misc/libfreetype/src/sfnt/ttcmap.c
author sheepluva
Wed, 19 Oct 2011 16:10:18 +0200
changeset 6151 9fd5b70acb1a
parent 5172 88f2e05288ba
permissions -rw-r--r--
give the room name edit box a history of previous room. however I hate that box from the bottom of my heart, it shall dieeeee... later...

/***************************************************************************/
/*                                                                         */
/*  ttcmap.c                                                               */
/*                                                                         */
/*    TrueType character mapping table (cmap) support (body).              */
/*                                                                         */
/*  Copyright 2002, 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010 by      */
/*  David Turner, Robert Wilhelm, and Werner Lemberg.                      */
/*                                                                         */
/*  This file is part of the FreeType project, and may only be used,       */
/*  modified, and distributed under the terms of the FreeType project      */
/*  license, LICENSE.TXT.  By continuing to use, modify, or distribute     */
/*  this file you indicate that you have read the license and              */
/*  understand and accept it fully.                                        */
/*                                                                         */
/***************************************************************************/


#include <ft2build.h>
#include FT_INTERNAL_DEBUG_H

#include "sferrors.h"           /* must come before FT_INTERNAL_VALIDATE_H */

#include FT_INTERNAL_VALIDATE_H
#include FT_INTERNAL_STREAM_H
#include "ttload.h"
#include "ttcmap.h"
#include "sfntpic.h"


  /*************************************************************************/
  /*                                                                       */
  /* The macro FT_COMPONENT is used in trace mode.  It is an implicit      */
  /* parameter of the FT_TRACE() and FT_ERROR() macros, used to print/log  */
  /* messages during execution.                                            */
  /*                                                                       */
#undef  FT_COMPONENT
#define FT_COMPONENT  trace_ttcmap


#define TT_PEEK_SHORT   FT_PEEK_SHORT
#define TT_PEEK_USHORT  FT_PEEK_USHORT
#define TT_PEEK_UINT24  FT_PEEK_UOFF3
#define TT_PEEK_LONG    FT_PEEK_LONG
#define TT_PEEK_ULONG   FT_PEEK_ULONG

#define TT_NEXT_SHORT   FT_NEXT_SHORT
#define TT_NEXT_USHORT  FT_NEXT_USHORT
#define TT_NEXT_UINT24  FT_NEXT_UOFF3
#define TT_NEXT_LONG    FT_NEXT_LONG
#define TT_NEXT_ULONG   FT_NEXT_ULONG


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap_init( TT_CMap   cmap,
                FT_Byte*  table )
  {
    cmap->data = table;
    return SFNT_Err_Ok;
  }


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                           FORMAT 0                            *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET         TYPE          DESCRIPTION                */
  /*                                                                       */
  /*   format      0              USHORT        must be 0                  */
  /*   length      2              USHORT        table length in bytes      */
  /*   language    4              USHORT        Mac language code          */
  /*   glyph_ids   6              BYTE[256]     array of glyph indices     */
  /*               262                                                     */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_0

  FT_CALLBACK_DEF( FT_Error )
  tt_cmap0_validate( FT_Byte*      table,
                     FT_Validator  valid )
  {
    FT_Byte*  p      = table + 2;
    FT_UInt   length = TT_NEXT_USHORT( p );


    if ( table + length > valid->limit || length < 262 )
      FT_INVALID_TOO_SHORT;

    /* check glyph indices whenever necessary */
    if ( valid->level >= FT_VALIDATE_TIGHT )
    {
      FT_UInt  n, idx;


      p = table + 6;
      for ( n = 0; n < 256; n++ )
      {
        idx = *p++;
        if ( idx >= TT_VALID_GLYPH_COUNT( valid ) )
          FT_INVALID_GLYPH_ID;
      }
    }

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap0_char_index( TT_CMap    cmap,
                       FT_UInt32  char_code )
  {
    FT_Byte*  table = cmap->data;


    return char_code < 256 ? table[6 + char_code] : 0;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap0_char_next( TT_CMap     cmap,
                      FT_UInt32  *pchar_code )
  {
    FT_Byte*   table    = cmap->data;
    FT_UInt32  charcode = *pchar_code;
    FT_UInt32  result   = 0;
    FT_UInt    gindex   = 0;


    table += 6;  /* go to glyph IDs */
    while ( ++charcode < 256 )
    {
      gindex = table[charcode];
      if ( gindex != 0 )
      {
        result = charcode;
        break;
      }
    }

    *pchar_code = result;
    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap0_get_info( TT_CMap       cmap,
                     TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 4;


    cmap_info->format   = 0;
    cmap_info->language = (FT_ULong)TT_PEEK_USHORT( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap0_class_rec,
      sizeof ( TT_CMapRec ),

      (FT_CMap_InitFunc)     tt_cmap_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap0_char_index,
      (FT_CMap_CharNextFunc) tt_cmap0_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    0,
    (TT_CMap_ValidateFunc)   tt_cmap0_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap0_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_0 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 2                             *****/
  /*****                                                               *****/
  /***** This is used for certain CJK encodings that encode text in a  *****/
  /***** mixed 8/16 bits encoding along the following lines:           *****/
  /*****                                                               *****/
  /***** * Certain byte values correspond to an 8-bit character code   *****/
  /*****   (typically in the range 0..127 for ASCII compatibility).    *****/
  /*****                                                               *****/
  /***** * Certain byte values signal the first byte of a 2-byte       *****/
  /*****   character code (but these values are also valid as the      *****/
  /*****   second byte of a 2-byte character).                         *****/
  /*****                                                               *****/
  /***** The following charmap lookup and iteration functions all      *****/
  /***** assume that the value "charcode" correspond to following:     *****/
  /*****                                                               *****/
  /*****   - For one byte characters, "charcode" is simply the         *****/
  /*****     character code.                                           *****/
  /*****                                                               *****/
  /*****   - For two byte characters, "charcode" is the 2-byte         *****/
  /*****     character code in big endian format.  More exactly:       *****/
  /*****                                                               *****/
  /*****       (charcode >> 8)    is the first byte value              *****/
  /*****       (charcode & 0xFF)  is the second byte value             *****/
  /*****                                                               *****/
  /***** Note that not all values of "charcode" are valid according    *****/
  /***** to these rules, and the function moderately check the         *****/
  /***** arguments.                                                    *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET         TYPE            DESCRIPTION              */
  /*                                                                       */
  /*   format      0              USHORT          must be 2                */
  /*   length      2              USHORT          table length in bytes    */
  /*   language    4              USHORT          Mac language code        */
  /*   keys        6              USHORT[256]     sub-header keys          */
  /*   subs        518            SUBHEAD[NSUBS]  sub-headers array        */
  /*   glyph_ids   518+NSUB*8     USHORT[]        glyph ID array           */
  /*                                                                       */
  /* The `keys' table is used to map charcode high-bytes to sub-headers.   */
  /* The value of `NSUBS' is the number of sub-headers defined in the      */
  /* table and is computed by finding the maximum of the `keys' table.     */
  /*                                                                       */
  /* Note that for any n, `keys[n]' is a byte offset within the `subs'     */
  /* table, i.e., it is the corresponding sub-header index multiplied      */
  /* by 8.                                                                 */
  /*                                                                       */
  /* Each sub-header has the following format:                             */
  /*                                                                       */
  /*   NAME        OFFSET      TYPE            DESCRIPTION                 */
  /*                                                                       */
  /*   first       0           USHORT          first valid low-byte        */
  /*   count       2           USHORT          number of valid low-bytes   */
  /*   delta       4           SHORT           see below                   */
  /*   offset      6           USHORT          see below                   */
  /*                                                                       */
  /* A sub-header defines, for each high-byte, the range of valid          */
  /* low-bytes within the charmap.  Note that the range defined by `first' */
  /* and `count' must be completely included in the interval [0..255]      */
  /* according to the specification.                                       */
  /*                                                                       */
  /* If a character code is contained within a given sub-header, then      */
  /* mapping it to a glyph index is done as follows:                       */
  /*                                                                       */
  /* * The value of `offset' is read.  This is a _byte_ distance from the  */
  /*   location of the `offset' field itself into a slice of the           */
  /*   `glyph_ids' table.  Let's call it `slice' (it is a USHORT[] too).   */
  /*                                                                       */
  /* * The value `slice[char.lo - first]' is read.  If it is 0, there is   */
  /*   no glyph for the charcode.  Otherwise, the value of `delta' is      */
  /*   added to it (modulo 65536) to form a new glyph index.               */
  /*                                                                       */
  /* It is up to the validation routine to check that all offsets fall     */
  /* within the glyph IDs table (and not within the `subs' table itself or */
  /* outside of the CMap).                                                 */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_2

  FT_CALLBACK_DEF( FT_Error )
  tt_cmap2_validate( FT_Byte*      table,
                     FT_Validator  valid )
  {
    FT_Byte*  p      = table + 2;           /* skip format */
    FT_UInt   length = TT_PEEK_USHORT( p );
    FT_UInt   n, max_subs;
    FT_Byte*  keys;                         /* keys table */
    FT_Byte*  subs;                         /* sub-headers */
    FT_Byte*  glyph_ids;                    /* glyph ID array */


    if ( table + length > valid->limit || length < 6 + 512 )
      FT_INVALID_TOO_SHORT;

    keys = table + 6;

    /* parse keys to compute sub-headers count */
    p        = keys;
    max_subs = 0;
    for ( n = 0; n < 256; n++ )
    {
      FT_UInt  idx = TT_NEXT_USHORT( p );


      /* value must be multiple of 8 */
      if ( valid->level >= FT_VALIDATE_PARANOID && ( idx & 7 ) != 0 )
        FT_INVALID_DATA;

      idx >>= 3;

      if ( idx > max_subs )
        max_subs = idx;
    }

    FT_ASSERT( p == table + 518 );

    subs      = p;
    glyph_ids = subs + (max_subs + 1) * 8;
    if ( glyph_ids > valid->limit )
      FT_INVALID_TOO_SHORT;

    /* parse sub-headers */
    for ( n = 0; n <= max_subs; n++ )
    {
      FT_UInt   first_code, code_count, offset;
      FT_Int    delta;
      FT_Byte*  ids;


      first_code = TT_NEXT_USHORT( p );
      code_count = TT_NEXT_USHORT( p );
      delta      = TT_NEXT_SHORT( p );
      offset     = TT_NEXT_USHORT( p );

      /* many Dynalab fonts have empty sub-headers */
      if ( code_count == 0 )
        continue;

      /* check range within 0..255 */
      if ( valid->level >= FT_VALIDATE_PARANOID )
      {
        if ( first_code >= 256 || first_code + code_count > 256 )
          FT_INVALID_DATA;
      }

      /* check offset */
      if ( offset != 0 )
      {
        ids = p - 2 + offset;
        if ( ids < glyph_ids || ids + code_count*2 > table + length )
          FT_INVALID_OFFSET;

        /* check glyph IDs */
        if ( valid->level >= FT_VALIDATE_TIGHT )
        {
          FT_Byte*  limit = p + code_count * 2;
          FT_UInt   idx;


          for ( ; p < limit; )
          {
            idx = TT_NEXT_USHORT( p );
            if ( idx != 0 )
            {
              idx = ( idx + delta ) & 0xFFFFU;
              if ( idx >= TT_VALID_GLYPH_COUNT( valid ) )
                FT_INVALID_GLYPH_ID;
            }
          }
        }
      }
    }

    return SFNT_Err_Ok;
  }


  /* return sub header corresponding to a given character code */
  /* NULL on invalid charcode                                  */
  static FT_Byte*
  tt_cmap2_get_subheader( FT_Byte*   table,
                          FT_UInt32  char_code )
  {
    FT_Byte*  result = NULL;


    if ( char_code < 0x10000UL )
    {
      FT_UInt   char_lo = (FT_UInt)( char_code & 0xFF );
      FT_UInt   char_hi = (FT_UInt)( char_code >> 8 );
      FT_Byte*  p       = table + 6;    /* keys table */
      FT_Byte*  subs    = table + 518;  /* subheaders table */
      FT_Byte*  sub;


      if ( char_hi == 0 )
      {
        /* an 8-bit character code -- we use subHeader 0 in this case */
        /* to test whether the character code is in the charmap       */
        /*                                                            */
        sub = subs;  /* jump to first sub-header */

        /* check that the sub-header for this byte is 0, which */
        /* indicates that it is really a valid one-byte value  */
        /* Otherwise, return 0                                 */
        /*                                                     */
        p += char_lo * 2;
        if ( TT_PEEK_USHORT( p ) != 0 )
          goto Exit;
      }
      else
      {
        /* a 16-bit character code */

        /* jump to key entry  */
        p  += char_hi * 2;
        /* jump to sub-header */
        sub = subs + ( FT_PAD_FLOOR( TT_PEEK_USHORT( p ), 8 ) );

        /* check that the high byte isn't a valid one-byte value */
        if ( sub == subs )
          goto Exit;
      }
      result = sub;
    }
  Exit:
    return result;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap2_char_index( TT_CMap    cmap,
                       FT_UInt32  char_code )
  {
    FT_Byte*  table   = cmap->data;
    FT_UInt   result  = 0;
    FT_Byte*  subheader;


    subheader = tt_cmap2_get_subheader( table, char_code );
    if ( subheader )
    {
      FT_Byte*  p   = subheader;
      FT_UInt   idx = (FT_UInt)(char_code & 0xFF);
      FT_UInt   start, count;
      FT_Int    delta;
      FT_UInt   offset;


      start  = TT_NEXT_USHORT( p );
      count  = TT_NEXT_USHORT( p );
      delta  = TT_NEXT_SHORT ( p );
      offset = TT_PEEK_USHORT( p );

      idx -= start;
      if ( idx < count && offset != 0 )
      {
        p  += offset + 2 * idx;
        idx = TT_PEEK_USHORT( p );

        if ( idx != 0 )
          result = (FT_UInt)( idx + delta ) & 0xFFFFU;
      }
    }
    return result;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap2_char_next( TT_CMap     cmap,
                      FT_UInt32  *pcharcode )
  {
    FT_Byte*   table    = cmap->data;
    FT_UInt    gindex   = 0;
    FT_UInt32  result   = 0;
    FT_UInt32  charcode = *pcharcode + 1;
    FT_Byte*   subheader;


    while ( charcode < 0x10000UL )
    {
      subheader = tt_cmap2_get_subheader( table, charcode );
      if ( subheader )
      {
        FT_Byte*  p       = subheader;
        FT_UInt   start   = TT_NEXT_USHORT( p );
        FT_UInt   count   = TT_NEXT_USHORT( p );
        FT_Int    delta   = TT_NEXT_SHORT ( p );
        FT_UInt   offset  = TT_PEEK_USHORT( p );
        FT_UInt   char_lo = (FT_UInt)( charcode & 0xFF );
        FT_UInt   pos, idx;


        if ( offset == 0 )
          goto Next_SubHeader;

        if ( char_lo < start )
        {
          char_lo = start;
          pos     = 0;
        }
        else
          pos = (FT_UInt)( char_lo - start );

        p       += offset + pos * 2;
        charcode = FT_PAD_FLOOR( charcode, 256 ) + char_lo;

        for ( ; pos < count; pos++, charcode++ )
        {
          idx = TT_NEXT_USHORT( p );

          if ( idx != 0 )
          {
            gindex = ( idx + delta ) & 0xFFFFU;
            if ( gindex != 0 )
            {
              result = charcode;
              goto Exit;
            }
          }
        }
      }

      /* jump to next sub-header, i.e. higher byte value */
    Next_SubHeader:
      charcode = FT_PAD_FLOOR( charcode, 256 ) + 256;
    }

  Exit:
    *pcharcode = result;

    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap2_get_info( TT_CMap       cmap,
                     TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 4;


    cmap_info->format   = 2;
    cmap_info->language = (FT_ULong)TT_PEEK_USHORT( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap2_class_rec,
      sizeof ( TT_CMapRec ),

      (FT_CMap_InitFunc)     tt_cmap_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap2_char_index,
      (FT_CMap_CharNextFunc) tt_cmap2_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    2,
    (TT_CMap_ValidateFunc)   tt_cmap2_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap2_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_2 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                           FORMAT 4                            *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME          OFFSET         TYPE              DESCRIPTION          */
  /*                                                                       */
  /*   format        0              USHORT            must be 4            */
  /*   length        2              USHORT            table length         */
  /*                                                  in bytes             */
  /*   language      4              USHORT            Mac language code    */
  /*                                                                       */
  /*   segCountX2    6              USHORT            2*NUM_SEGS           */
  /*   searchRange   8              USHORT            2*(1 << LOG_SEGS)    */
  /*   entrySelector 10             USHORT            LOG_SEGS             */
  /*   rangeShift    12             USHORT            segCountX2 -         */
  /*                                                    searchRange        */
  /*                                                                       */
  /*   endCount      14             USHORT[NUM_SEGS]  end charcode for     */
  /*                                                  each segment; last   */
  /*                                                  is 0xFFFF            */
  /*                                                                       */
  /*   pad           14+NUM_SEGS*2  USHORT            padding              */
  /*                                                                       */
  /*   startCount    16+NUM_SEGS*2  USHORT[NUM_SEGS]  first charcode for   */
  /*                                                  each segment         */
  /*                                                                       */
  /*   idDelta       16+NUM_SEGS*4  SHORT[NUM_SEGS]   delta for each       */
  /*                                                  segment              */
  /*   idOffset      16+NUM_SEGS*6  SHORT[NUM_SEGS]   range offset for     */
  /*                                                  each segment; can be */
  /*                                                  zero                 */
  /*                                                                       */
  /*   glyphIds      16+NUM_SEGS*8  USHORT[]          array of glyph ID    */
  /*                                                  ranges               */
  /*                                                                       */
  /* Character codes are modelled by a series of ordered (increasing)      */
  /* intervals called segments.  Each segment has start and end codes,     */
  /* provided by the `startCount' and `endCount' arrays.  Segments must    */
  /* not overlap, and the last segment should always contain the value     */
  /* 0xFFFF for `endCount'.                                                */
  /*                                                                       */
  /* The fields `searchRange', `entrySelector' and `rangeShift' are better */
  /* ignored (they are traces of over-engineering in the TrueType          */
  /* specification).                                                       */
  /*                                                                       */
  /* Each segment also has a signed `delta', as well as an optional offset */
  /* within the `glyphIds' table.                                          */
  /*                                                                       */
  /* If a segment's idOffset is 0, the glyph index corresponding to any    */
  /* charcode within the segment is obtained by adding the value of        */
  /* `idDelta' directly to the charcode, modulo 65536.                     */
  /*                                                                       */
  /* Otherwise, a glyph index is taken from the glyph IDs sub-array for    */
  /* the segment, and the value of `idDelta' is added to it.               */
  /*                                                                       */
  /*                                                                       */
  /* Finally, note that a lot of fonts contain an invalid last segment,    */
  /* where `start' and `end' are correctly set to 0xFFFF but both `delta'  */
  /* and `offset' are incorrect (e.g., `opens___.ttf' which comes with     */
  /* OpenOffice.org).  We need special code to deal with them correctly.   */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_4

  typedef struct  TT_CMap4Rec_
  {
    TT_CMapRec  cmap;
    FT_UInt32   cur_charcode;   /* current charcode */
    FT_UInt     cur_gindex;     /* current glyph index */

    FT_UInt     num_ranges;
    FT_UInt     cur_range;
    FT_UInt     cur_start;
    FT_UInt     cur_end;
    FT_Int      cur_delta;
    FT_Byte*    cur_values;

  } TT_CMap4Rec, *TT_CMap4;


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap4_init( TT_CMap4  cmap,
                 FT_Byte*  table )
  {
    FT_Byte*  p;


    cmap->cmap.data    = table;

    p                  = table + 6;
    cmap->num_ranges   = FT_PEEK_USHORT( p ) >> 1;
    cmap->cur_charcode = (FT_UInt32)0xFFFFFFFFUL;
    cmap->cur_gindex   = 0;

    return SFNT_Err_Ok;
  }


  static FT_Int
  tt_cmap4_set_range( TT_CMap4  cmap,
                      FT_UInt   range_index )
  {
    FT_Byte*  table = cmap->cmap.data;
    FT_Byte*  p;
    FT_UInt   num_ranges = cmap->num_ranges;


    while ( range_index < num_ranges )
    {
      FT_UInt  offset;


      p             = table + 14 + range_index * 2;
      cmap->cur_end = FT_PEEK_USHORT( p );

      p              += 2 + num_ranges * 2;
      cmap->cur_start = FT_PEEK_USHORT( p );

      p              += num_ranges * 2;
      cmap->cur_delta = FT_PEEK_SHORT( p );

      p     += num_ranges * 2;
      offset = FT_PEEK_USHORT( p );

      /* some fonts have an incorrect last segment; */
      /* we have to catch it                        */
      if ( range_index     >= num_ranges - 1 &&
           cmap->cur_start == 0xFFFFU        &&
           cmap->cur_end   == 0xFFFFU        )
      {
        TT_Face   face  = (TT_Face)cmap->cmap.cmap.charmap.face;
        FT_Byte*  limit = face->cmap_table + face->cmap_size;


        if ( offset && p + offset + 2 > limit )
        {
          cmap->cur_delta = 1;
          offset          = 0;
        }
      }

      if ( offset != 0xFFFFU )
      {
        cmap->cur_values = offset ? p + offset : NULL;
        cmap->cur_range  = range_index;
        return 0;
      }

      /* we skip empty segments */
      range_index++;
    }

    return -1;
  }


  /* search the index of the charcode next to cmap->cur_charcode; */
  /* caller should call tt_cmap4_set_range with proper range      */
  /* before calling this function                                 */
  /*                                                              */
  static void
  tt_cmap4_next( TT_CMap4  cmap )
  {
    FT_UInt  charcode;


    if ( cmap->cur_charcode >= 0xFFFFUL )
      goto Fail;

    charcode = (FT_UInt)cmap->cur_charcode + 1;

    if ( charcode < cmap->cur_start )
      charcode = cmap->cur_start;

    for ( ;; )
    {
      FT_Byte*  values = cmap->cur_values;
      FT_UInt   end    = cmap->cur_end;
      FT_Int    delta  = cmap->cur_delta;


      if ( charcode <= end )
      {
        if ( values )
        {
          FT_Byte*  p = values + 2 * ( charcode - cmap->cur_start );


          do
          {
            FT_UInt  gindex = FT_NEXT_USHORT( p );


            if ( gindex != 0 )
            {
              gindex = (FT_UInt)( ( gindex + delta ) & 0xFFFFU );
              if ( gindex != 0 )
              {
                cmap->cur_charcode = charcode;
                cmap->cur_gindex   = gindex;
                return;
              }
            }
          } while ( ++charcode <= end );
        }
        else
        {
          do
          {
            FT_UInt  gindex = (FT_UInt)( ( charcode + delta ) & 0xFFFFU );


            if ( gindex != 0 )
            {
              cmap->cur_charcode = charcode;
              cmap->cur_gindex   = gindex;
              return;
            }
          } while ( ++charcode <= end );
        }
      }

      /* we need to find another range */
      if ( tt_cmap4_set_range( cmap, cmap->cur_range + 1 ) < 0 )
        break;

      if ( charcode < cmap->cur_start )
        charcode = cmap->cur_start;
    }

  Fail:
    cmap->cur_charcode = (FT_UInt32)0xFFFFFFFFUL;
    cmap->cur_gindex   = 0;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap4_validate( FT_Byte*      table,
                     FT_Validator  valid )
  {
    FT_Byte*  p      = table + 2;               /* skip format */
    FT_UInt   length = TT_NEXT_USHORT( p );
    FT_Byte   *ends, *starts, *offsets, *deltas, *glyph_ids;
    FT_UInt   num_segs;
    FT_Error  error = SFNT_Err_Ok;


    if ( length < 16 )
      FT_INVALID_TOO_SHORT;

    /* in certain fonts, the `length' field is invalid and goes */
    /* out of bound.  We try to correct this here...            */
    if ( table + length > valid->limit )
    {
      if ( valid->level >= FT_VALIDATE_TIGHT )
        FT_INVALID_TOO_SHORT;

      length = (FT_UInt)( valid->limit - table );
    }

    p        = table + 6;
    num_segs = TT_NEXT_USHORT( p );   /* read segCountX2 */

    if ( valid->level >= FT_VALIDATE_PARANOID )
    {
      /* check that we have an even value here */
      if ( num_segs & 1 )
        FT_INVALID_DATA;
    }

    num_segs /= 2;

    if ( length < 16 + num_segs * 2 * 4 )
      FT_INVALID_TOO_SHORT;

    /* check the search parameters - even though we never use them */
    /*                                                             */
    if ( valid->level >= FT_VALIDATE_PARANOID )
    {
      /* check the values of `searchRange', `entrySelector', `rangeShift' */
      FT_UInt  search_range   = TT_NEXT_USHORT( p );
      FT_UInt  entry_selector = TT_NEXT_USHORT( p );
      FT_UInt  range_shift    = TT_NEXT_USHORT( p );


      if ( ( search_range | range_shift ) & 1 )  /* must be even values */
        FT_INVALID_DATA;

      search_range /= 2;
      range_shift  /= 2;

      /* `search range' is the greatest power of 2 that is <= num_segs */

      if ( search_range                > num_segs                 ||
           search_range * 2            < num_segs                 ||
           search_range + range_shift != num_segs                 ||
           search_range               != ( 1U << entry_selector ) )
        FT_INVALID_DATA;
    }

    ends      = table   + 14;
    starts    = table   + 16 + num_segs * 2;
    deltas    = starts  + num_segs * 2;
    offsets   = deltas  + num_segs * 2;
    glyph_ids = offsets + num_segs * 2;

    /* check last segment; its end count value must be 0xFFFF */
    if ( valid->level >= FT_VALIDATE_PARANOID )
    {
      p = ends + ( num_segs - 1 ) * 2;
      if ( TT_PEEK_USHORT( p ) != 0xFFFFU )
        FT_INVALID_DATA;
    }

    {
      FT_UInt   start, end, offset, n;
      FT_UInt   last_start = 0, last_end = 0;
      FT_Int    delta;
      FT_Byte*  p_start   = starts;
      FT_Byte*  p_end     = ends;
      FT_Byte*  p_delta   = deltas;
      FT_Byte*  p_offset  = offsets;


      for ( n = 0; n < num_segs; n++ )
      {
        p      = p_offset;
        start  = TT_NEXT_USHORT( p_start );
        end    = TT_NEXT_USHORT( p_end );
        delta  = TT_NEXT_SHORT( p_delta );
        offset = TT_NEXT_USHORT( p_offset );

        if ( start > end )
          FT_INVALID_DATA;

        /* this test should be performed at default validation level; */
        /* unfortunately, some popular Asian fonts have overlapping   */
        /* ranges in their charmaps                                   */
        /*                                                            */
        if ( start <= last_end && n > 0 )
        {
          if ( valid->level >= FT_VALIDATE_TIGHT )
            FT_INVALID_DATA;
          else
          {
            /* allow overlapping segments, provided their start points */
            /* and end points, respectively, are in ascending order    */
            /*                                                         */
            if ( last_start > start || last_end > end )
              error |= TT_CMAP_FLAG_UNSORTED;
            else
              error |= TT_CMAP_FLAG_OVERLAPPING;
          }
        }

        if ( offset && offset != 0xFFFFU )
        {
          p += offset;  /* start of glyph ID array */

          /* check that we point within the glyph IDs table only */
          if ( valid->level >= FT_VALIDATE_TIGHT )
          {
            if ( p < glyph_ids                                ||
                 p + ( end - start + 1 ) * 2 > table + length )
              FT_INVALID_DATA;
          }
          /* Some fonts handle the last segment incorrectly.  In */
          /* theory, 0xFFFF might point to an ordinary glyph --  */
          /* a cmap 4 is versatile and could be used for any     */
          /* encoding, not only Unicode.  However, reality shows */
          /* that far too many fonts are sloppy and incorrectly  */
          /* set all fields but `start' and `end' for the last   */
          /* segment if it contains only a single character.     */
          /*                                                     */
          /* We thus omit the test here, delaying it to the      */
          /* routines which actually access the cmap.            */
          else if ( n != num_segs - 1                       ||
                    !( start == 0xFFFFU && end == 0xFFFFU ) )
          {
            if ( p < glyph_ids                              ||
                 p + ( end - start + 1 ) * 2 > valid->limit )
              FT_INVALID_DATA;
          }

          /* check glyph indices within the segment range */
          if ( valid->level >= FT_VALIDATE_TIGHT )
          {
            FT_UInt  i, idx;


            for ( i = start; i < end; i++ )
            {
              idx = FT_NEXT_USHORT( p );
              if ( idx != 0 )
              {
                idx = (FT_UInt)( idx + delta ) & 0xFFFFU;

                if ( idx >= TT_VALID_GLYPH_COUNT( valid ) )
                  FT_INVALID_GLYPH_ID;
              }
            }
          }
        }
        else if ( offset == 0xFFFFU )
        {
          /* some fonts (erroneously?) use a range offset of 0xFFFF */
          /* to mean missing glyph in cmap table                    */
          /*                                                        */
          if ( valid->level >= FT_VALIDATE_PARANOID    ||
               n != num_segs - 1                       ||
               !( start == 0xFFFFU && end == 0xFFFFU ) )
            FT_INVALID_DATA;
        }

        last_start = start;
        last_end   = end;
      }
    }

    return error;
  }


  static FT_UInt
  tt_cmap4_char_map_linear( TT_CMap     cmap,
                            FT_UInt32*  pcharcode,
                            FT_Bool     next )
  {
    FT_UInt    num_segs2, start, end, offset;
    FT_Int     delta;
    FT_UInt    i, num_segs;
    FT_UInt32  charcode = *pcharcode;
    FT_UInt    gindex   = 0;
    FT_Byte*   p;


    p = cmap->data + 6;
    num_segs2 = FT_PAD_FLOOR( TT_PEEK_USHORT( p ), 2 );

    num_segs = num_segs2 >> 1;

    if ( !num_segs )
      return 0;

    if ( next )
      charcode++;

    /* linear search */
    for ( ; charcode <= 0xFFFFU; charcode++ )
    {
      FT_Byte*  q;


      p = cmap->data + 14;               /* ends table   */
      q = cmap->data + 16 + num_segs2;   /* starts table */

      for ( i = 0; i < num_segs; i++ )
      {
        end   = TT_NEXT_USHORT( p );
        start = TT_NEXT_USHORT( q );

        if ( charcode >= start && charcode <= end )
        {
          p       = q - 2 + num_segs2;
          delta   = TT_PEEK_SHORT( p );
          p      += num_segs2;
          offset  = TT_PEEK_USHORT( p );

          /* some fonts have an incorrect last segment; */
          /* we have to catch it                        */
          if ( i >= num_segs - 1                  &&
               start == 0xFFFFU && end == 0xFFFFU )
          {
            TT_Face   face  = (TT_Face)cmap->cmap.charmap.face;
            FT_Byte*  limit = face->cmap_table + face->cmap_size;


            if ( offset && p + offset + 2 > limit )
            {
              delta  = 1;
              offset = 0;
            }
          }

          if ( offset == 0xFFFFU )
            continue;

          if ( offset )
          {
            p += offset + ( charcode - start ) * 2;
            gindex = TT_PEEK_USHORT( p );
            if ( gindex != 0 )
              gindex = (FT_UInt)( gindex + delta ) & 0xFFFFU;
          }
          else
            gindex = (FT_UInt)( charcode + delta ) & 0xFFFFU;

          break;
        }
      }

      if ( !next || gindex )
        break;
    }

    if ( next && gindex )
      *pcharcode = charcode;

    return gindex;
  }


  static FT_UInt
  tt_cmap4_char_map_binary( TT_CMap     cmap,
                            FT_UInt32*  pcharcode,
                            FT_Bool     next )
  {
    FT_UInt   num_segs2, start, end, offset;
    FT_Int    delta;
    FT_UInt   max, min, mid, num_segs;
    FT_UInt   charcode = (FT_UInt)*pcharcode;
    FT_UInt   gindex   = 0;
    FT_Byte*  p;


    p = cmap->data + 6;
    num_segs2 = FT_PAD_FLOOR( TT_PEEK_USHORT( p ), 2 );

    if ( !num_segs2 )
      return 0;

    num_segs = num_segs2 >> 1;

    /* make compiler happy */
    mid = num_segs;
    end = 0xFFFFU;

    if ( next )
      charcode++;

    min = 0;
    max = num_segs;

    /* binary search */
    while ( min < max )
    {
      mid    = ( min + max ) >> 1;
      p      = cmap->data + 14 + mid * 2;
      end    = TT_PEEK_USHORT( p );
      p     += 2 + num_segs2;
      start  = TT_PEEK_USHORT( p );

      if ( charcode < start )
        max = mid;
      else if ( charcode > end )
        min = mid + 1;
      else
      {
        p     += num_segs2;
        delta  = TT_PEEK_SHORT( p );
        p     += num_segs2;
        offset = TT_PEEK_USHORT( p );

        /* some fonts have an incorrect last segment; */
        /* we have to catch it                        */
        if ( mid >= num_segs - 1                &&
             start == 0xFFFFU && end == 0xFFFFU )
        {
          TT_Face   face  = (TT_Face)cmap->cmap.charmap.face;
          FT_Byte*  limit = face->cmap_table + face->cmap_size;


          if ( offset && p + offset + 2 > limit )
          {
            delta  = 1;
            offset = 0;
          }
        }

        /* search the first segment containing `charcode' */
        if ( cmap->flags & TT_CMAP_FLAG_OVERLAPPING )
        {
          FT_UInt  i;


          /* call the current segment `max' */
          max = mid;

          if ( offset == 0xFFFFU )
            mid = max + 1;

          /* search in segments before the current segment */
          for ( i = max ; i > 0; i-- )
          {
            FT_UInt   prev_end;
            FT_Byte*  old_p;


            old_p    = p;
            p        = cmap->data + 14 + ( i - 1 ) * 2;
            prev_end = TT_PEEK_USHORT( p );

            if ( charcode > prev_end )
            {
              p = old_p;
              break;
            }

            end    = prev_end;
            p     += 2 + num_segs2;
            start  = TT_PEEK_USHORT( p );
            p     += num_segs2;
            delta  = TT_PEEK_SHORT( p );
            p     += num_segs2;
            offset = TT_PEEK_USHORT( p );

            if ( offset != 0xFFFFU )
              mid = i - 1;
          }

          /* no luck */
          if ( mid == max + 1 )
          {
            if ( i != max )
            {
              p      = cmap->data + 14 + max * 2;
              end    = TT_PEEK_USHORT( p );
              p     += 2 + num_segs2;
              start  = TT_PEEK_USHORT( p );
              p     += num_segs2;
              delta  = TT_PEEK_SHORT( p );
              p     += num_segs2;
              offset = TT_PEEK_USHORT( p );
            }

            mid = max;

            /* search in segments after the current segment */
            for ( i = max + 1; i < num_segs; i++ )
            {
              FT_UInt  next_end, next_start;


              p          = cmap->data + 14 + i * 2;
              next_end   = TT_PEEK_USHORT( p );
              p         += 2 + num_segs2;
              next_start = TT_PEEK_USHORT( p );

              if ( charcode < next_start )
                break;

              end    = next_end;
              start  = next_start;
              p     += num_segs2;
              delta  = TT_PEEK_SHORT( p );
              p     += num_segs2;
              offset = TT_PEEK_USHORT( p );

              if ( offset != 0xFFFFU )
                mid = i;
            }
            i--;

            /* still no luck */
            if ( mid == max )
            {
              mid = i;

              break;
            }
          }

          /* end, start, delta, and offset are for the i'th segment */
          if ( mid != i )
          {
            p      = cmap->data + 14 + mid * 2;
            end    = TT_PEEK_USHORT( p );
            p     += 2 + num_segs2;
            start  = TT_PEEK_USHORT( p );
            p     += num_segs2;
            delta  = TT_PEEK_SHORT( p );
            p     += num_segs2;
            offset = TT_PEEK_USHORT( p );
          }
        }
        else
        {
          if ( offset == 0xFFFFU )
            break;
        }

        if ( offset )
        {
          p += offset + ( charcode - start ) * 2;
          gindex = TT_PEEK_USHORT( p );
          if ( gindex != 0 )
            gindex = (FT_UInt)( gindex + delta ) & 0xFFFFU;
        }
        else
          gindex = (FT_UInt)( charcode + delta ) & 0xFFFFU;

        break;
      }
    }

    if ( next )
    {
      TT_CMap4  cmap4 = (TT_CMap4)cmap;


      /* if `charcode' is not in any segment, then `mid' is */
      /* the segment nearest to `charcode'                  */
      /*                                                    */

      if ( charcode > end )
      {
        mid++;
        if ( mid == num_segs )
          return 0;
      }

      if ( tt_cmap4_set_range( cmap4, mid ) )
      {
        if ( gindex )
          *pcharcode = charcode;
      }
      else
      {
        cmap4->cur_charcode = charcode;

        if ( gindex )
          cmap4->cur_gindex = gindex;
        else
        {
          cmap4->cur_charcode = charcode;
          tt_cmap4_next( cmap4 );
          gindex = cmap4->cur_gindex;
        }

        if ( gindex )
          *pcharcode = cmap4->cur_charcode;
      }
    }

    return gindex;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap4_char_index( TT_CMap    cmap,
                       FT_UInt32  char_code )
  {
    if ( char_code >= 0x10000UL )
      return 0;

    if ( cmap->flags & TT_CMAP_FLAG_UNSORTED )
      return tt_cmap4_char_map_linear( cmap, &char_code, 0 );
    else
      return tt_cmap4_char_map_binary( cmap, &char_code, 0 );
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap4_char_next( TT_CMap     cmap,
                      FT_UInt32  *pchar_code )
  {
    FT_UInt  gindex;


    if ( *pchar_code >= 0xFFFFU )
      return 0;

    if ( cmap->flags & TT_CMAP_FLAG_UNSORTED )
      gindex = tt_cmap4_char_map_linear( cmap, pchar_code, 1 );
    else
    {
      TT_CMap4  cmap4 = (TT_CMap4)cmap;


      /* no need to search */
      if ( *pchar_code == cmap4->cur_charcode )
      {
        tt_cmap4_next( cmap4 );
        gindex = cmap4->cur_gindex;
        if ( gindex )
          *pchar_code = cmap4->cur_charcode;
      }
      else
        gindex = tt_cmap4_char_map_binary( cmap, pchar_code, 1 );
    }

    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap4_get_info( TT_CMap       cmap,
                     TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 4;


    cmap_info->format   = 4;
    cmap_info->language = (FT_ULong)TT_PEEK_USHORT( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap4_class_rec,
      sizeof ( TT_CMap4Rec ),
      (FT_CMap_InitFunc)     tt_cmap4_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap4_char_index,
      (FT_CMap_CharNextFunc) tt_cmap4_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    4,
    (TT_CMap_ValidateFunc)   tt_cmap4_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap4_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_4 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 6                             *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET          TYPE             DESCRIPTION            */
  /*                                                                       */
  /*   format       0              USHORT           must be 4              */
  /*   length       2              USHORT           table length in bytes  */
  /*   language     4              USHORT           Mac language code      */
  /*                                                                       */
  /*   first        6              USHORT           first segment code     */
  /*   count        8              USHORT           segment size in chars  */
  /*   glyphIds     10             USHORT[count]    glyph IDs              */
  /*                                                                       */
  /* A very simplified segment mapping.                                    */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_6

  FT_CALLBACK_DEF( FT_Error )
  tt_cmap6_validate( FT_Byte*      table,
                     FT_Validator  valid )
  {
    FT_Byte*  p;
    FT_UInt   length, count;


    if ( table + 10 > valid->limit )
      FT_INVALID_TOO_SHORT;

    p      = table + 2;
    length = TT_NEXT_USHORT( p );

    p      = table + 8;             /* skip language and start index */
    count  = TT_NEXT_USHORT( p );

    if ( table + length > valid->limit || length < 10 + count * 2 )
      FT_INVALID_TOO_SHORT;

    /* check glyph indices */
    if ( valid->level >= FT_VALIDATE_TIGHT )
    {
      FT_UInt  gindex;


      for ( ; count > 0; count-- )
      {
        gindex = TT_NEXT_USHORT( p );
        if ( gindex >= TT_VALID_GLYPH_COUNT( valid ) )
          FT_INVALID_GLYPH_ID;
      }
    }

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap6_char_index( TT_CMap    cmap,
                       FT_UInt32  char_code )
  {
    FT_Byte*  table  = cmap->data;
    FT_UInt   result = 0;
    FT_Byte*  p      = table + 6;
    FT_UInt   start  = TT_NEXT_USHORT( p );
    FT_UInt   count  = TT_NEXT_USHORT( p );
    FT_UInt   idx    = (FT_UInt)( char_code - start );


    if ( idx < count )
    {
      p += 2 * idx;
      result = TT_PEEK_USHORT( p );
    }
    return result;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap6_char_next( TT_CMap     cmap,
                      FT_UInt32  *pchar_code )
  {
    FT_Byte*   table     = cmap->data;
    FT_UInt32  result    = 0;
    FT_UInt32  char_code = *pchar_code + 1;
    FT_UInt    gindex    = 0;

    FT_Byte*   p         = table + 6;
    FT_UInt    start     = TT_NEXT_USHORT( p );
    FT_UInt    count     = TT_NEXT_USHORT( p );
    FT_UInt    idx;


    if ( char_code >= 0x10000UL )
      goto Exit;

    if ( char_code < start )
      char_code = start;

    idx = (FT_UInt)( char_code - start );
    p  += 2 * idx;

    for ( ; idx < count; idx++ )
    {
      gindex = TT_NEXT_USHORT( p );
      if ( gindex != 0 )
      {
        result = char_code;
        break;
      }
      char_code++;
    }

  Exit:
    *pchar_code = result;
    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap6_get_info( TT_CMap       cmap,
                     TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 4;


    cmap_info->format   = 6;
    cmap_info->language = (FT_ULong)TT_PEEK_USHORT( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap6_class_rec,
      sizeof ( TT_CMapRec ),

      (FT_CMap_InitFunc)     tt_cmap_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap6_char_index,
      (FT_CMap_CharNextFunc) tt_cmap6_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    6,
    (TT_CMap_ValidateFunc)   tt_cmap6_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap6_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_6 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 8                             *****/
  /*****                                                               *****/
  /***** It is hard to completely understand what the OpenType spec    *****/
  /***** says about this format, but here is my conclusion.            *****/
  /*****                                                               *****/
  /***** The purpose of this format is to easily map UTF-16 text to    *****/
  /***** glyph indices.  Basically, the `char_code' must be in one of  *****/
  /***** the following formats:                                        *****/
  /*****                                                               *****/
  /*****   - A 16-bit value that isn't part of the Unicode Surrogates  *****/
  /*****     Area (i.e. U+D800-U+DFFF).                                *****/
  /*****                                                               *****/
  /*****   - A 32-bit value, made of two surrogate values, i.e.. if    *****/
  /*****     `char_code = (char_hi << 16) | char_lo', then both        *****/
  /*****     `char_hi' and `char_lo' must be in the Surrogates Area.   *****/
  /*****      Area.                                                    *****/
  /*****                                                               *****/
  /***** The `is32' table embedded in the charmap indicates whether a  *****/
  /***** given 16-bit value is in the surrogates area or not.          *****/
  /*****                                                               *****/
  /***** So, for any given `char_code', we can assert the following:   *****/
  /*****                                                               *****/
  /*****   If `char_hi == 0' then we must have `is32[char_lo] == 0'.   *****/
  /*****                                                               *****/
  /*****   If `char_hi != 0' then we must have both                    *****/
  /*****   `is32[char_hi] != 0' and `is32[char_lo] != 0'.              *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET         TYPE        DESCRIPTION                  */
  /*                                                                       */
  /*   format      0              USHORT      must be 8                    */
  /*   reserved    2              USHORT      reserved                     */
  /*   length      4              ULONG       length in bytes              */
  /*   language    8              ULONG       Mac language code            */
  /*   is32        12             BYTE[8192]  32-bitness bitmap            */
  /*   count       8204           ULONG       number of groups             */
  /*                                                                       */
  /* This header is followed by `count' groups of the following format:    */
  /*                                                                       */
  /*   start       0              ULONG       first charcode               */
  /*   end         4              ULONG       last charcode                */
  /*   startId     8              ULONG       start glyph ID for the group */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_8

  FT_CALLBACK_DEF( FT_Error )
  tt_cmap8_validate( FT_Byte*      table,
                     FT_Validator  valid )
  {
    FT_Byte*   p = table + 4;
    FT_Byte*   is32;
    FT_UInt32  length;
    FT_UInt32  num_groups;


    if ( table + 16 + 8192 > valid->limit )
      FT_INVALID_TOO_SHORT;

    length = TT_NEXT_ULONG( p );
    if ( length > (FT_UInt32)( valid->limit - table ) || length < 8192 + 16 )
      FT_INVALID_TOO_SHORT;

    is32       = table + 12;
    p          = is32  + 8192;          /* skip `is32' array */
    num_groups = TT_NEXT_ULONG( p );

    if ( p + num_groups * 12 > valid->limit )
      FT_INVALID_TOO_SHORT;

    /* check groups, they must be in increasing order */
    {
      FT_UInt32  n, start, end, start_id, count, last = 0;


      for ( n = 0; n < num_groups; n++ )
      {
        FT_UInt   hi, lo;


        start    = TT_NEXT_ULONG( p );
        end      = TT_NEXT_ULONG( p );
        start_id = TT_NEXT_ULONG( p );

        if ( start > end )
          FT_INVALID_DATA;

        if ( n > 0 && start <= last )
          FT_INVALID_DATA;

        if ( valid->level >= FT_VALIDATE_TIGHT )
        {
          if ( start_id + end - start >= TT_VALID_GLYPH_COUNT( valid ) )
            FT_INVALID_GLYPH_ID;

          count = (FT_UInt32)( end - start + 1 );

          if ( start & ~0xFFFFU )
          {
            /* start_hi != 0; check that is32[i] is 1 for each i in */
            /* the `hi' and `lo' of the range [start..end]          */
            for ( ; count > 0; count--, start++ )
            {
              hi = (FT_UInt)( start >> 16 );
              lo = (FT_UInt)( start & 0xFFFFU );

              if ( (is32[hi >> 3] & ( 0x80 >> ( hi & 7 ) ) ) == 0 )
                FT_INVALID_DATA;

              if ( (is32[lo >> 3] & ( 0x80 >> ( lo & 7 ) ) ) == 0 )
                FT_INVALID_DATA;
            }
          }
          else
          {
            /* start_hi == 0; check that is32[i] is 0 for each i in */
            /* the range [start..end]                               */

            /* end_hi cannot be != 0! */
            if ( end & ~0xFFFFU )
              FT_INVALID_DATA;

            for ( ; count > 0; count--, start++ )
            {
              lo = (FT_UInt)( start & 0xFFFFU );

              if ( (is32[lo >> 3] & ( 0x80 >> ( lo & 7 ) ) ) != 0 )
                FT_INVALID_DATA;
            }
          }
        }

        last = end;
      }
    }

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap8_char_index( TT_CMap    cmap,
                       FT_UInt32  char_code )
  {
    FT_Byte*   table      = cmap->data;
    FT_UInt    result     = 0;
    FT_Byte*   p          = table + 8204;
    FT_UInt32  num_groups = TT_NEXT_ULONG( p );
    FT_UInt32  start, end, start_id;


    for ( ; num_groups > 0; num_groups-- )
    {
      start    = TT_NEXT_ULONG( p );
      end      = TT_NEXT_ULONG( p );
      start_id = TT_NEXT_ULONG( p );

      if ( char_code < start )
        break;

      if ( char_code <= end )
      {
        result = (FT_UInt)( start_id + char_code - start );
        break;
      }
    }
    return result;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap8_char_next( TT_CMap     cmap,
                      FT_UInt32  *pchar_code )
  {
    FT_UInt32  result     = 0;
    FT_UInt32  char_code  = *pchar_code + 1;
    FT_UInt    gindex     = 0;
    FT_Byte*   table      = cmap->data;
    FT_Byte*   p          = table + 8204;
    FT_UInt32  num_groups = TT_NEXT_ULONG( p );
    FT_UInt32  start, end, start_id;


    p = table + 8208;

    for ( ; num_groups > 0; num_groups-- )
    {
      start    = TT_NEXT_ULONG( p );
      end      = TT_NEXT_ULONG( p );
      start_id = TT_NEXT_ULONG( p );

      if ( char_code < start )
        char_code = start;

      if ( char_code <= end )
      {
        gindex = (FT_UInt)( char_code - start + start_id );
        if ( gindex != 0 )
        {
          result = char_code;
          goto Exit;
        }
      }
    }

  Exit:
    *pchar_code = result;
    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap8_get_info( TT_CMap       cmap,
                     TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 8;


    cmap_info->format   = 8;
    cmap_info->language = (FT_ULong)TT_PEEK_ULONG( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap8_class_rec,
      sizeof ( TT_CMapRec ),

      (FT_CMap_InitFunc)     tt_cmap_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap8_char_index,
      (FT_CMap_CharNextFunc) tt_cmap8_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    8,
    (TT_CMap_ValidateFunc)   tt_cmap8_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap8_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_8 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 10                            *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME      OFFSET  TYPE               DESCRIPTION                    */
  /*                                                                       */
  /*   format     0      USHORT             must be 10                     */
  /*   reserved   2      USHORT             reserved                       */
  /*   length     4      ULONG              length in bytes                */
  /*   language   8      ULONG              Mac language code              */
  /*                                                                       */
  /*   start     12      ULONG              first char in range            */
  /*   count     16      ULONG              number of chars in range       */
  /*   glyphIds  20      USHORT[count]      glyph indices covered          */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_10

  FT_CALLBACK_DEF( FT_Error )
  tt_cmap10_validate( FT_Byte*      table,
                      FT_Validator  valid )
  {
    FT_Byte*  p = table + 4;
    FT_ULong  length, count;


    if ( table + 20 > valid->limit )
      FT_INVALID_TOO_SHORT;

    length = TT_NEXT_ULONG( p );
    p      = table + 16;
    count  = TT_NEXT_ULONG( p );

    if ( length > (FT_ULong)( valid->limit - table ) ||
         length < 20 + count * 2                     )
      FT_INVALID_TOO_SHORT;

    /* check glyph indices */
    if ( valid->level >= FT_VALIDATE_TIGHT )
    {
      FT_UInt  gindex;


      for ( ; count > 0; count-- )
      {
        gindex = TT_NEXT_USHORT( p );
        if ( gindex >= TT_VALID_GLYPH_COUNT( valid ) )
          FT_INVALID_GLYPH_ID;
      }
    }

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap10_char_index( TT_CMap    cmap,
                        FT_UInt32  char_code )
  {
    FT_Byte*   table  = cmap->data;
    FT_UInt    result = 0;
    FT_Byte*   p      = table + 12;
    FT_UInt32  start  = TT_NEXT_ULONG( p );
    FT_UInt32  count  = TT_NEXT_ULONG( p );
    FT_UInt32  idx    = (FT_ULong)( char_code - start );


    if ( idx < count )
    {
      p     += 2 * idx;
      result = TT_PEEK_USHORT( p );
    }
    return result;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap10_char_next( TT_CMap     cmap,
                       FT_UInt32  *pchar_code )
  {
    FT_Byte*   table     = cmap->data;
    FT_UInt32  char_code = *pchar_code + 1;
    FT_UInt    gindex    = 0;
    FT_Byte*   p         = table + 12;
    FT_UInt32  start     = TT_NEXT_ULONG( p );
    FT_UInt32  count     = TT_NEXT_ULONG( p );
    FT_UInt32  idx;


    if ( char_code < start )
      char_code = start;

    idx = (FT_UInt32)( char_code - start );
    p  += 2 * idx;

    for ( ; idx < count; idx++ )
    {
      gindex = TT_NEXT_USHORT( p );
      if ( gindex != 0 )
        break;
      char_code++;
    }

    *pchar_code = char_code;
    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap10_get_info( TT_CMap       cmap,
                      TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 8;


    cmap_info->format   = 10;
    cmap_info->language = (FT_ULong)TT_PEEK_ULONG( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap10_class_rec,
      sizeof ( TT_CMapRec ),

      (FT_CMap_InitFunc)     tt_cmap_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap10_char_index,
      (FT_CMap_CharNextFunc) tt_cmap10_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    10,
    (TT_CMap_ValidateFunc)   tt_cmap10_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap10_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_10 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 12                            *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET     TYPE       DESCRIPTION                       */
  /*                                                                       */
  /*   format      0          USHORT     must be 12                        */
  /*   reserved    2          USHORT     reserved                          */
  /*   length      4          ULONG      length in bytes                   */
  /*   language    8          ULONG      Mac language code                 */
  /*   count       12         ULONG      number of groups                  */
  /*               16                                                      */
  /*                                                                       */
  /* This header is followed by `count' groups of the following format:    */
  /*                                                                       */
  /*   start       0          ULONG      first charcode                    */
  /*   end         4          ULONG      last charcode                     */
  /*   startId     8          ULONG      start glyph ID for the group      */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_12

  typedef struct  TT_CMap12Rec_
  {
    TT_CMapRec  cmap;
    FT_Bool     valid;
    FT_ULong    cur_charcode;
    FT_UInt     cur_gindex;
    FT_ULong    cur_group;
    FT_ULong    num_groups;

  } TT_CMap12Rec, *TT_CMap12;


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap12_init( TT_CMap12  cmap,
                  FT_Byte*   table )
  {
    cmap->cmap.data  = table;

    table           += 12;
    cmap->num_groups = FT_PEEK_ULONG( table );

    cmap->valid      = 0;

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap12_validate( FT_Byte*      table,
                      FT_Validator  valid )
  {
    FT_Byte*   p;
    FT_ULong   length;
    FT_ULong   num_groups;


    if ( table + 16 > valid->limit )
      FT_INVALID_TOO_SHORT;

    p      = table + 4;
    length = TT_NEXT_ULONG( p );

    p          = table + 12;
    num_groups = TT_NEXT_ULONG( p );

    if ( length > (FT_ULong)( valid->limit - table ) ||
         length < 16 + 12 * num_groups               )
      FT_INVALID_TOO_SHORT;

    /* check groups, they must be in increasing order */
    {
      FT_ULong  n, start, end, start_id, last = 0;


      for ( n = 0; n < num_groups; n++ )
      {
        start    = TT_NEXT_ULONG( p );
        end      = TT_NEXT_ULONG( p );
        start_id = TT_NEXT_ULONG( p );

        if ( start > end )
          FT_INVALID_DATA;

        if ( n > 0 && start <= last )
          FT_INVALID_DATA;

        if ( valid->level >= FT_VALIDATE_TIGHT )
        {
          if ( start_id + end - start >= TT_VALID_GLYPH_COUNT( valid ) )
            FT_INVALID_GLYPH_ID;
        }

        last = end;
      }
    }

    return SFNT_Err_Ok;
  }


  /* search the index of the charcode next to cmap->cur_charcode */
  /* cmap->cur_group should be set up properly by caller         */
  /*                                                             */
  static void
  tt_cmap12_next( TT_CMap12  cmap )
  {
    FT_Byte*  p;
    FT_ULong  start, end, start_id, char_code;
    FT_ULong  n;
    FT_UInt   gindex;


    if ( cmap->cur_charcode >= 0xFFFFFFFFUL )
      goto Fail;

    char_code = cmap->cur_charcode + 1;

    n = cmap->cur_group;

    for ( n = cmap->cur_group; n < cmap->num_groups; n++ )
    {
      p        = cmap->cmap.data + 16 + 12 * n;
      start    = TT_NEXT_ULONG( p );
      end      = TT_NEXT_ULONG( p );
      start_id = TT_PEEK_ULONG( p );

      if ( char_code < start )
        char_code = start;

      for ( ; char_code <= end; char_code++ )
      {
        gindex = (FT_UInt)( start_id + char_code - start );

        if ( gindex )
        {
          cmap->cur_charcode = char_code;;
          cmap->cur_gindex   = gindex;
          cmap->cur_group    = n;

          return;
        }
      }
    }

  Fail:
    cmap->valid = 0;
  }


  static FT_UInt
  tt_cmap12_char_map_binary( TT_CMap     cmap,
                             FT_UInt32*  pchar_code,
                             FT_Bool     next )
  {
    FT_UInt    gindex     = 0;
    FT_Byte*   p          = cmap->data + 12;
    FT_UInt32  num_groups = TT_PEEK_ULONG( p );
    FT_UInt32  char_code  = *pchar_code;
    FT_UInt32  start, end, start_id;
    FT_UInt32  max, min, mid;


    if ( !num_groups )
      return 0;

    /* make compiler happy */
    mid = num_groups;
    end = 0xFFFFFFFFUL;

    if ( next )
      char_code++;

    min = 0;
    max = num_groups;

    /* binary search */
    while ( min < max )
    {
      mid = ( min + max ) >> 1;
      p   = cmap->data + 16 + 12 * mid;

      start = TT_NEXT_ULONG( p );
      end   = TT_NEXT_ULONG( p );

      if ( char_code < start )
        max = mid;
      else if ( char_code > end )
        min = mid + 1;
      else
      {
        start_id = TT_PEEK_ULONG( p );
        gindex = (FT_UInt)( start_id + char_code - start );

        break;
      }
    }

    if ( next )
    {
      TT_CMap12  cmap12 = (TT_CMap12)cmap;


      /* if `char_code' is not in any group, then `mid' is */
      /* the group nearest to `char_code'                  */
      /*                                                   */

      if ( char_code > end )
      {
        mid++;
        if ( mid == num_groups )
          return 0;
      }

      cmap12->valid        = 1;
      cmap12->cur_charcode = char_code;
      cmap12->cur_group    = mid;

      if ( !gindex )
      {
        tt_cmap12_next( cmap12 );

        if ( cmap12->valid )
          gindex = cmap12->cur_gindex;
      }
      else
        cmap12->cur_gindex = gindex;

      if ( gindex )
        *pchar_code = cmap12->cur_charcode;
    }

    return gindex;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap12_char_index( TT_CMap    cmap,
                        FT_UInt32  char_code )
  {
    return tt_cmap12_char_map_binary( cmap, &char_code, 0 );
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap12_char_next( TT_CMap     cmap,
                       FT_UInt32  *pchar_code )
  {
    TT_CMap12  cmap12 = (TT_CMap12)cmap;
    FT_ULong   gindex;


    if ( cmap12->cur_charcode >= 0xFFFFFFFFUL )
      return 0;

    /* no need to search */
    if ( cmap12->valid && cmap12->cur_charcode == *pchar_code )
    {
      tt_cmap12_next( cmap12 );
      if ( cmap12->valid )
      {
        gindex = cmap12->cur_gindex;

        /* XXX: check cur_charcode overflow is expected */
        if ( gindex )
          *pchar_code = (FT_UInt32)cmap12->cur_charcode;
      }
      else
        gindex = 0;
    }
    else
      gindex = tt_cmap12_char_map_binary( cmap, pchar_code, 1 );

    /* XXX: check gindex overflow is expected */
    return (FT_UInt32)gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap12_get_info( TT_CMap       cmap,
                      TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 8;


    cmap_info->format   = 12;
    cmap_info->language = (FT_ULong)TT_PEEK_ULONG( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap12_class_rec,
      sizeof ( TT_CMap12Rec ),

      (FT_CMap_InitFunc)     tt_cmap12_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap12_char_index,
      (FT_CMap_CharNextFunc) tt_cmap12_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    12,
    (TT_CMap_ValidateFunc)   tt_cmap12_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap12_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_12 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                          FORMAT 13                            *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME        OFFSET     TYPE       DESCRIPTION                       */
  /*                                                                       */
  /*   format      0          USHORT     must be 13                        */
  /*   reserved    2          USHORT     reserved                          */
  /*   length      4          ULONG      length in bytes                   */
  /*   language    8          ULONG      Mac language code                 */
  /*   count       12         ULONG      number of groups                  */
  /*               16                                                      */
  /*                                                                       */
  /* This header is followed by `count' groups of the following format:    */
  /*                                                                       */
  /*   start       0          ULONG      first charcode                    */
  /*   end         4          ULONG      last charcode                     */
  /*   glyphId     8          ULONG      glyph ID for the whole group      */
  /*                                                                       */

#ifdef TT_CONFIG_CMAP_FORMAT_13

  typedef struct  TT_CMap13Rec_
  {
    TT_CMapRec  cmap;
    FT_Bool     valid;
    FT_ULong    cur_charcode;
    FT_UInt     cur_gindex;
    FT_ULong    cur_group;
    FT_ULong    num_groups;

  } TT_CMap13Rec, *TT_CMap13;


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap13_init( TT_CMap13  cmap,
                  FT_Byte*   table )
  {
    cmap->cmap.data  = table;

    table           += 12;
    cmap->num_groups = FT_PEEK_ULONG( table );

    cmap->valid      = 0;

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap13_validate( FT_Byte*      table,
                      FT_Validator  valid )
  {
    FT_Byte*   p;
    FT_ULong   length;
    FT_ULong   num_groups;


    if ( table + 16 > valid->limit )
      FT_INVALID_TOO_SHORT;

    p      = table + 4;
    length = TT_NEXT_ULONG( p );

    p          = table + 12;
    num_groups = TT_NEXT_ULONG( p );

    if ( length > (FT_ULong)( valid->limit - table ) ||
         length < 16 + 12 * num_groups               )
      FT_INVALID_TOO_SHORT;

    /* check groups, they must be in increasing order */
    {
      FT_ULong  n, start, end, glyph_id, last = 0;


      for ( n = 0; n < num_groups; n++ )
      {
        start    = TT_NEXT_ULONG( p );
        end      = TT_NEXT_ULONG( p );
        glyph_id = TT_NEXT_ULONG( p );

        if ( start > end )
          FT_INVALID_DATA;

        if ( n > 0 && start <= last )
          FT_INVALID_DATA;

        if ( valid->level >= FT_VALIDATE_TIGHT )
        {
          if ( glyph_id >= TT_VALID_GLYPH_COUNT( valid ) )
            FT_INVALID_GLYPH_ID;
        }

        last = end;
      }
    }

    return SFNT_Err_Ok;
  }


  /* search the index of the charcode next to cmap->cur_charcode */
  /* cmap->cur_group should be set up properly by caller         */
  /*                                                             */
  static void
  tt_cmap13_next( TT_CMap13  cmap )
  {
    FT_Byte*  p;
    FT_ULong  start, end, glyph_id, char_code;
    FT_ULong  n;
    FT_UInt   gindex;


    if ( cmap->cur_charcode >= 0xFFFFFFFFUL )
      goto Fail;

    char_code = cmap->cur_charcode + 1;

    n = cmap->cur_group;

    for ( n = cmap->cur_group; n < cmap->num_groups; n++ )
    {
      p        = cmap->cmap.data + 16 + 12 * n;
      start    = TT_NEXT_ULONG( p );
      end      = TT_NEXT_ULONG( p );
      glyph_id = TT_PEEK_ULONG( p );

      if ( char_code < start )
        char_code = start;

      if ( char_code <= end )
      {
        gindex = (FT_UInt)glyph_id;

        if ( gindex )
        {
          cmap->cur_charcode = char_code;;
          cmap->cur_gindex   = gindex;
          cmap->cur_group    = n;

          return;
        }
      }
    }

  Fail:
    cmap->valid = 0;
  }


  static FT_UInt
  tt_cmap13_char_map_binary( TT_CMap     cmap,
                             FT_UInt32*  pchar_code,
                             FT_Bool     next )
  {
    FT_UInt    gindex     = 0;
    FT_Byte*   p          = cmap->data + 12;
    FT_UInt32  num_groups = TT_PEEK_ULONG( p );
    FT_UInt32  char_code  = *pchar_code;
    FT_UInt32  start, end;
    FT_UInt32  max, min, mid;


    if ( !num_groups )
      return 0;

    /* make compiler happy */
    mid = num_groups;
    end = 0xFFFFFFFFUL;

    if ( next )
      char_code++;

    min = 0;
    max = num_groups;

    /* binary search */
    while ( min < max )
    {
      mid = ( min + max ) >> 1;
      p   = cmap->data + 16 + 12 * mid;

      start = TT_NEXT_ULONG( p );
      end   = TT_NEXT_ULONG( p );

      if ( char_code < start )
        max = mid;
      else if ( char_code > end )
        min = mid + 1;
      else
      {
        gindex = (FT_UInt)TT_PEEK_ULONG( p );

        break;
      }
    }

    if ( next )
    {
      TT_CMap13  cmap13 = (TT_CMap13)cmap;


      /* if `char_code' is not in any group, then `mid' is */
      /* the group nearest to `char_code'                  */
      /*                                                   */

      if ( char_code > end )
      {
        mid++;
        if ( mid == num_groups )
          return 0;
      }

      cmap13->valid        = 1;
      cmap13->cur_charcode = char_code;
      cmap13->cur_group    = mid;

      if ( !gindex )
      {
        tt_cmap13_next( cmap13 );

        if ( cmap13->valid )
          gindex = cmap13->cur_gindex;
      }
      else
        cmap13->cur_gindex = gindex;

      if ( gindex )
        *pchar_code = cmap13->cur_charcode;
    }

    return gindex;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap13_char_index( TT_CMap    cmap,
                        FT_UInt32  char_code )
  {
    return tt_cmap13_char_map_binary( cmap, &char_code, 0 );
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap13_char_next( TT_CMap     cmap,
                       FT_UInt32  *pchar_code )
  {
    TT_CMap13  cmap13 = (TT_CMap13)cmap;
    FT_UInt    gindex;


    if ( cmap13->cur_charcode >= 0xFFFFFFFFUL )
      return 0;

    /* no need to search */
    if ( cmap13->valid && cmap13->cur_charcode == *pchar_code )
    {
      tt_cmap13_next( cmap13 );
      if ( cmap13->valid )
      {
        gindex = cmap13->cur_gindex;
        if ( gindex )
          *pchar_code = cmap13->cur_charcode;
      }
      else
        gindex = 0;
    }
    else
      gindex = tt_cmap13_char_map_binary( cmap, pchar_code, 1 );

    return gindex;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap13_get_info( TT_CMap       cmap,
                      TT_CMapInfo  *cmap_info )
  {
    FT_Byte*  p = cmap->data + 8;


    cmap_info->format   = 13;
    cmap_info->language = (FT_ULong)TT_PEEK_ULONG( p );

    return SFNT_Err_Ok;
  }


  FT_DEFINE_TT_CMAP(tt_cmap13_class_rec,
      sizeof ( TT_CMap13Rec ),

      (FT_CMap_InitFunc)     tt_cmap13_init,
      (FT_CMap_DoneFunc)     NULL,
      (FT_CMap_CharIndexFunc)tt_cmap13_char_index,
      (FT_CMap_CharNextFunc) tt_cmap13_char_next,

      NULL, NULL, NULL, NULL, NULL
    ,
    13,
    (TT_CMap_ValidateFunc)   tt_cmap13_validate,
    (TT_CMap_Info_GetFunc)   tt_cmap13_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_13 */


  /*************************************************************************/
  /*************************************************************************/
  /*****                                                               *****/
  /*****                           FORMAT 14                           *****/
  /*****                                                               *****/
  /*************************************************************************/
  /*************************************************************************/

  /*************************************************************************/
  /*                                                                       */
  /* TABLE OVERVIEW                                                        */
  /* --------------                                                        */
  /*                                                                       */
  /*   NAME         OFFSET  TYPE    DESCRIPTION                            */
  /*                                                                       */
  /*   format         0     USHORT  must be 14                             */
  /*   length         2     ULONG   table length in bytes                  */
  /*   numSelector    6     ULONG   number of variation sel. records       */
  /*                                                                       */
  /* Followed by numSelector records, each of which looks like             */
  /*                                                                       */
  /*   varSelector    0     UINT24  Unicode codepoint of sel.              */
  /*   defaultOff     3     ULONG   offset to a default UVS table          */
  /*                                describing any variants to be found in */
  /*                                the normal Unicode subtable.           */
  /*   nonDefOff      7     ULONG   offset to a non-default UVS table      */
  /*                                describing any variants not in the     */
  /*                                standard cmap, with GIDs here          */
  /* (either offset may be 0 NULL)                                         */
  /*                                                                       */
  /* Selectors are sorted by code point.                                   */
  /*                                                                       */
  /* A default Unicode Variation Selector (UVS) subtable is just a list of */
  /* ranges of code points which are to be found in the standard cmap.  No */
  /* glyph IDs (GIDs) here.                                                */
  /*                                                                       */
  /*   numRanges      0     ULONG   number of ranges following             */
  /*                                                                       */
  /* A range looks like                                                    */
  /*                                                                       */
  /*   uniStart       0     UINT24  code point of the first character in   */
  /*                                this range                             */
  /*   additionalCnt  3     UBYTE   count of additional characters in this */
  /*                                range (zero means a range of a single  */
  /*                                character)                             */
  /*                                                                       */
  /* Ranges are sorted by `uniStart'.                                      */
  /*                                                                       */
  /* A non-default Unicode Variation Selector (UVS) subtable is a list of  */
  /* mappings from codepoint to GID.                                       */
  /*                                                                       */
  /*   numMappings    0     ULONG   number of mappings                     */
  /*                                                                       */
  /* A range looks like                                                    */
  /*                                                                       */
  /*   uniStart       0     UINT24  code point of the first character in   */
  /*                                this range                             */
  /*   GID            3     USHORT  and its GID                            */
  /*                                                                       */
  /* Ranges are sorted by `uniStart'.                                      */

#ifdef TT_CONFIG_CMAP_FORMAT_14

  typedef struct  TT_CMap14Rec_
  {
    TT_CMapRec  cmap;
    FT_ULong    num_selectors;

    /* This array is used to store the results of various
     * cmap 14 query functions.  The data is overwritten
     * on each call to these functions.
     */
    FT_UInt32   max_results;
    FT_UInt32*  results;
    FT_Memory   memory;

  } TT_CMap14Rec, *TT_CMap14;


  FT_CALLBACK_DEF( void )
  tt_cmap14_done( TT_CMap14  cmap )
  {
    FT_Memory  memory = cmap->memory;


    cmap->max_results = 0;
    if ( memory != NULL && cmap->results != NULL )
      FT_FREE( cmap->results );
  }


  static FT_Error
  tt_cmap14_ensure( TT_CMap14  cmap,
                    FT_UInt32  num_results,
                    FT_Memory  memory )
  {
    FT_UInt32 old_max = cmap->max_results;
    FT_Error  error   = SFNT_Err_Ok;


    if ( num_results > cmap->max_results )
    {
       cmap->memory = memory;

       if ( FT_QRENEW_ARRAY( cmap->results, old_max, num_results ) )
         return error;

       cmap->max_results = num_results;
    }

    return error;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap14_init( TT_CMap14  cmap,
                  FT_Byte*   table )
  {
    cmap->cmap.data = table;

    table               += 6;
    cmap->num_selectors = FT_PEEK_ULONG( table );
    cmap->max_results   = 0;
    cmap->results       = NULL;

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap14_validate( FT_Byte*      table,
                      FT_Validator  valid )
  {
    FT_Byte*  p             = table + 2;
    FT_ULong  length        = TT_NEXT_ULONG( p );
    FT_ULong  num_selectors = TT_NEXT_ULONG( p );


    if ( length > (FT_ULong)( valid->limit - table ) ||
         length < 10 + 11 * num_selectors            )
      FT_INVALID_TOO_SHORT;

    /* check selectors, they must be in increasing order */
    {
      /* we start lastVarSel at 1 because a variant selector value of 0
       * isn't valid.
       */
      FT_ULong  n, lastVarSel = 1;


      for ( n = 0; n < num_selectors; n++ )
      {
        FT_ULong  varSel    = TT_NEXT_UINT24( p );
        FT_ULong  defOff    = TT_NEXT_ULONG( p );
        FT_ULong  nondefOff = TT_NEXT_ULONG( p );


        if ( defOff >= length || nondefOff >= length )
          FT_INVALID_TOO_SHORT;

        if ( varSel < lastVarSel )
          FT_INVALID_DATA;

        lastVarSel = varSel + 1;

        /* check the default table (these glyphs should be reached     */
        /* through the normal Unicode cmap, no GIDs, just check order) */
        if ( defOff != 0 )
        {
          FT_Byte*  defp      = table + defOff;
          FT_ULong  numRanges = TT_NEXT_ULONG( defp );
          FT_ULong  i;
          FT_ULong  lastBase  = 0;


          if ( defp + numRanges * 4 > valid->limit )
            FT_INVALID_TOO_SHORT;

          for ( i = 0; i < numRanges; ++i )
          {
            FT_ULong  base = TT_NEXT_UINT24( defp );
            FT_ULong  cnt  = FT_NEXT_BYTE( defp );


            if ( base + cnt >= 0x110000UL )              /* end of Unicode */
              FT_INVALID_DATA;

            if ( base < lastBase )
              FT_INVALID_DATA;

            lastBase = base + cnt + 1U;
          }
        }

        /* and the non-default table (these glyphs are specified here) */
        if ( nondefOff != 0 )
        {
          FT_Byte*  ndp         = table + nondefOff;
          FT_ULong  numMappings = TT_NEXT_ULONG( ndp );
          FT_ULong  i, lastUni = 0;


          if ( numMappings * 4 > (FT_ULong)( valid->limit - ndp ) )
            FT_INVALID_TOO_SHORT;

          for ( i = 0; i < numMappings; ++i )
          {
            FT_ULong  uni = TT_NEXT_UINT24( ndp );
            FT_ULong  gid = TT_NEXT_USHORT( ndp );


            if ( uni >= 0x110000UL )                     /* end of Unicode */
              FT_INVALID_DATA;

            if ( uni < lastUni )
              FT_INVALID_DATA;

            lastUni = uni + 1U;

            if ( valid->level >= FT_VALIDATE_TIGHT    &&
                 gid >= TT_VALID_GLYPH_COUNT( valid ) )
              FT_INVALID_GLYPH_ID;
          }
        }
      }
    }

    return SFNT_Err_Ok;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap14_char_index( TT_CMap    cmap,
                        FT_UInt32  char_code )
  {
    FT_UNUSED( cmap );
    FT_UNUSED( char_code );

    /* This can't happen */
    return 0;
  }


  FT_CALLBACK_DEF( FT_UInt32 )
  tt_cmap14_char_next( TT_CMap     cmap,
                       FT_UInt32  *pchar_code )
  {
    FT_UNUSED( cmap );

    /* This can't happen */
    *pchar_code = 0;
    return 0;
  }


  FT_CALLBACK_DEF( FT_Error )
  tt_cmap14_get_info( TT_CMap       cmap,
                      TT_CMapInfo  *cmap_info )
  {
    FT_UNUSED( cmap );

    cmap_info->format   = 14;
    /* subtable 14 does not define a language field */
    cmap_info->language = 0xFFFFFFFFUL;

    return SFNT_Err_Ok;
  }


  static FT_UInt
  tt_cmap14_char_map_def_binary( FT_Byte    *base,
                                 FT_UInt32   char_code )
  {
    FT_UInt32  numRanges = TT_PEEK_ULONG( base );
    FT_UInt32  max, min;


    min = 0;
    max = numRanges;

    base += 4;

    /* binary search */
    while ( min < max )
    {
      FT_UInt32  mid   = ( min + max ) >> 1;
      FT_Byte*   p     = base + 4 * mid;
      FT_ULong   start = TT_NEXT_UINT24( p );
      FT_UInt    cnt   = FT_NEXT_BYTE( p );


      if ( char_code < start )
        max = mid;
      else if ( char_code > start+cnt )
        min = mid + 1;
      else
        return TRUE;
    }

    return FALSE;
  }


  static FT_UInt
  tt_cmap14_char_map_nondef_binary( FT_Byte    *base,
                                    FT_UInt32   char_code )
  {
    FT_UInt32  numMappings = TT_PEEK_ULONG( base );
    FT_UInt32  max, min;


    min = 0;
    max = numMappings;

    base += 4;

    /* binary search */
    while ( min < max )
    {
      FT_UInt32  mid = ( min + max ) >> 1;
      FT_Byte*   p   = base + 5 * mid;
      FT_UInt32  uni = (FT_UInt32)TT_NEXT_UINT24( p );


      if ( char_code < uni )
        max = mid;
      else if ( char_code > uni )
        min = mid + 1;
      else
        return TT_PEEK_USHORT( p );
    }

    return 0;
  }


  static FT_Byte*
  tt_cmap14_find_variant( FT_Byte    *base,
                          FT_UInt32   variantCode )
  {
    FT_UInt32  numVar = TT_PEEK_ULONG( base );
    FT_UInt32  max, min;


    min = 0;
    max = numVar;

    base += 4;

    /* binary search */
    while ( min < max )
    {
      FT_UInt32  mid    = ( min + max ) >> 1;
      FT_Byte*   p      = base + 11 * mid;
      FT_ULong   varSel = TT_NEXT_UINT24( p );


      if ( variantCode < varSel )
        max = mid;
      else if ( variantCode > varSel )
        min = mid + 1;
      else
        return p;
    }

    return NULL;
  }


  FT_CALLBACK_DEF( FT_UInt )
  tt_cmap14_char_var_index( TT_CMap    cmap,
                            TT_CMap    ucmap,
                            FT_UInt32  charcode,
                            FT_UInt32  variantSelector)
  {
    FT_Byte*  p = tt_cmap14_find_variant( cmap->data + 6, variantSelector );
    FT_ULong  defOff;
    FT_ULong  nondefOff;


    if ( !p )
      return 0;

    defOff    = TT_NEXT_ULONG( p );
    nondefOff = TT_PEEK_ULONG( p );

    if ( defOff != 0                                                    &&
         tt_cmap14_char_map_def_binary( cmap->data + defOff, charcode ) )
    {
      /* This is the default variant of this charcode.  GID not stored */
      /* here; stored in the normal Unicode charmap instead.           */
      return ucmap->cmap.clazz->char_index( &ucmap->cmap, charcode );
    }

    if ( nondefOff != 0 )
      return tt_cmap14_char_map_nondef_binary( cmap->data + nondefOff,
                                               charcode );

    return 0;
  }


  FT_CALLBACK_DEF( FT_Int )
  tt_cmap14_char_var_isdefault( TT_CMap    cmap,
                                FT_UInt32  charcode,
                                FT_UInt32  variantSelector )
  {
    FT_Byte*  p = tt_cmap14_find_variant( cmap->data + 6, variantSelector );
    FT_ULong  defOff;
    FT_ULong  nondefOff;


    if ( !p )
      return -1;

    defOff    = TT_NEXT_ULONG( p );
    nondefOff = TT_NEXT_ULONG( p );

    if ( defOff != 0                                                    &&
         tt_cmap14_char_map_def_binary( cmap->data + defOff, charcode ) )
      return 1;

    if ( nondefOff != 0                                            &&
         tt_cmap14_char_map_nondef_binary( cmap->data + nondefOff,
                                           charcode ) != 0         )
      return 0;

    return -1;
  }


  FT_CALLBACK_DEF( FT_UInt32* )
  tt_cmap14_variants( TT_CMap    cmap,
                      FT_Memory  memory )
  {
    TT_CMap14   cmap14 = (TT_CMap14)cmap;
    FT_UInt32   count  = cmap14->num_selectors;
    FT_Byte*    p      = cmap->data + 10;
    FT_UInt32*  result;
    FT_UInt32   i;


    if ( tt_cmap14_ensure( cmap14, ( count + 1 ), memory ) )
      return NULL;

    result = cmap14->results;
    for ( i = 0; i < count; ++i )
    {
      result[i] = (FT_UInt32)TT_NEXT_UINT24( p );
      p        += 8;
    }
    result[i] = 0;

    return result;
  }


  FT_CALLBACK_DEF( FT_UInt32 * )
  tt_cmap14_char_variants( TT_CMap    cmap,
                           FT_Memory  memory,
                           FT_UInt32  charCode )
  {
    TT_CMap14   cmap14 = (TT_CMap14)  cmap;
    FT_UInt32   count  = cmap14->num_selectors;
    FT_Byte*    p      = cmap->data + 10;
    FT_UInt32*  q;


    if ( tt_cmap14_ensure( cmap14, ( count + 1 ), memory ) )
      return NULL;

    for ( q = cmap14->results; count > 0; --count )
    {
      FT_UInt32  varSel    = TT_NEXT_UINT24( p );
      FT_ULong   defOff    = TT_NEXT_ULONG( p );
      FT_ULong   nondefOff = TT_NEXT_ULONG( p );


      if ( ( defOff != 0                                               &&
             tt_cmap14_char_map_def_binary( cmap->data + defOff,
                                            charCode )                 ) ||
           ( nondefOff != 0                                            &&
             tt_cmap14_char_map_nondef_binary( cmap->data + nondefOff,
                                               charCode ) != 0         ) )
      {
        q[0] = varSel;
        q++;
      }
    }
    q[0] = 0;

    return cmap14->results;
  }


  static FT_UInt
  tt_cmap14_def_char_count( FT_Byte  *p )
  {
    FT_UInt32  numRanges = (FT_UInt32)TT_NEXT_ULONG( p );
    FT_UInt    tot       = 0;


    p += 3;  /* point to the first `cnt' field */
    for ( ; numRanges > 0; numRanges-- )
    {
      tot += 1 + p[0];
      p   += 4;
    }

    return tot;
  }


  static FT_UInt32*
  tt_cmap14_get_def_chars( TT_CMap     cmap,
                           FT_Byte*    p,
                           FT_Memory   memory )
  {
    TT_CMap14   cmap14 = (TT_CMap14) cmap;
    FT_UInt32   numRanges;
    FT_UInt     cnt;
    FT_UInt32*  q;


    cnt       = tt_cmap14_def_char_count( p );
    numRanges = (FT_UInt32)TT_NEXT_ULONG( p );

    if ( tt_cmap14_ensure( cmap14, ( cnt + 1 ), memory ) )
      return NULL;

    for ( q = cmap14->results; numRanges > 0; --numRanges )
    {
      FT_UInt32 uni = (FT_UInt32)TT_NEXT_UINT24( p );


      cnt = FT_NEXT_BYTE( p ) + 1;
      do
      {
        q[0]  = uni;
        uni  += 1;
        q    += 1;
      } while ( --cnt != 0 );
    }
    q[0] = 0;

    return cmap14->results;
  }


  static FT_UInt32*
  tt_cmap14_get_nondef_chars( TT_CMap     cmap,
                              FT_Byte    *p,
                              FT_Memory   memory )
  {
    TT_CMap14   cmap14 = (TT_CMap14) cmap;
    FT_UInt32   numMappings;
    FT_UInt     i;
    FT_UInt32  *ret;


    numMappings = (FT_UInt32)TT_NEXT_ULONG( p );

    if ( tt_cmap14_ensure( cmap14, ( numMappings + 1 ), memory ) )
      return NULL;

    ret = cmap14->results;
    for ( i = 0; i < numMappings; ++i )
    {
      ret[i] = (FT_UInt32)TT_NEXT_UINT24( p );
      p += 2;
    }
    ret[i] = 0;

    return ret;
  }


  FT_CALLBACK_DEF( FT_UInt32 * )
  tt_cmap14_variant_chars( TT_CMap    cmap,
                           FT_Memory  memory,
                           FT_UInt32  variantSelector )
  {
    FT_Byte    *p  = tt_cmap14_find_variant( cmap->data + 6,
                                             variantSelector );
    FT_UInt32  *ret;
    FT_Int      i;
    FT_ULong    defOff;
    FT_ULong    nondefOff;


    if ( !p )
      return NULL;

    defOff    = TT_NEXT_ULONG( p );
    nondefOff = TT_NEXT_ULONG( p );

    if ( defOff == 0 && nondefOff == 0 )
      return NULL;

    if ( defOff == 0 )
      return tt_cmap14_get_nondef_chars( cmap, cmap->data + nondefOff,
                                         memory );
    else if ( nondefOff == 0 )
      return tt_cmap14_get_def_chars( cmap, cmap->data + defOff,
                                      memory );
    else
    {
      /* Both a default and a non-default glyph set?  That's probably not */
      /* good font design, but the spec allows for it...                  */
      TT_CMap14  cmap14 = (TT_CMap14) cmap;
      FT_UInt32  numRanges;
      FT_UInt32  numMappings;
      FT_UInt32  duni;
      FT_UInt32  dcnt;
      FT_UInt32  nuni;
      FT_Byte*   dp;
      FT_UInt    di, ni, k;


      p  = cmap->data + nondefOff;
      dp = cmap->data + defOff;

      numMappings = (FT_UInt32)TT_NEXT_ULONG( p );
      dcnt        = tt_cmap14_def_char_count( dp );
      numRanges   = (FT_UInt32)TT_NEXT_ULONG( dp );

      if ( numMappings == 0 )
        return tt_cmap14_get_def_chars( cmap, cmap->data + defOff,
                                        memory );
      if ( dcnt == 0 )
        return tt_cmap14_get_nondef_chars( cmap, cmap->data + nondefOff,
                                           memory );

      if ( tt_cmap14_ensure( cmap14, ( dcnt + numMappings + 1 ), memory ) )
        return NULL;

      ret  = cmap14->results;
      duni = (FT_UInt32)TT_NEXT_UINT24( dp );
      dcnt = FT_NEXT_BYTE( dp );
      di   = 1;
      nuni = (FT_UInt32)TT_NEXT_UINT24( p );
      p   += 2;
      ni   = 1;
      i    = 0;

      for ( ;; )
      {
        if ( nuni > duni + dcnt )
        {
          for ( k = 0; k <= dcnt; ++k )
            ret[i++] = duni + k;

          ++di;

          if ( di > numRanges )
            break;

          duni = (FT_UInt32)TT_NEXT_UINT24( dp );
          dcnt = FT_NEXT_BYTE( dp );
        }
        else
        {
          if ( nuni < duni )
            ret[i++] = nuni;
          /* If it is within the default range then ignore it -- */
          /* that should not have happened                       */
          ++ni;
          if ( ni > numMappings )
            break;

          nuni = (FT_UInt32)TT_NEXT_UINT24( p );
          p += 2;
        }
      }

      if ( ni <= numMappings )
      {
        /* If we get here then we have run out of all default ranges.   */
        /* We have read one non-default mapping which we haven't stored */
        /* and there may be others that need to be read.                */
        ret[i++] = nuni;
        while ( ni < numMappings )
        {
          ret[i++] = (FT_UInt32)TT_NEXT_UINT24( p );
          p += 2;
          ++ni;
        }
      }
      else if ( di <= numRanges )
      {
        /* If we get here then we have run out of all non-default     */
        /* mappings.  We have read one default range which we haven't */
        /* stored and there may be others that need to be read.       */
        for ( k = 0; k <= dcnt; ++k )
          ret[i++] = duni + k;

        while ( di < numRanges )
        {
          duni = (FT_UInt32)TT_NEXT_UINT24( dp );
          dcnt = FT_NEXT_BYTE( dp );

          for ( k = 0; k <= dcnt; ++k )
            ret[i++] = duni + k;
          ++di;
        }
      }

      ret[i] = 0;

      return ret;
    }
  }


  FT_DEFINE_TT_CMAP(tt_cmap14_class_rec,
      sizeof ( TT_CMap14Rec ),

      (FT_CMap_InitFunc)     tt_cmap14_init,
      (FT_CMap_DoneFunc)     tt_cmap14_done,
      (FT_CMap_CharIndexFunc)tt_cmap14_char_index,
      (FT_CMap_CharNextFunc) tt_cmap14_char_next,

      /* Format 14 extension functions */
      (FT_CMap_CharVarIndexFunc)    tt_cmap14_char_var_index,
      (FT_CMap_CharVarIsDefaultFunc)tt_cmap14_char_var_isdefault,
      (FT_CMap_VariantListFunc)     tt_cmap14_variants,
      (FT_CMap_CharVariantListFunc) tt_cmap14_char_variants,
      (FT_CMap_VariantCharListFunc) tt_cmap14_variant_chars
    ,
    14,
    (TT_CMap_ValidateFunc)tt_cmap14_validate,
    (TT_CMap_Info_GetFunc)tt_cmap14_get_info
  )

#endif /* TT_CONFIG_CMAP_FORMAT_14 */


#ifndef FT_CONFIG_OPTION_PIC

  static const TT_CMap_Class  tt_cmap_classes[] =
  {
#define TTCMAPCITEM(a) &a,
#include "ttcmapc.h"
    NULL,
  };

#else /*FT_CONFIG_OPTION_PIC*/

  void FT_Destroy_Class_tt_cmap_classes(FT_Library library, TT_CMap_Class* clazz)
  {
    FT_Memory memory = library->memory;
    if ( clazz )
      FT_FREE( clazz );
  }

  FT_Error FT_Create_Class_tt_cmap_classes(FT_Library library, TT_CMap_Class** output_class)
  {
    TT_CMap_Class*  clazz;
    TT_CMap_ClassRec* recs;
    FT_Error          error;
    FT_Memory memory = library->memory;
    int i = 0;

#define TTCMAPCITEM(a) i++;
#include "ttcmapc.h"

    /* allocate enough space for both the pointers +terminator and the class instances */
    if ( FT_ALLOC( clazz, sizeof(*clazz)*(i+1)+sizeof(TT_CMap_ClassRec)*i ) )
      return error;

    /* the location of the class instances follows the array of pointers */
    recs = (TT_CMap_ClassRec*) (((char*)clazz)+(sizeof(*clazz)*(i+1))); 
    i=0;

#undef TTCMAPCITEM
#define TTCMAPCITEM(a)           \
    FT_Init_Class_##a(&recs[i]); \
    clazz[i] = &recs[i];         \
    i++;
#include "ttcmapc.h"

    clazz[i] = NULL;

    *output_class = clazz;
    return SFNT_Err_Ok;
  }

#endif /*FT_CONFIG_OPTION_PIC*/


  /* parse the `cmap' table and build the corresponding TT_CMap objects */
  /* in the current face                                                */
  /*                                                                    */
  FT_LOCAL_DEF( FT_Error )
  tt_face_build_cmaps( TT_Face  face )
  {
    FT_Byte*           table = face->cmap_table;
    FT_Byte*           limit = table + face->cmap_size;
    FT_UInt volatile   num_cmaps;
    FT_Byte* volatile  p     = table;
    FT_Library         library = FT_FACE_LIBRARY( face );

    FT_UNUSED( library );


    if ( !p || p + 4 > limit )
      return SFNT_Err_Invalid_Table;

    /* only recognize format 0 */
    if ( TT_NEXT_USHORT( p ) != 0 )
    {
      p -= 2;
      FT_ERROR(( "tt_face_build_cmaps:"
                 " unsupported `cmap' table format = %d\n",
                 TT_PEEK_USHORT( p ) ));
      return SFNT_Err_Invalid_Table;
    }

    num_cmaps = TT_NEXT_USHORT( p );
#ifdef FT_MAX_CHARMAP_CACHEABLE
    if ( num_cmaps > FT_MAX_CHARMAP_CACHEABLE )
      FT_ERROR(( "tt_face_build_cmaps: too many cmap subtables(%d) "
                 "subtable#%d and later are loaded but cannot be searched\n",
                 num_cmaps, FT_MAX_CHARMAP_CACHEABLE + 1 ));
#endif

    for ( ; num_cmaps > 0 && p + 8 <= limit; num_cmaps-- )
    {
      FT_CharMapRec  charmap;
      FT_UInt32      offset;


      charmap.platform_id = TT_NEXT_USHORT( p );
      charmap.encoding_id = TT_NEXT_USHORT( p );
      charmap.face        = FT_FACE( face );
      charmap.encoding    = FT_ENCODING_NONE;  /* will be filled later */
      offset              = TT_NEXT_ULONG( p );

      if ( offset && offset <= face->cmap_size - 2 )
      {
        FT_Byte* volatile              cmap   = table + offset;
        volatile FT_UInt               format = TT_PEEK_USHORT( cmap );
        const TT_CMap_Class* volatile  pclazz = FT_TT_CMAP_CLASSES_GET;
        TT_CMap_Class volatile         clazz;


        for ( ; *pclazz; pclazz++ )
        {
          clazz = *pclazz;
          if ( clazz->format == format )
          {
            volatile TT_ValidatorRec  valid;
            volatile FT_Error         error = SFNT_Err_Ok;


            ft_validator_init( FT_VALIDATOR( &valid ), cmap, limit,
                               FT_VALIDATE_DEFAULT );

            valid.num_glyphs = (FT_UInt)face->max_profile.numGlyphs;

            if ( ft_setjmp(
              *((ft_jmp_buf*)&FT_VALIDATOR( &valid )->jump_buffer) ) == 0 )
            {
              /* validate this cmap sub-table */
              error = clazz->validate( cmap, FT_VALIDATOR( &valid ) );
            }

            if ( valid.validator.error == 0 )
            {
              FT_CMap  ttcmap;


              /* It might make sense to store the single variation selector */
              /* cmap somewhere special.  But it would have to be in the    */
              /* public FT_FaceRec, and we can't change that.               */

              if ( !FT_CMap_New( (FT_CMap_Class)clazz,
                                 cmap, &charmap, &ttcmap ) )
              {
                /* it is simpler to directly set `flags' than adding */
                /* a parameter to FT_CMap_New                        */
                ((TT_CMap)ttcmap)->flags = (FT_Int)error;
              }
            }
            else
            {
              FT_TRACE0(( "tt_face_build_cmaps:"
                          " broken cmap sub-table ignored\n" ));
            }
            break;
          }
        }

        if ( *pclazz == NULL )
        {
          FT_TRACE0(( "tt_face_build_cmaps:"
                      " unsupported cmap sub-table ignored\n" ));
        }
      }
    }

    return SFNT_Err_Ok;
  }


  FT_LOCAL( FT_Error )
  tt_get_cmap_info( FT_CharMap    charmap,
                    TT_CMapInfo  *cmap_info )
  {
    FT_CMap        cmap  = (FT_CMap)charmap;
    TT_CMap_Class  clazz = (TT_CMap_Class)cmap->clazz;


    return clazz->get_cmap_info( charmap, cmap_info );
  }


/* END */