xd800) 0x400 + (l) - 0xdc00 + 0x10000);
	text++;
	} else
	*unicode = -1;
	} else
	*unicode = c;

	return text;
	}

	void
	hb_buffer_add_utf16 (hb_buffer_t *buffer,
	const uint16_t *text,
	int text_length,
	unsigned int item_offset,
	int item_length)
	{
	#define UTF_NEXT(S, E, U) hb_utf16_next (S, E, &(U))
	ADD_UTF (uint16_t);
	#undef UTF_NEXT
	}

	void
	hb_buffer_add_utf32 (hb_buffer_t *buffer,
	const uint32_t *text,
	int text_length,
	unsigned int item_offset,
	int item_length)
	{
	#define UTF_NEXT(S, E, U) ((U) = *(S), (S)+1)
	ADD_UTF (uint32_t);
	#undef UTF_NEXT
	}


	static int
	compare_info_codepoint (const hb_glyph_info_t *pa,
	const hb_glyph_info_t *pb)
	{
	return (int) pb->codepoint - (int) pa->codepoint;
	}

	static inline void
	normalize_glyphs_cluster (hb_buffer_t *buffer,
	unsigned int start,
	unsigned int end,
	bool backward)
	{
	hb_glyph_position_t *pos = buffer->pos;

	/* Total cluster advance */
	hb_position_t total_x_advance = 0, total_y_advance = 0;
	for (unsigned int i = start; i < end; i++)
	{
	total_x_advance += pos[i].x_advance;
	total_y_advance += pos[i].y_advance;
	}

	hb_position_t x_advance = 0, y_advance = 0;
	for (unsigned int i = start; i < end; i++)
	{
	pos[i].x_offset += x_advance;
	pos[i].y_offset += y_advance;

	x_advance += pos[i].x_advance;
	y_advance += pos[i].y_advance;

	pos[i].x_advance = 0;
	pos[i].y_advance = 0;
	}

	if (backward)
	{
	/* Transfer all cluster advance to the last glyph. */
	pos[end - 1].x_advance = total_x_advance;
	pos[end - 1].y_advance = total_y_advance;

	hb_bubble_sort (buffer->info + start, end - start - 1, compare_info_codepoint, buffer->pos + start);
	} else {
	/* Transfer all cluster advance to the first glyph. */
	pos[start].x_advance += total_x_advance;
	pos[start].y_advance += total_y_advance;
	for (unsigned int i = start + 1; i < end; i++) {
	pos[i].x_offset -= total_x_advance;
	pos[i].y_offset -= total_y_advance;
	}
	hb_bubble_sort (buffer->info + start + 1, end - start - 1, compare_info_codepoint, buffer->pos + start + 1);
	}
	}

	void
	hb_buffer_normalize_glyphs (hb_buffer_t *buffer)
	{
	assert (buffer->have_positions);
	/* XXX assert (buffer->have_glyphs); */

	bool backward = HB_DIRECTION_IS_BACKWARD (buffer->props.direction);

	unsigned int count = buffer->len;
	if (unlikely (!count)) return;
	hb_glyph_info_t *info = buffer->info;

	unsigned int start = 0;
	unsigned int end;
	for (end = start + 1; end < count; end++)
	if (info[start].cluster != info[end].cluster) {
	normalize_glyphs_cluster (buffer, start, end, backward);
	start = end;
	}
	normalize_glyphs_cluster (buffer, start, end, backward);
	}