misc/libfreetype/src/raster/ftraster.c
changeset 5172 88f2e05288ba
--- /dev/null	Thu Jan 01 00:00:00 1970 +0000
+++ b/misc/libfreetype/src/raster/ftraster.c	Mon Apr 25 01:46:54 2011 +0200
@@ -0,0 +1,3601 @@
+/***************************************************************************/
+/*                                                                         */
+/*  ftraster.c                                                             */
+/*                                                                         */
+/*    The FreeType glyph rasterizer (body).                                */
+/*                                                                         */
+/*  Copyright 1996-2001, 2002, 2003, 2005, 2007, 2008, 2009, 2010, 2011 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.                                        */
+/*                                                                         */
+/***************************************************************************/
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* This file can be compiled without the rest of the FreeType engine, by */
+  /* defining the _STANDALONE_ macro when compiling it.  You also need to  */
+  /* put the files `ftimage.h' and `ftmisc.h' into the $(incdir)           */
+  /* directory.  Typically, you should do something like                   */
+  /*                                                                       */
+  /* - copy `src/raster/ftraster.c' (this file) to your current directory  */
+  /*                                                                       */
+  /* - copy `include/freetype/ftimage.h' and `src/raster/ftmisc.h'         */
+  /*   to your current directory                                           */
+  /*                                                                       */
+  /* - compile `ftraster' with the _STANDALONE_ macro defined, as in       */
+  /*                                                                       */
+  /*     cc -c -D_STANDALONE_ ftraster.c                                   */
+  /*                                                                       */
+  /* The renderer can be initialized with a call to                        */
+  /* `ft_standard_raster.raster_new'; a bitmap can be generated            */
+  /* with a call to `ft_standard_raster.raster_render'.                    */
+  /*                                                                       */
+  /* See the comments and documentation in the file `ftimage.h' for more   */
+  /* details on how the raster works.                                      */
+  /*                                                                       */
+  /*************************************************************************/
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* This is a rewrite of the FreeType 1.x scan-line converter             */
+  /*                                                                       */
+  /*************************************************************************/
+
+#ifdef _STANDALONE_
+
+#define FT_CONFIG_STANDARD_LIBRARY_H  <stdlib.h>
+
+#include <string.h>           /* for memset */
+
+#include "ftmisc.h"
+#include "ftimage.h"
+
+#else /* !_STANDALONE_ */
+
+#include <ft2build.h>
+#include "ftraster.h"
+#include FT_INTERNAL_CALC_H   /* for FT_MulDiv only */
+
+#include "rastpic.h"
+
+#endif /* !_STANDALONE_ */
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* A simple technical note on how the raster works                       */
+  /* -----------------------------------------------                       */
+  /*                                                                       */
+  /*   Converting an outline into a bitmap is achieved in several steps:   */
+  /*                                                                       */
+  /*   1 - Decomposing the outline into successive `profiles'.  Each       */
+  /*       profile is simply an array of scanline intersections on a given */
+  /*       dimension.  A profile's main attributes are                     */
+  /*                                                                       */
+  /*       o its scanline position boundaries, i.e. `Ymin' and `Ymax'      */
+  /*                                                                       */
+  /*       o an array of intersection coordinates for each scanline        */
+  /*         between `Ymin' and `Ymax'                                     */
+  /*                                                                       */
+  /*       o a direction, indicating whether it was built going `up' or    */
+  /*         `down', as this is very important for filling rules           */
+  /*                                                                       */
+  /*       o its drop-out mode                                             */
+  /*                                                                       */
+  /*   2 - Sweeping the target map's scanlines in order to compute segment */
+  /*       `spans' which are then filled.  Additionally, this pass         */
+  /*       performs drop-out control.                                      */
+  /*                                                                       */
+  /*   The outline data is parsed during step 1 only.  The profiles are    */
+  /*   built from the bottom of the render pool, used as a stack.  The     */
+  /*   following graphics shows the profile list under construction:       */
+  /*                                                                       */
+  /*     __________________________________________________________ _ _    */
+  /*    |         |                 |         |                 |          */
+  /*    | profile | coordinates for | profile | coordinates for |-->       */
+  /*    |    1    |  profile 1      |    2    |  profile 2      |-->       */
+  /*    |_________|_________________|_________|_________________|__ _ _    */
+  /*                                                                       */
+  /*    ^                                                       ^          */
+  /*    |                                                       |          */
+  /* start of render pool                                      top         */
+  /*                                                                       */
+  /*   The top of the profile stack is kept in the `top' variable.         */
+  /*                                                                       */
+  /*   As you can see, a profile record is pushed on top of the render     */
+  /*   pool, which is then followed by its coordinates/intersections.  If  */
+  /*   a change of direction is detected in the outline, a new profile is  */
+  /*   generated until the end of the outline.                             */
+  /*                                                                       */
+  /*   Note that when all profiles have been generated, the function       */
+  /*   Finalize_Profile_Table() is used to record, for each profile, its   */
+  /*   bottom-most scanline as well as the scanline above its upmost       */
+  /*   boundary.  These positions are called `y-turns' because they (sort  */
+  /*   of) correspond to local extrema.  They are stored in a sorted list  */
+  /*   built from the top of the render pool as a downwards stack:         */
+  /*                                                                       */
+  /*      _ _ _______________________________________                      */
+  /*                            |                    |                     */
+  /*                         <--| sorted list of     |                     */
+  /*                         <--|  extrema scanlines |                     */
+  /*      _ _ __________________|____________________|                     */
+  /*                                                                       */
+  /*                            ^                    ^                     */
+  /*                            |                    |                     */
+  /*                         maxBuff           sizeBuff = end of pool      */
+  /*                                                                       */
+  /*   This list is later used during the sweep phase in order to          */
+  /*   optimize performance (see technical note on the sweep below).       */
+  /*                                                                       */
+  /*   Of course, the raster detects whether the two stacks collide and    */
+  /*   handles the situation properly.                                     */
+  /*                                                                       */
+  /*************************************************************************/
+
+
+  /*************************************************************************/
+  /*************************************************************************/
+  /**                                                                     **/
+  /**  CONFIGURATION MACROS                                               **/
+  /**                                                                     **/
+  /*************************************************************************/
+  /*************************************************************************/
+
+  /* define DEBUG_RASTER if you want to compile a debugging version */
+/* #define DEBUG_RASTER */
+
+  /* define FT_RASTER_OPTION_ANTI_ALIASING if you want to support */
+  /* 5-levels anti-aliasing                                       */
+/* #define FT_RASTER_OPTION_ANTI_ALIASING */
+
+  /* The size of the two-lines intermediate bitmap used */
+  /* for anti-aliasing, in bytes.                       */
+#define RASTER_GRAY_LINES  2048
+
+
+  /*************************************************************************/
+  /*************************************************************************/
+  /**                                                                     **/
+  /**  OTHER MACROS (do not change)                                       **/
+  /**                                                                     **/
+  /*************************************************************************/
+  /*************************************************************************/
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* 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_raster
+
+
+#ifdef _STANDALONE_
+
+
+  /* This macro is used to indicate that a function parameter is unused. */
+  /* Its purpose is simply to reduce compiler warnings.  Note also that  */
+  /* simply defining it as `(void)x' doesn't avoid warnings with certain */
+  /* ANSI compilers (e.g. LCC).                                          */
+#define FT_UNUSED( x )  (x) = (x)
+
+  /* Disable the tracing mechanism for simplicity -- developers can      */
+  /* activate it easily by redefining these two macros.                  */
+#ifndef FT_ERROR
+#define FT_ERROR( x )  do { } while ( 0 )     /* nothing */
+#endif
+
+#ifndef FT_TRACE
+#define FT_TRACE( x )   do { } while ( 0 )    /* nothing */
+#define FT_TRACE1( x )  do { } while ( 0 )    /* nothing */
+#define FT_TRACE6( x )  do { } while ( 0 )    /* nothing */
+#endif
+
+#define Raster_Err_None          0
+#define Raster_Err_Not_Ini      -1
+#define Raster_Err_Overflow     -2
+#define Raster_Err_Neg_Height   -3
+#define Raster_Err_Invalid      -4
+#define Raster_Err_Unsupported  -5
+
+#define ft_memset  memset
+
+#define FT_DEFINE_RASTER_FUNCS( class_, glyph_format_, raster_new_, \
+                                raster_reset_, raster_set_mode_,    \
+                                raster_render_, raster_done_ )      \
+          const FT_Raster_Funcs class_ =                            \
+          {                                                         \
+            glyph_format_,                                          \
+            raster_new_,                                            \
+            raster_reset_,                                          \
+            raster_set_mode_,                                       \
+            raster_render_,                                         \
+            raster_done_                                            \
+         };
+
+#else /* !_STANDALONE_ */
+
+
+#include FT_INTERNAL_OBJECTS_H
+#include FT_INTERNAL_DEBUG_H        /* for FT_TRACE() and FT_ERROR() */
+
+#include "rasterrs.h"
+
+#define Raster_Err_None         Raster_Err_Ok
+#define Raster_Err_Not_Ini      Raster_Err_Raster_Uninitialized
+#define Raster_Err_Overflow     Raster_Err_Raster_Overflow
+#define Raster_Err_Neg_Height   Raster_Err_Raster_Negative_Height
+#define Raster_Err_Invalid      Raster_Err_Invalid_Outline
+#define Raster_Err_Unsupported  Raster_Err_Cannot_Render_Glyph
+
+
+#endif /* !_STANDALONE_ */
+
+
+#ifndef FT_MEM_SET
+#define FT_MEM_SET( d, s, c )  ft_memset( d, s, c )
+#endif
+
+#ifndef FT_MEM_ZERO
+#define FT_MEM_ZERO( dest, count )  FT_MEM_SET( dest, 0, count )
+#endif
+
+  /* FMulDiv means `Fast MulDiv'; it is used in case where `b' is       */
+  /* typically a small value and the result of a*b is known to fit into */
+  /* 32 bits.                                                           */
+#define FMulDiv( a, b, c )  ( (a) * (b) / (c) )
+
+  /* On the other hand, SMulDiv means `Slow MulDiv', and is used typically */
+  /* for clipping computations.  It simply uses the FT_MulDiv() function   */
+  /* defined in `ftcalc.h'.                                                */
+#define SMulDiv  FT_MulDiv
+
+  /* The rasterizer is a very general purpose component; please leave */
+  /* the following redefinitions there (you never know your target    */
+  /* environment).                                                    */
+
+#ifndef TRUE
+#define TRUE   1
+#endif
+
+#ifndef FALSE
+#define FALSE  0
+#endif
+
+#ifndef NULL
+#define NULL  (void*)0
+#endif
+
+#ifndef SUCCESS
+#define SUCCESS  0
+#endif
+
+#ifndef FAILURE
+#define FAILURE  1
+#endif
+
+
+#define MaxBezier  32   /* The maximum number of stacked Bezier curves. */
+                        /* Setting this constant to more than 32 is a   */
+                        /* pure waste of space.                         */
+
+#define Pixel_Bits  6   /* fractional bits of *input* coordinates */
+
+
+  /*************************************************************************/
+  /*************************************************************************/
+  /**                                                                     **/
+  /**  SIMPLE TYPE DECLARATIONS                                           **/
+  /**                                                                     **/
+  /*************************************************************************/
+  /*************************************************************************/
+
+  typedef int             Int;
+  typedef unsigned int    UInt;
+  typedef short           Short;
+  typedef unsigned short  UShort, *PUShort;
+  typedef long            Long, *PLong;
+
+  typedef unsigned char   Byte, *PByte;
+  typedef char            Bool;
+
+
+  typedef union  Alignment_
+  {
+    long    l;
+    void*   p;
+    void  (*f)(void);
+
+  } Alignment, *PAlignment;
+
+
+  typedef struct  TPoint_
+  {
+    Long  x;
+    Long  y;
+
+  } TPoint;
+
+
+  /* values for the `flags' bit field */
+#define Flow_Up           0x8
+#define Overshoot_Top     0x10
+#define Overshoot_Bottom  0x20
+
+
+  /* States of each line, arc, and profile */
+  typedef enum  TStates_
+  {
+    Unknown_State,
+    Ascending_State,
+    Descending_State,
+    Flat_State
+
+  } TStates;
+
+
+  typedef struct TProfile_  TProfile;
+  typedef TProfile*         PProfile;
+
+  struct  TProfile_
+  {
+    FT_F26Dot6  X;           /* current coordinate during sweep          */
+    PProfile    link;        /* link to next profile (various purposes)  */
+    PLong       offset;      /* start of profile's data in render pool   */
+    unsigned    flags;       /* Bit 0-2: drop-out mode                   */
+                             /* Bit 3: profile orientation (up/down)     */
+                             /* Bit 4: is top profile?                   */
+                             /* Bit 5: is bottom profile?                */
+    long        height;      /* profile's height in scanlines            */
+    long        start;       /* profile's starting scanline              */
+
+    unsigned    countL;      /* number of lines to step before this      */
+                             /* profile becomes drawable                 */
+
+    PProfile    next;        /* next profile in same contour, used       */
+                             /* during drop-out control                  */
+  };
+
+  typedef PProfile   TProfileList;
+  typedef PProfile*  PProfileList;
+
+
+  /* Simple record used to implement a stack of bands, required */
+  /* by the sub-banding mechanism                               */
+  typedef struct  TBand_
+  {
+    Short  y_min;   /* band's minimum */
+    Short  y_max;   /* band's maximum */
+
+  } TBand;
+
+
+#define AlignProfileSize \
+  ( ( sizeof ( TProfile ) + sizeof ( Alignment ) - 1 ) / sizeof ( long ) )
+
+
+#ifdef FT_STATIC_RASTER
+
+
+#define RAS_ARGS       /* void */
+#define RAS_ARG        /* void */
+
+#define RAS_VARS       /* void */
+#define RAS_VAR        /* void */
+
+#define FT_UNUSED_RASTER  do { } while ( 0 )
+
+
+#else /* !FT_STATIC_RASTER */
+
+
+#define RAS_ARGS       PWorker    worker,
+#define RAS_ARG        PWorker    worker
+
+#define RAS_VARS       worker,
+#define RAS_VAR        worker
+
+#define FT_UNUSED_RASTER  FT_UNUSED( worker )
+
+
+#endif /* !FT_STATIC_RASTER */
+
+
+  typedef struct TWorker_  TWorker, *PWorker;
+
+
+  /* prototypes used for sweep function dispatch */
+  typedef void
+  Function_Sweep_Init( RAS_ARGS Short*  min,
+                                Short*  max );
+
+  typedef void
+  Function_Sweep_Span( RAS_ARGS Short       y,
+                                FT_F26Dot6  x1,
+                                FT_F26Dot6  x2,
+                                PProfile    left,
+                                PProfile    right );
+
+  typedef void
+  Function_Sweep_Step( RAS_ARG );
+
+
+  /* NOTE: These operations are only valid on 2's complement processors */
+
+#define FLOOR( x )    ( (x) & -ras.precision )
+#define CEILING( x )  ( ( (x) + ras.precision - 1 ) & -ras.precision )
+#define TRUNC( x )    ( (signed long)(x) >> ras.precision_bits )
+#define FRAC( x )     ( (x) & ( ras.precision - 1 ) )
+#define SCALED( x )   ( ( (x) << ras.scale_shift ) - ras.precision_half )
+
+#define IS_BOTTOM_OVERSHOOT( x )  ( CEILING( x ) - x >= ras.precision_half )
+#define IS_TOP_OVERSHOOT( x )     ( x - FLOOR( x ) >= ras.precision_half )
+
+  /* The most used variables are positioned at the top of the structure. */
+  /* Thus, their offset can be coded with less opcodes, resulting in a   */
+  /* smaller executable.                                                 */
+
+  struct  TWorker_
+  {
+    Int         precision_bits;     /* precision related variables         */
+    Int         precision;
+    Int         precision_half;
+    Int         precision_shift;
+    Int         precision_step;
+    Int         precision_jitter;
+
+    Int         scale_shift;        /* == precision_shift   for bitmaps    */
+                                    /* == precision_shift+1 for pixmaps    */
+
+    PLong       buff;               /* The profiles buffer                 */
+    PLong       sizeBuff;           /* Render pool size                    */
+    PLong       maxBuff;            /* Profiles buffer size                */
+    PLong       top;                /* Current cursor in buffer            */
+
+    FT_Error    error;
+
+    Int         numTurns;           /* number of Y-turns in outline        */
+
+    TPoint*     arc;                /* current Bezier arc pointer          */
+
+    UShort      bWidth;             /* target bitmap width                 */
+    PByte       bTarget;            /* target bitmap buffer                */
+    PByte       gTarget;            /* target pixmap buffer                */
+
+    Long        lastX, lastY;
+    Long        minY, maxY;
+
+    UShort      num_Profs;          /* current number of profiles          */
+
+    Bool        fresh;              /* signals a fresh new profile which   */
+                                    /* `start' field must be completed     */
+    Bool        joint;              /* signals that the last arc ended     */
+                                    /* exactly on a scanline.  Allows      */
+                                    /* removal of doublets                 */
+    PProfile    cProfile;           /* current profile                     */
+    PProfile    fProfile;           /* head of linked list of profiles     */
+    PProfile    gProfile;           /* contour's first profile in case     */
+                                    /* of impact                           */
+
+    TStates     state;              /* rendering state                     */
+
+    FT_Bitmap   target;             /* description of target bit/pixmap    */
+    FT_Outline  outline;
+
+    Long        traceOfs;           /* current offset in target bitmap     */
+    Long        traceG;             /* current offset in target pixmap     */
+
+    Short       traceIncr;          /* sweep's increment in target bitmap  */
+
+    Short       gray_min_x;         /* current min x during gray rendering */
+    Short       gray_max_x;         /* current max x during gray rendering */
+
+    /* dispatch variables */
+
+    Function_Sweep_Init*  Proc_Sweep_Init;
+    Function_Sweep_Span*  Proc_Sweep_Span;
+    Function_Sweep_Span*  Proc_Sweep_Drop;
+    Function_Sweep_Step*  Proc_Sweep_Step;
+
+    Byte        dropOutControl;     /* current drop_out control method     */
+
+    Bool        second_pass;        /* indicates whether a horizontal pass */
+                                    /* should be performed to control      */
+                                    /* drop-out accurately when calling    */
+                                    /* Render_Glyph.  Note that there is   */
+                                    /* no horizontal pass during gray      */
+                                    /* rendering.                          */
+
+    TPoint      arcs[3 * MaxBezier + 1]; /* The Bezier stack               */
+
+    TBand       band_stack[16];     /* band stack used for sub-banding     */
+    Int         band_top;           /* band stack top                      */
+
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+
+    Byte*       grays;
+
+    Byte        gray_lines[RASTER_GRAY_LINES];
+                                /* Intermediate table used to render the   */
+                                /* graylevels pixmaps.                     */
+                                /* gray_lines is a buffer holding two      */
+                                /* monochrome scanlines                    */
+
+    Short       gray_width;     /* width in bytes of one monochrome        */
+                                /* intermediate scanline of gray_lines.    */
+                                /* Each gray pixel takes 2 bits long there */
+
+                       /* The gray_lines must hold 2 lines, thus with size */
+                       /* in bytes of at least `gray_width*2'.             */
+
+#endif /* FT_RASTER_ANTI_ALIASING */
+
+  };
+
+
+  typedef struct  TRaster_
+  {
+    char*    buffer;
+    long     buffer_size;
+    void*    memory;
+    PWorker  worker;
+    Byte     grays[5];
+    Short    gray_width;
+
+  } TRaster, *PRaster;
+
+#ifdef FT_STATIC_RASTER
+
+  static TWorker  cur_ras;
+#define ras  cur_ras
+
+#else /* !FT_STATIC_RASTER */
+
+#define ras  (*worker)
+
+#endif /* !FT_STATIC_RASTER */
+
+
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+
+  /* A lookup table used to quickly count set bits in four gray 2x2 */
+  /* cells.  The values of the table have been produced with the    */
+  /* following code:                                                */
+  /*                                                                */
+  /*   for ( i = 0; i < 256; i++ )                                  */
+  /*   {                                                            */
+  /*     l = 0;                                                     */
+  /*     j = i;                                                     */
+  /*                                                                */
+  /*     for ( c = 0; c < 4; c++ )                                  */
+  /*     {                                                          */
+  /*       l <<= 4;                                                 */
+  /*                                                                */
+  /*       if ( j & 0x80 ) l++;                                     */
+  /*       if ( j & 0x40 ) l++;                                     */
+  /*                                                                */
+  /*       j = ( j << 2 ) & 0xFF;                                   */
+  /*     }                                                          */
+  /*     printf( "0x%04X", l );                                     */
+  /*   }                                                            */
+  /*                                                                */
+
+  static const short  count_table[256] =
+  {
+    0x0000, 0x0001, 0x0001, 0x0002, 0x0010, 0x0011, 0x0011, 0x0012,
+    0x0010, 0x0011, 0x0011, 0x0012, 0x0020, 0x0021, 0x0021, 0x0022,
+    0x0100, 0x0101, 0x0101, 0x0102, 0x0110, 0x0111, 0x0111, 0x0112,
+    0x0110, 0x0111, 0x0111, 0x0112, 0x0120, 0x0121, 0x0121, 0x0122,
+    0x0100, 0x0101, 0x0101, 0x0102, 0x0110, 0x0111, 0x0111, 0x0112,
+    0x0110, 0x0111, 0x0111, 0x0112, 0x0120, 0x0121, 0x0121, 0x0122,
+    0x0200, 0x0201, 0x0201, 0x0202, 0x0210, 0x0211, 0x0211, 0x0212,
+    0x0210, 0x0211, 0x0211, 0x0212, 0x0220, 0x0221, 0x0221, 0x0222,
+    0x1000, 0x1001, 0x1001, 0x1002, 0x1010, 0x1011, 0x1011, 0x1012,
+    0x1010, 0x1011, 0x1011, 0x1012, 0x1020, 0x1021, 0x1021, 0x1022,
+    0x1100, 0x1101, 0x1101, 0x1102, 0x1110, 0x1111, 0x1111, 0x1112,
+    0x1110, 0x1111, 0x1111, 0x1112, 0x1120, 0x1121, 0x1121, 0x1122,
+    0x1100, 0x1101, 0x1101, 0x1102, 0x1110, 0x1111, 0x1111, 0x1112,
+    0x1110, 0x1111, 0x1111, 0x1112, 0x1120, 0x1121, 0x1121, 0x1122,
+    0x1200, 0x1201, 0x1201, 0x1202, 0x1210, 0x1211, 0x1211, 0x1212,
+    0x1210, 0x1211, 0x1211, 0x1212, 0x1220, 0x1221, 0x1221, 0x1222,
+    0x1000, 0x1001, 0x1001, 0x1002, 0x1010, 0x1011, 0x1011, 0x1012,
+    0x1010, 0x1011, 0x1011, 0x1012, 0x1020, 0x1021, 0x1021, 0x1022,
+    0x1100, 0x1101, 0x1101, 0x1102, 0x1110, 0x1111, 0x1111, 0x1112,
+    0x1110, 0x1111, 0x1111, 0x1112, 0x1120, 0x1121, 0x1121, 0x1122,
+    0x1100, 0x1101, 0x1101, 0x1102, 0x1110, 0x1111, 0x1111, 0x1112,
+    0x1110, 0x1111, 0x1111, 0x1112, 0x1120, 0x1121, 0x1121, 0x1122,
+    0x1200, 0x1201, 0x1201, 0x1202, 0x1210, 0x1211, 0x1211, 0x1212,
+    0x1210, 0x1211, 0x1211, 0x1212, 0x1220, 0x1221, 0x1221, 0x1222,
+    0x2000, 0x2001, 0x2001, 0x2002, 0x2010, 0x2011, 0x2011, 0x2012,
+    0x2010, 0x2011, 0x2011, 0x2012, 0x2020, 0x2021, 0x2021, 0x2022,
+    0x2100, 0x2101, 0x2101, 0x2102, 0x2110, 0x2111, 0x2111, 0x2112,
+    0x2110, 0x2111, 0x2111, 0x2112, 0x2120, 0x2121, 0x2121, 0x2122,
+    0x2100, 0x2101, 0x2101, 0x2102, 0x2110, 0x2111, 0x2111, 0x2112,
+    0x2110, 0x2111, 0x2111, 0x2112, 0x2120, 0x2121, 0x2121, 0x2122,
+    0x2200, 0x2201, 0x2201, 0x2202, 0x2210, 0x2211, 0x2211, 0x2212,
+    0x2210, 0x2211, 0x2211, 0x2212, 0x2220, 0x2221, 0x2221, 0x2222
+  };
+
+#endif /* FT_RASTER_OPTION_ANTI_ALIASING */
+
+
+
+  /*************************************************************************/
+  /*************************************************************************/
+  /**                                                                     **/
+  /**  PROFILES COMPUTATION                                               **/
+  /**                                                                     **/
+  /*************************************************************************/
+  /*************************************************************************/
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Set_High_Precision                                                 */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Set precision variables according to param flag.                   */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    High :: Set to True for high precision (typically for ppem < 18),  */
+  /*            false otherwise.                                           */
+  /*                                                                       */
+  static void
+  Set_High_Precision( RAS_ARGS Int  High )
+  {
+    /*
+     * `precision_step' is used in `Bezier_Up' to decide when to split a
+     * given y-monotonous Bezier arc that crosses a scanline before
+     * approximating it as a straight segment.  The default value of 32 (for
+     * low accuracy) corresponds to
+     *
+     *   32 / 64 == 0.5 pixels ,
+     *
+     * while for the high accuracy case we have
+     *
+     *   256/ (1 << 12) = 0.0625 pixels .
+     *
+     * `precision_jitter' is an epsilon threshold used in
+     * `Vertical_Sweep_Span' to deal with small imperfections in the Bezier
+     * decomposition (after all, we are working with approximations only);
+     * it avoids switching on additional pixels which would cause artifacts
+     * otherwise.
+     *
+     * The value of `precision_jitter' has been determined heuristically.
+     *
+     */
+
+    if ( High )
+    {
+      ras.precision_bits   = 12;
+      ras.precision_step   = 256;
+      ras.precision_jitter = 30;
+    }
+    else
+    {
+      ras.precision_bits   = 6;
+      ras.precision_step   = 32;
+      ras.precision_jitter = 2;
+    }
+
+    FT_TRACE6(( "Set_High_Precision(%s)\n", High ? "true" : "false" ));
+
+    ras.precision       = 1 << ras.precision_bits;
+    ras.precision_half  = ras.precision / 2;
+    ras.precision_shift = ras.precision_bits - Pixel_Bits;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    New_Profile                                                        */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Create a new profile in the render pool.                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    aState    :: The state/orientation of the new profile.             */
+  /*                                                                       */
+  /*    overshoot :: Whether the profile's unrounded start position        */
+  /*                 differs by at least a half pixel.                     */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*   SUCCESS on success.  FAILURE in case of overflow or of incoherent   */
+  /*   profile.                                                            */
+  /*                                                                       */
+  static Bool
+  New_Profile( RAS_ARGS TStates  aState,
+                        Bool     overshoot )
+  {
+    if ( !ras.fProfile )
+    {
+      ras.cProfile  = (PProfile)ras.top;
+      ras.fProfile  = ras.cProfile;
+      ras.top      += AlignProfileSize;
+    }
+
+    if ( ras.top >= ras.maxBuff )
+    {
+      ras.error = Raster_Err_Overflow;
+      return FAILURE;
+    }
+
+    ras.cProfile->flags  = 0;
+    ras.cProfile->start  = 0;
+    ras.cProfile->height = 0;
+    ras.cProfile->offset = ras.top;
+    ras.cProfile->link   = (PProfile)0;
+    ras.cProfile->next   = (PProfile)0;
+    ras.cProfile->flags  = ras.dropOutControl;
+
+    switch ( aState )
+    {
+    case Ascending_State:
+      ras.cProfile->flags |= Flow_Up;
+      if ( overshoot )
+        ras.cProfile->flags |= Overshoot_Bottom;
+
+      FT_TRACE6(( "New ascending profile = %p\n", ras.cProfile ));
+      break;
+
+    case Descending_State:
+      if ( overshoot )
+        ras.cProfile->flags |= Overshoot_Top;
+      FT_TRACE6(( "New descending profile = %p\n", ras.cProfile ));
+      break;
+
+    default:
+      FT_ERROR(( "New_Profile: invalid profile direction\n" ));
+      ras.error = Raster_Err_Invalid;
+      return FAILURE;
+    }
+
+    if ( !ras.gProfile )
+      ras.gProfile = ras.cProfile;
+
+    ras.state = aState;
+    ras.fresh = TRUE;
+    ras.joint = FALSE;
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    End_Profile                                                        */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Finalize the current profile.                                      */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    overshoot :: Whether the profile's unrounded end position differs  */
+  /*                 by at least a half pixel.                             */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success.  FAILURE in case of overflow or incoherency.   */
+  /*                                                                       */
+  static Bool
+  End_Profile( RAS_ARGS Bool  overshoot )
+  {
+    Long      h;
+    PProfile  oldProfile;
+
+
+    h = (Long)( ras.top - ras.cProfile->offset );
+
+    if ( h < 0 )
+    {
+      FT_ERROR(( "End_Profile: negative height encountered\n" ));
+      ras.error = Raster_Err_Neg_Height;
+      return FAILURE;
+    }
+
+    if ( h > 0 )
+    {
+      FT_TRACE6(( "Ending profile %p, start = %ld, height = %ld\n",
+                  ras.cProfile, ras.cProfile->start, h ));
+
+      ras.cProfile->height = h;
+      if ( overshoot )
+      {
+        if ( ras.cProfile->flags & Flow_Up )
+          ras.cProfile->flags |= Overshoot_Top;
+        else
+          ras.cProfile->flags |= Overshoot_Bottom;
+      }
+
+      oldProfile   = ras.cProfile;
+      ras.cProfile = (PProfile)ras.top;
+
+      ras.top += AlignProfileSize;
+
+      ras.cProfile->height = 0;
+      ras.cProfile->offset = ras.top;
+
+      oldProfile->next = ras.cProfile;
+      ras.num_Profs++;
+    }
+
+    if ( ras.top >= ras.maxBuff )
+    {
+      FT_TRACE1(( "overflow in End_Profile\n" ));
+      ras.error = Raster_Err_Overflow;
+      return FAILURE;
+    }
+
+    ras.joint = FALSE;
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Insert_Y_Turn                                                      */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Insert a salient into the sorted list placed on top of the render  */
+  /*    pool.                                                              */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    New y scanline position.                                           */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success.  FAILURE in case of overflow.                  */
+  /*                                                                       */
+  static Bool
+  Insert_Y_Turn( RAS_ARGS Int  y )
+  {
+    PLong  y_turns;
+    Int    y2, n;
+
+
+    n       = ras.numTurns - 1;
+    y_turns = ras.sizeBuff - ras.numTurns;
+
+    /* look for first y value that is <= */
+    while ( n >= 0 && y < y_turns[n] )
+      n--;
+
+    /* if it is <, simply insert it, ignore if == */
+    if ( n >= 0 && y > y_turns[n] )
+      while ( n >= 0 )
+      {
+        y2 = (Int)y_turns[n];
+        y_turns[n] = y;
+        y = y2;
+        n--;
+      }
+
+    if ( n < 0 )
+    {
+      ras.maxBuff--;
+      if ( ras.maxBuff <= ras.top )
+      {
+        ras.error = Raster_Err_Overflow;
+        return FAILURE;
+      }
+      ras.numTurns++;
+      ras.sizeBuff[-ras.numTurns] = y;
+    }
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Finalize_Profile_Table                                             */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Adjust all links in the profiles list.                             */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success.  FAILURE in case of overflow.                  */
+  /*                                                                       */
+  static Bool
+  Finalize_Profile_Table( RAS_ARG )
+  {
+    Int       bottom, top;
+    UShort    n;
+    PProfile  p;
+
+
+    n = ras.num_Profs;
+    p = ras.fProfile;
+
+    if ( n > 1 && p )
+    {
+      while ( n > 0 )
+      {
+        if ( n > 1 )
+          p->link = (PProfile)( p->offset + p->height );
+        else
+          p->link = NULL;
+
+        if ( p->flags & Flow_Up )
+        {
+          bottom = (Int)p->start;
+          top    = (Int)( p->start + p->height - 1 );
+        }
+        else
+        {
+          bottom     = (Int)( p->start - p->height + 1 );
+          top        = (Int)p->start;
+          p->start   = bottom;
+          p->offset += p->height - 1;
+        }
+
+        if ( Insert_Y_Turn( RAS_VARS bottom )  ||
+             Insert_Y_Turn( RAS_VARS top + 1 ) )
+          return FAILURE;
+
+        p = p->link;
+        n--;
+      }
+    }
+    else
+      ras.fProfile = NULL;
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Split_Conic                                                        */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Subdivide one conic Bezier into two joint sub-arcs in the Bezier   */
+  /*    stack.                                                             */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    None (subdivided Bezier is taken from the top of the stack).       */
+  /*                                                                       */
+  /* <Note>                                                                */
+  /*    This routine is the `beef' of this component.  It is  _the_ inner  */
+  /*    loop that should be optimized to hell to get the best performance. */
+  /*                                                                       */
+  static void
+  Split_Conic( TPoint*  base )
+  {
+    Long  a, b;
+
+
+    base[4].x = base[2].x;
+    b = base[1].x;
+    a = base[3].x = ( base[2].x + b ) / 2;
+    b = base[1].x = ( base[0].x + b ) / 2;
+    base[2].x = ( a + b ) / 2;
+
+    base[4].y = base[2].y;
+    b = base[1].y;
+    a = base[3].y = ( base[2].y + b ) / 2;
+    b = base[1].y = ( base[0].y + b ) / 2;
+    base[2].y = ( a + b ) / 2;
+
+    /* hand optimized.  gcc doesn't seem to be too good at common      */
+    /* expression substitution and instruction scheduling ;-)          */
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Split_Cubic                                                        */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Subdivide a third-order Bezier arc into two joint sub-arcs in the  */
+  /*    Bezier stack.                                                      */
+  /*                                                                       */
+  /* <Note>                                                                */
+  /*    This routine is the `beef' of the component.  It is one of _the_   */
+  /*    inner loops that should be optimized like hell to get the best     */
+  /*    performance.                                                       */
+  /*                                                                       */
+  static void
+  Split_Cubic( TPoint*  base )
+  {
+    Long  a, b, c, d;
+
+
+    base[6].x = base[3].x;
+    c = base[1].x;
+    d = base[2].x;
+    base[1].x = a = ( base[0].x + c + 1 ) >> 1;
+    base[5].x = b = ( base[3].x + d + 1 ) >> 1;
+    c = ( c + d + 1 ) >> 1;
+    base[2].x = a = ( a + c + 1 ) >> 1;
+    base[4].x = b = ( b + c + 1 ) >> 1;
+    base[3].x = ( a + b + 1 ) >> 1;
+
+    base[6].y = base[3].y;
+    c = base[1].y;
+    d = base[2].y;
+    base[1].y = a = ( base[0].y + c + 1 ) >> 1;
+    base[5].y = b = ( base[3].y + d + 1 ) >> 1;
+    c = ( c + d + 1 ) >> 1;
+    base[2].y = a = ( a + c + 1 ) >> 1;
+    base[4].y = b = ( b + c + 1 ) >> 1;
+    base[3].y = ( a + b + 1 ) >> 1;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Line_Up                                                            */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Compute the x-coordinates of an ascending line segment and store   */
+  /*    them in the render pool.                                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    x1   :: The x-coordinate of the segment's start point.             */
+  /*                                                                       */
+  /*    y1   :: The y-coordinate of the segment's start point.             */
+  /*                                                                       */
+  /*    x2   :: The x-coordinate of the segment's end point.               */
+  /*                                                                       */
+  /*    y2   :: The y-coordinate of the segment's end point.               */
+  /*                                                                       */
+  /*    miny :: A lower vertical clipping bound value.                     */
+  /*                                                                       */
+  /*    maxy :: An upper vertical clipping bound value.                    */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE on render pool overflow.               */
+  /*                                                                       */
+  static Bool
+  Line_Up( RAS_ARGS Long  x1,
+                    Long  y1,
+                    Long  x2,
+                    Long  y2,
+                    Long  miny,
+                    Long  maxy )
+  {
+    Long   Dx, Dy;
+    Int    e1, e2, f1, f2, size;     /* XXX: is `Short' sufficient? */
+    Long   Ix, Rx, Ax;
+
+    PLong  top;
+
+
+    Dx = x2 - x1;
+    Dy = y2 - y1;
+
+    if ( Dy <= 0 || y2 < miny || y1 > maxy )
+      return SUCCESS;
+
+    if ( y1 < miny )
+    {
+      /* Take care: miny-y1 can be a very large value; we use     */
+      /*            a slow MulDiv function to avoid clipping bugs */
+      x1 += SMulDiv( Dx, miny - y1, Dy );
+      e1  = (Int)TRUNC( miny );
+      f1  = 0;
+    }
+    else
+    {
+      e1 = (Int)TRUNC( y1 );
+      f1 = (Int)FRAC( y1 );
+    }
+
+    if ( y2 > maxy )
+    {
+      /* x2 += FMulDiv( Dx, maxy - y2, Dy );  UNNECESSARY */
+      e2  = (Int)TRUNC( maxy );
+      f2  = 0;
+    }
+    else
+    {
+      e2 = (Int)TRUNC( y2 );
+      f2 = (Int)FRAC( y2 );
+    }
+
+    if ( f1 > 0 )
+    {
+      if ( e1 == e2 )
+        return SUCCESS;
+      else
+      {
+        x1 += SMulDiv( Dx, ras.precision - f1, Dy );
+        e1 += 1;
+      }
+    }
+    else
+      if ( ras.joint )
+      {
+        ras.top--;
+        ras.joint = FALSE;
+      }
+
+    ras.joint = (char)( f2 == 0 );
+
+    if ( ras.fresh )
+    {
+      ras.cProfile->start = e1;
+      ras.fresh           = FALSE;
+    }
+
+    size = e2 - e1 + 1;
+    if ( ras.top + size >= ras.maxBuff )
+    {
+      ras.error = Raster_Err_Overflow;
+      return FAILURE;
+    }
+
+    if ( Dx > 0 )
+    {
+      Ix = SMulDiv( ras.precision, Dx, Dy);
+      Rx = ( ras.precision * Dx ) % Dy;
+      Dx = 1;
+    }
+    else
+    {
+      Ix = SMulDiv( ras.precision, -Dx, Dy) * -1;
+      Rx =    ( ras.precision * -Dx ) % Dy;
+      Dx = -1;
+    }
+
+    Ax  = -Dy;
+    top = ras.top;
+
+    while ( size > 0 )
+    {
+      *top++ = x1;
+
+      x1 += Ix;
+      Ax += Rx;
+      if ( Ax >= 0 )
+      {
+        Ax -= Dy;
+        x1 += Dx;
+      }
+      size--;
+    }
+
+    ras.top = top;
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Line_Down                                                          */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Compute the x-coordinates of an descending line segment and store  */
+  /*    them in the render pool.                                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    x1   :: The x-coordinate of the segment's start point.             */
+  /*                                                                       */
+  /*    y1   :: The y-coordinate of the segment's start point.             */
+  /*                                                                       */
+  /*    x2   :: The x-coordinate of the segment's end point.               */
+  /*                                                                       */
+  /*    y2   :: The y-coordinate of the segment's end point.               */
+  /*                                                                       */
+  /*    miny :: A lower vertical clipping bound value.                     */
+  /*                                                                       */
+  /*    maxy :: An upper vertical clipping bound value.                    */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE on render pool overflow.               */
+  /*                                                                       */
+  static Bool
+  Line_Down( RAS_ARGS Long  x1,
+                      Long  y1,
+                      Long  x2,
+                      Long  y2,
+                      Long  miny,
+                      Long  maxy )
+  {
+    Bool  result, fresh;
+
+
+    fresh  = ras.fresh;
+
+    result = Line_Up( RAS_VARS x1, -y1, x2, -y2, -maxy, -miny );
+
+    if ( fresh && !ras.fresh )
+      ras.cProfile->start = -ras.cProfile->start;
+
+    return result;
+  }
+
+
+  /* A function type describing the functions used to split Bezier arcs */
+  typedef void  (*TSplitter)( TPoint*  base );
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Bezier_Up                                                          */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Compute the x-coordinates of an ascending Bezier arc and store     */
+  /*    them in the render pool.                                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    degree   :: The degree of the Bezier arc (either 2 or 3).          */
+  /*                                                                       */
+  /*    splitter :: The function to split Bezier arcs.                     */
+  /*                                                                       */
+  /*    miny     :: A lower vertical clipping bound value.                 */
+  /*                                                                       */
+  /*    maxy     :: An upper vertical clipping bound value.                */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE on render pool overflow.               */
+  /*                                                                       */
+  static Bool
+  Bezier_Up( RAS_ARGS Int        degree,
+                      TSplitter  splitter,
+                      Long       miny,
+                      Long       maxy )
+  {
+    Long   y1, y2, e, e2, e0;
+    Short  f1;
+
+    TPoint*  arc;
+    TPoint*  start_arc;
+
+    PLong top;
+
+
+    arc = ras.arc;
+    y1  = arc[degree].y;
+    y2  = arc[0].y;
+    top = ras.top;
+
+    if ( y2 < miny || y1 > maxy )
+      goto Fin;
+
+    e2 = FLOOR( y2 );
+
+    if ( e2 > maxy )
+      e2 = maxy;
+
+    e0 = miny;
+
+    if ( y1 < miny )
+      e = miny;
+    else
+    {
+      e  = CEILING( y1 );
+      f1 = (Short)( FRAC( y1 ) );
+      e0 = e;
+
+      if ( f1 == 0 )
+      {
+        if ( ras.joint )
+        {
+          top--;
+          ras.joint = FALSE;
+        }
+
+        *top++ = arc[degree].x;
+
+        e += ras.precision;
+      }
+    }
+
+    if ( ras.fresh )
+    {
+      ras.cProfile->start = TRUNC( e0 );
+      ras.fresh = FALSE;
+    }
+
+    if ( e2 < e )
+      goto Fin;
+
+    if ( ( top + TRUNC( e2 - e ) + 1 ) >= ras.maxBuff )
+    {
+      ras.top   = top;
+      ras.error = Raster_Err_Overflow;
+      return FAILURE;
+    }
+
+    start_arc = arc;
+
+    while ( arc >= start_arc && e <= e2 )
+    {
+      ras.joint = FALSE;
+
+      y2 = arc[0].y;
+
+      if ( y2 > e )
+      {
+        y1 = arc[degree].y;
+        if ( y2 - y1 >= ras.precision_step )
+        {
+          splitter( arc );
+          arc += degree;
+        }
+        else
+        {
+          *top++ = arc[degree].x + FMulDiv( arc[0].x - arc[degree].x,
+                                            e - y1, y2 - y1 );
+          arc -= degree;
+          e   += ras.precision;
+        }
+      }
+      else
+      {
+        if ( y2 == e )
+        {
+          ras.joint  = TRUE;
+          *top++     = arc[0].x;
+
+          e += ras.precision;
+        }
+        arc -= degree;
+      }
+    }
+
+  Fin:
+    ras.top  = top;
+    ras.arc -= degree;
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Bezier_Down                                                        */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Compute the x-coordinates of an descending Bezier arc and store    */
+  /*    them in the render pool.                                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    degree   :: The degree of the Bezier arc (either 2 or 3).          */
+  /*                                                                       */
+  /*    splitter :: The function to split Bezier arcs.                     */
+  /*                                                                       */
+  /*    miny     :: A lower vertical clipping bound value.                 */
+  /*                                                                       */
+  /*    maxy     :: An upper vertical clipping bound value.                */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE on render pool overflow.               */
+  /*                                                                       */
+  static Bool
+  Bezier_Down( RAS_ARGS Int        degree,
+                        TSplitter  splitter,
+                        Long       miny,
+                        Long       maxy )
+  {
+    TPoint*  arc = ras.arc;
+    Bool     result, fresh;
+
+
+    arc[0].y = -arc[0].y;
+    arc[1].y = -arc[1].y;
+    arc[2].y = -arc[2].y;
+    if ( degree > 2 )
+      arc[3].y = -arc[3].y;
+
+    fresh = ras.fresh;
+
+    result = Bezier_Up( RAS_VARS degree, splitter, -maxy, -miny );
+
+    if ( fresh && !ras.fresh )
+      ras.cProfile->start = -ras.cProfile->start;
+
+    arc[0].y = -arc[0].y;
+    return result;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Line_To                                                            */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Inject a new line segment and adjust the Profiles list.            */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*   x :: The x-coordinate of the segment's end point (its start point   */
+  /*        is stored in `lastX').                                         */
+  /*                                                                       */
+  /*   y :: The y-coordinate of the segment's end point (its start point   */
+  /*        is stored in `lastY').                                         */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*   SUCCESS on success, FAILURE on render pool overflow or incorrect    */
+  /*   profile.                                                            */
+  /*                                                                       */
+  static Bool
+  Line_To( RAS_ARGS Long  x,
+                    Long  y )
+  {
+    /* First, detect a change of direction */
+
+    switch ( ras.state )
+    {
+    case Unknown_State:
+      if ( y > ras.lastY )
+      {
+        if ( New_Profile( RAS_VARS Ascending_State,
+                                   IS_BOTTOM_OVERSHOOT( ras.lastY ) ) )
+          return FAILURE;
+      }
+      else
+      {
+        if ( y < ras.lastY )
+          if ( New_Profile( RAS_VARS Descending_State,
+                                     IS_TOP_OVERSHOOT( ras.lastY ) ) )
+            return FAILURE;
+      }
+      break;
+
+    case Ascending_State:
+      if ( y < ras.lastY )
+      {
+        if ( End_Profile( RAS_VARS IS_TOP_OVERSHOOT( ras.lastY ) ) ||
+             New_Profile( RAS_VARS Descending_State,
+                                   IS_TOP_OVERSHOOT( ras.lastY ) ) )
+          return FAILURE;
+      }
+      break;
+
+    case Descending_State:
+      if ( y > ras.lastY )
+      {
+        if ( End_Profile( RAS_VARS IS_BOTTOM_OVERSHOOT( ras.lastY ) ) ||
+             New_Profile( RAS_VARS Ascending_State,
+                                   IS_BOTTOM_OVERSHOOT( ras.lastY ) ) )
+          return FAILURE;
+      }
+      break;
+
+    default:
+      ;
+    }
+
+    /* Then compute the lines */
+
+    switch ( ras.state )
+    {
+    case Ascending_State:
+      if ( Line_Up( RAS_VARS ras.lastX, ras.lastY,
+                             x, y, ras.minY, ras.maxY ) )
+        return FAILURE;
+      break;
+
+    case Descending_State:
+      if ( Line_Down( RAS_VARS ras.lastX, ras.lastY,
+                               x, y, ras.minY, ras.maxY ) )
+        return FAILURE;
+      break;
+
+    default:
+      ;
+    }
+
+    ras.lastX = x;
+    ras.lastY = y;
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Conic_To                                                           */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Inject a new conic arc and adjust the profile list.                */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*   cx :: The x-coordinate of the arc's new control point.              */
+  /*                                                                       */
+  /*   cy :: The y-coordinate of the arc's new control point.              */
+  /*                                                                       */
+  /*   x  :: The x-coordinate of the arc's end point (its start point is   */
+  /*         stored in `lastX').                                           */
+  /*                                                                       */
+  /*   y  :: The y-coordinate of the arc's end point (its start point is   */
+  /*         stored in `lastY').                                           */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*   SUCCESS on success, FAILURE on render pool overflow or incorrect    */
+  /*   profile.                                                            */
+  /*                                                                       */
+  static Bool
+  Conic_To( RAS_ARGS Long  cx,
+                     Long  cy,
+                     Long  x,
+                     Long  y )
+  {
+    Long     y1, y2, y3, x3, ymin, ymax;
+    TStates  state_bez;
+
+
+    ras.arc      = ras.arcs;
+    ras.arc[2].x = ras.lastX;
+    ras.arc[2].y = ras.lastY;
+    ras.arc[1].x = cx;
+    ras.arc[1].y = cy;
+    ras.arc[0].x = x;
+    ras.arc[0].y = y;
+
+    do
+    {
+      y1 = ras.arc[2].y;
+      y2 = ras.arc[1].y;
+      y3 = ras.arc[0].y;
+      x3 = ras.arc[0].x;
+
+      /* first, categorize the Bezier arc */
+
+      if ( y1 <= y3 )
+      {
+        ymin = y1;
+        ymax = y3;
+      }
+      else
+      {
+        ymin = y3;
+        ymax = y1;
+      }
+
+      if ( y2 < ymin || y2 > ymax )
+      {
+        /* this arc has no given direction, split it! */
+        Split_Conic( ras.arc );
+        ras.arc += 2;
+      }
+      else if ( y1 == y3 )
+      {
+        /* this arc is flat, ignore it and pop it from the Bezier stack */
+        ras.arc -= 2;
+      }
+      else
+      {
+        /* the arc is y-monotonous, either ascending or descending */
+        /* detect a change of direction                            */
+        state_bez = y1 < y3 ? Ascending_State : Descending_State;
+        if ( ras.state != state_bez )
+        {
+          Bool  o = state_bez == Ascending_State ? IS_BOTTOM_OVERSHOOT( y1 )
+                                                 : IS_TOP_OVERSHOOT( y1 );
+
+
+          /* finalize current profile if any */
+          if ( ras.state != Unknown_State &&
+               End_Profile( RAS_VARS o )  )
+            goto Fail;
+
+          /* create a new profile */
+          if ( New_Profile( RAS_VARS state_bez, o ) )
+            goto Fail;
+        }
+
+        /* now call the appropriate routine */
+        if ( state_bez == Ascending_State )
+        {
+          if ( Bezier_Up( RAS_VARS 2, Split_Conic, ras.minY, ras.maxY ) )
+            goto Fail;
+        }
+        else
+          if ( Bezier_Down( RAS_VARS 2, Split_Conic, ras.minY, ras.maxY ) )
+            goto Fail;
+      }
+
+    } while ( ras.arc >= ras.arcs );
+
+    ras.lastX = x3;
+    ras.lastY = y3;
+
+    return SUCCESS;
+
+  Fail:
+    return FAILURE;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Cubic_To                                                           */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Inject a new cubic arc and adjust the profile list.                */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*   cx1 :: The x-coordinate of the arc's first new control point.       */
+  /*                                                                       */
+  /*   cy1 :: The y-coordinate of the arc's first new control point.       */
+  /*                                                                       */
+  /*   cx2 :: The x-coordinate of the arc's second new control point.      */
+  /*                                                                       */
+  /*   cy2 :: The y-coordinate of the arc's second new control point.      */
+  /*                                                                       */
+  /*   x   :: The x-coordinate of the arc's end point (its start point is  */
+  /*          stored in `lastX').                                          */
+  /*                                                                       */
+  /*   y   :: The y-coordinate of the arc's end point (its start point is  */
+  /*          stored in `lastY').                                          */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*   SUCCESS on success, FAILURE on render pool overflow or incorrect    */
+  /*   profile.                                                            */
+  /*                                                                       */
+  static Bool
+  Cubic_To( RAS_ARGS Long  cx1,
+                     Long  cy1,
+                     Long  cx2,
+                     Long  cy2,
+                     Long  x,
+                     Long  y )
+  {
+    Long     y1, y2, y3, y4, x4, ymin1, ymax1, ymin2, ymax2;
+    TStates  state_bez;
+
+
+    ras.arc      = ras.arcs;
+    ras.arc[3].x = ras.lastX;
+    ras.arc[3].y = ras.lastY;
+    ras.arc[2].x = cx1;
+    ras.arc[2].y = cy1;
+    ras.arc[1].x = cx2;
+    ras.arc[1].y = cy2;
+    ras.arc[0].x = x;
+    ras.arc[0].y = y;
+
+    do
+    {
+      y1 = ras.arc[3].y;
+      y2 = ras.arc[2].y;
+      y3 = ras.arc[1].y;
+      y4 = ras.arc[0].y;
+      x4 = ras.arc[0].x;
+
+      /* first, categorize the Bezier arc */
+
+      if ( y1 <= y4 )
+      {
+        ymin1 = y1;
+        ymax1 = y4;
+      }
+      else
+      {
+        ymin1 = y4;
+        ymax1 = y1;
+      }
+
+      if ( y2 <= y3 )
+      {
+        ymin2 = y2;
+        ymax2 = y3;
+      }
+      else
+      {
+        ymin2 = y3;
+        ymax2 = y2;
+      }
+
+      if ( ymin2 < ymin1 || ymax2 > ymax1 )
+      {
+        /* this arc has no given direction, split it! */
+        Split_Cubic( ras.arc );
+        ras.arc += 3;
+      }
+      else if ( y1 == y4 )
+      {
+        /* this arc is flat, ignore it and pop it from the Bezier stack */
+        ras.arc -= 3;
+      }
+      else
+      {
+        state_bez = ( y1 <= y4 ) ? Ascending_State : Descending_State;
+
+        /* detect a change of direction */
+        if ( ras.state != state_bez )
+        {
+          Bool  o = state_bez == Ascending_State ? IS_BOTTOM_OVERSHOOT( y1 )
+                                                 : IS_TOP_OVERSHOOT( y1 );
+
+
+          /* finalize current profile if any */
+          if ( ras.state != Unknown_State &&
+               End_Profile( RAS_VARS o )  )
+            goto Fail;
+
+          if ( New_Profile( RAS_VARS state_bez, o ) )
+            goto Fail;
+        }
+
+        /* compute intersections */
+        if ( state_bez == Ascending_State )
+        {
+          if ( Bezier_Up( RAS_VARS 3, Split_Cubic, ras.minY, ras.maxY ) )
+            goto Fail;
+        }
+        else
+          if ( Bezier_Down( RAS_VARS 3, Split_Cubic, ras.minY, ras.maxY ) )
+            goto Fail;
+      }
+
+    } while ( ras.arc >= ras.arcs );
+
+    ras.lastX = x4;
+    ras.lastY = y4;
+
+    return SUCCESS;
+
+  Fail:
+    return FAILURE;
+  }
+
+
+#undef  SWAP_
+#define SWAP_( x, y )  do                \
+                       {                 \
+                         Long  swap = x; \
+                                         \
+                                         \
+                         x = y;          \
+                         y = swap;       \
+                       } while ( 0 )
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Decompose_Curve                                                    */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Scan the outline arrays in order to emit individual segments and   */
+  /*    Beziers by calling Line_To() and Bezier_To().  It handles all      */
+  /*    weird cases, like when the first point is off the curve, or when   */
+  /*    there are simply no `on' points in the contour!                    */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    first   :: The index of the first point in the contour.            */
+  /*                                                                       */
+  /*    last    :: The index of the last point in the contour.             */
+  /*                                                                       */
+  /*    flipped :: If set, flip the direction of the curve.                */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE on error.                              */
+  /*                                                                       */
+  static Bool
+  Decompose_Curve( RAS_ARGS UShort  first,
+                            UShort  last,
+                            int     flipped )
+  {
+    FT_Vector   v_last;
+    FT_Vector   v_control;
+    FT_Vector   v_start;
+
+    FT_Vector*  points;
+    FT_Vector*  point;
+    FT_Vector*  limit;
+    char*       tags;
+
+    unsigned    tag;       /* current point's state           */
+
+
+    points = ras.outline.points;
+    limit  = points + last;
+
+    v_start.x = SCALED( points[first].x );
+    v_start.y = SCALED( points[first].y );
+    v_last.x  = SCALED( points[last].x );
+    v_last.y  = SCALED( points[last].y );
+
+    if ( flipped )
+    {
+      SWAP_( v_start.x, v_start.y );
+      SWAP_( v_last.x, v_last.y );
+    }
+
+    v_control = v_start;
+
+    point = points + first;
+    tags  = ras.outline.tags + first;
+
+    /* set scan mode if necessary */
+    if ( tags[0] & FT_CURVE_TAG_HAS_SCANMODE )
+      ras.dropOutControl = (Byte)tags[0] >> 5;
+
+    tag = FT_CURVE_TAG( tags[0] );
+
+    /* A contour cannot start with a cubic control point! */
+    if ( tag == FT_CURVE_TAG_CUBIC )
+      goto Invalid_Outline;
+
+    /* check first point to determine origin */
+    if ( tag == FT_CURVE_TAG_CONIC )
+    {
+      /* first point is conic control.  Yes, this happens. */
+      if ( FT_CURVE_TAG( ras.outline.tags[last] ) == FT_CURVE_TAG_ON )
+      {
+        /* start at last point if it is on the curve */
+        v_start = v_last;
+        limit--;
+      }
+      else
+      {
+        /* if both first and last points are conic,         */
+        /* start at their middle and record its position    */
+        /* for closure                                      */
+        v_start.x = ( v_start.x + v_last.x ) / 2;
+        v_start.y = ( v_start.y + v_last.y ) / 2;
+
+        v_last = v_start;
+      }
+      point--;
+      tags--;
+    }
+
+    ras.lastX = v_start.x;
+    ras.lastY = v_start.y;
+
+    while ( point < limit )
+    {
+      point++;
+      tags++;
+
+      tag = FT_CURVE_TAG( tags[0] );
+
+      switch ( tag )
+      {
+      case FT_CURVE_TAG_ON:  /* emit a single line_to */
+        {
+          Long  x, y;
+
+
+          x = SCALED( point->x );
+          y = SCALED( point->y );
+          if ( flipped )
+            SWAP_( x, y );
+
+          if ( Line_To( RAS_VARS x, y ) )
+            goto Fail;
+          continue;
+        }
+
+      case FT_CURVE_TAG_CONIC:  /* consume conic arcs */
+        v_control.x = SCALED( point[0].x );
+        v_control.y = SCALED( point[0].y );
+
+        if ( flipped )
+          SWAP_( v_control.x, v_control.y );
+
+      Do_Conic:
+        if ( point < limit )
+        {
+          FT_Vector  v_middle;
+          Long       x, y;
+
+
+          point++;
+          tags++;
+          tag = FT_CURVE_TAG( tags[0] );
+
+          x = SCALED( point[0].x );
+          y = SCALED( point[0].y );
+
+          if ( flipped )
+            SWAP_( x, y );
+
+          if ( tag == FT_CURVE_TAG_ON )
+          {
+            if ( Conic_To( RAS_VARS v_control.x, v_control.y, x, y ) )
+              goto Fail;
+            continue;
+          }
+
+          if ( tag != FT_CURVE_TAG_CONIC )
+            goto Invalid_Outline;
+
+          v_middle.x = ( v_control.x + x ) / 2;
+          v_middle.y = ( v_control.y + y ) / 2;
+
+          if ( Conic_To( RAS_VARS v_control.x, v_control.y,
+                                  v_middle.x,  v_middle.y ) )
+            goto Fail;
+
+          v_control.x = x;
+          v_control.y = y;
+
+          goto Do_Conic;
+        }
+
+        if ( Conic_To( RAS_VARS v_control.x, v_control.y,
+                                v_start.x,   v_start.y ) )
+          goto Fail;
+
+        goto Close;
+
+      default:  /* FT_CURVE_TAG_CUBIC */
+        {
+          Long  x1, y1, x2, y2, x3, y3;
+
+
+          if ( point + 1 > limit                             ||
+               FT_CURVE_TAG( tags[1] ) != FT_CURVE_TAG_CUBIC )
+            goto Invalid_Outline;
+
+          point += 2;
+          tags  += 2;
+
+          x1 = SCALED( point[-2].x );
+          y1 = SCALED( point[-2].y );
+          x2 = SCALED( point[-1].x );
+          y2 = SCALED( point[-1].y );
+
+          if ( flipped )
+          {
+            SWAP_( x1, y1 );
+            SWAP_( x2, y2 );
+          }
+
+          if ( point <= limit )
+          {
+            x3 = SCALED( point[0].x );
+            y3 = SCALED( point[0].y );
+
+            if ( flipped )
+              SWAP_( x3, y3 );
+
+            if ( Cubic_To( RAS_VARS x1, y1, x2, y2, x3, y3 ) )
+              goto Fail;
+            continue;
+          }
+
+          if ( Cubic_To( RAS_VARS x1, y1, x2, y2, v_start.x, v_start.y ) )
+            goto Fail;
+          goto Close;
+        }
+      }
+    }
+
+    /* close the contour with a line segment */
+    if ( Line_To( RAS_VARS v_start.x, v_start.y ) )
+      goto Fail;
+
+  Close:
+    return SUCCESS;
+
+  Invalid_Outline:
+    ras.error = Raster_Err_Invalid;
+
+  Fail:
+    return FAILURE;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Convert_Glyph                                                      */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Convert a glyph into a series of segments and arcs and make a      */
+  /*    profiles list with them.                                           */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    flipped :: If set, flip the direction of curve.                    */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    SUCCESS on success, FAILURE if any error was encountered during    */
+  /*    rendering.                                                         */
+  /*                                                                       */
+  static Bool
+  Convert_Glyph( RAS_ARGS int  flipped )
+  {
+    int       i;
+    unsigned  start;
+
+    PProfile  lastProfile;
+
+
+    ras.fProfile = NULL;
+    ras.joint    = FALSE;
+    ras.fresh    = FALSE;
+
+    ras.maxBuff  = ras.sizeBuff - AlignProfileSize;
+
+    ras.numTurns = 0;
+
+    ras.cProfile         = (PProfile)ras.top;
+    ras.cProfile->offset = ras.top;
+    ras.num_Profs        = 0;
+
+    start = 0;
+
+    for ( i = 0; i < ras.outline.n_contours; i++ )
+    {
+      Bool  o;
+
+
+      ras.state    = Unknown_State;
+      ras.gProfile = NULL;
+
+      if ( Decompose_Curve( RAS_VARS (unsigned short)start,
+                                     ras.outline.contours[i],
+                                     flipped ) )
+        return FAILURE;
+
+      start = ras.outline.contours[i] + 1;
+
+      /* we must now check whether the extreme arcs join or not */
+      if ( FRAC( ras.lastY ) == 0 &&
+           ras.lastY >= ras.minY  &&
+           ras.lastY <= ras.maxY  )
+        if ( ras.gProfile                        &&
+             ( ras.gProfile->flags & Flow_Up ) ==
+               ( ras.cProfile->flags & Flow_Up ) )
+          ras.top--;
+        /* Note that ras.gProfile can be nil if the contour was too small */
+        /* to be drawn.                                                   */
+
+      lastProfile = ras.cProfile;
+      if ( ras.cProfile->flags & Flow_Up )
+        o = IS_TOP_OVERSHOOT( ras.lastY );
+      else
+        o = IS_BOTTOM_OVERSHOOT( ras.lastY );
+      if ( End_Profile( RAS_VARS o ) )
+        return FAILURE;
+
+      /* close the `next profile in contour' linked list */
+      if ( ras.gProfile )
+        lastProfile->next = ras.gProfile;
+    }
+
+    if ( Finalize_Profile_Table( RAS_VAR ) )
+      return FAILURE;
+
+    return (Bool)( ras.top < ras.maxBuff ? SUCCESS : FAILURE );
+  }
+
+
+  /*************************************************************************/
+  /*************************************************************************/
+  /**                                                                     **/
+  /**  SCAN-LINE SWEEPS AND DRAWING                                       **/
+  /**                                                                     **/
+  /*************************************************************************/
+  /*************************************************************************/
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  Init_Linked                                                          */
+  /*                                                                       */
+  /*    Initializes an empty linked list.                                  */
+  /*                                                                       */
+  static void
+  Init_Linked( TProfileList*  l )
+  {
+    *l = NULL;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  InsNew                                                               */
+  /*                                                                       */
+  /*    Inserts a new profile in a linked list.                            */
+  /*                                                                       */
+  static void
+  InsNew( PProfileList  list,
+          PProfile      profile )
+  {
+    PProfile  *old, current;
+    Long       x;
+
+
+    old     = list;
+    current = *old;
+    x       = profile->X;
+
+    while ( current )
+    {
+      if ( x < current->X )
+        break;
+      old     = &current->link;
+      current = *old;
+    }
+
+    profile->link = current;
+    *old          = profile;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  DelOld                                                               */
+  /*                                                                       */
+  /*    Removes an old profile from a linked list.                         */
+  /*                                                                       */
+  static void
+  DelOld( PProfileList  list,
+          PProfile      profile )
+  {
+    PProfile  *old, current;
+
+
+    old     = list;
+    current = *old;
+
+    while ( current )
+    {
+      if ( current == profile )
+      {
+        *old = current->link;
+        return;
+      }
+
+      old     = &current->link;
+      current = *old;
+    }
+
+    /* we should never get there, unless the profile was not part of */
+    /* the list.                                                     */
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  Sort                                                                 */
+  /*                                                                       */
+  /*    Sorts a trace list.  In 95%, the list is already sorted.  We need  */
+  /*    an algorithm which is fast in this case.  Bubble sort is enough    */
+  /*    and simple.                                                        */
+  /*                                                                       */
+  static void
+  Sort( PProfileList  list )
+  {
+    PProfile  *old, current, next;
+
+
+    /* First, set the new X coordinate of each profile */
+    current = *list;
+    while ( current )
+    {
+      current->X       = *current->offset;
+      current->offset += current->flags & Flow_Up ? 1 : -1;
+      current->height--;
+      current = current->link;
+    }
+
+    /* Then sort them */
+    old     = list;
+    current = *old;
+
+    if ( !current )
+      return;
+
+    next = current->link;
+
+    while ( next )
+    {
+      if ( current->X <= next->X )
+      {
+        old     = &current->link;
+        current = *old;
+
+        if ( !current )
+          return;
+      }
+      else
+      {
+        *old          = next;
+        current->link = next->link;
+        next->link    = current;
+
+        old     = list;
+        current = *old;
+      }
+
+      next = current->link;
+    }
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  Vertical Sweep Procedure Set                                         */
+  /*                                                                       */
+  /*  These four routines are used during the vertical black/white sweep   */
+  /*  phase by the generic Draw_Sweep() function.                          */
+  /*                                                                       */
+  /*************************************************************************/
+
+  static void
+  Vertical_Sweep_Init( RAS_ARGS Short*  min,
+                                Short*  max )
+  {
+    Long  pitch = ras.target.pitch;
+
+    FT_UNUSED( max );
+
+
+    ras.traceIncr = (Short)-pitch;
+    ras.traceOfs  = -*min * pitch;
+    if ( pitch > 0 )
+      ras.traceOfs += ( ras.target.rows - 1 ) * pitch;
+
+    ras.gray_min_x = 0;
+    ras.gray_max_x = 0;
+  }
+
+
+  static void
+  Vertical_Sweep_Span( RAS_ARGS Short       y,
+                                FT_F26Dot6  x1,
+                                FT_F26Dot6  x2,
+                                PProfile    left,
+                                PProfile    right )
+  {
+    Long   e1, e2;
+    int    c1, c2;
+    Byte   f1, f2;
+    Byte*  target;
+
+    FT_UNUSED( y );
+    FT_UNUSED( left );
+    FT_UNUSED( right );
+
+
+    /* Drop-out control */
+
+    e1 = TRUNC( CEILING( x1 ) );
+
+    if ( x2 - x1 - ras.precision <= ras.precision_jitter )
+      e2 = e1;
+    else
+      e2 = TRUNC( FLOOR( x2 ) );
+
+    if ( e2 >= 0 && e1 < ras.bWidth )
+    {
+      if ( e1 < 0 )
+        e1 = 0;
+      if ( e2 >= ras.bWidth )
+        e2 = ras.bWidth - 1;
+
+      c1 = (Short)( e1 >> 3 );
+      c2 = (Short)( e2 >> 3 );
+
+      f1 = (Byte)  ( 0xFF >> ( e1 & 7 ) );
+      f2 = (Byte) ~( 0x7F >> ( e2 & 7 ) );
+
+      if ( ras.gray_min_x > c1 )
+        ras.gray_min_x = (short)c1;
+      if ( ras.gray_max_x < c2 )
+        ras.gray_max_x = (short)c2;
+
+      target = ras.bTarget + ras.traceOfs + c1;
+      c2 -= c1;
+
+      if ( c2 > 0 )
+      {
+        target[0] |= f1;
+
+        /* memset() is slower than the following code on many platforms. */
+        /* This is due to the fact that, in the vast majority of cases,  */
+        /* the span length in bytes is relatively small.                 */
+        c2--;
+        while ( c2 > 0 )
+        {
+          *(++target) = 0xFF;
+          c2--;
+        }
+        target[1] |= f2;
+      }
+      else
+        *target |= ( f1 & f2 );
+    }
+  }
+
+
+  static void
+  Vertical_Sweep_Drop( RAS_ARGS Short       y,
+                                FT_F26Dot6  x1,
+                                FT_F26Dot6  x2,
+                                PProfile    left,
+                                PProfile    right )
+  {
+    Long   e1, e2, pxl;
+    Short  c1, f1;
+
+
+    /* Drop-out control */
+
+    /*   e2            x2                    x1           e1   */
+    /*                                                         */
+    /*                 ^                     |                 */
+    /*                 |                     |                 */
+    /*   +-------------+---------------------+------------+    */
+    /*                 |                     |                 */
+    /*                 |                     v                 */
+    /*                                                         */
+    /* pixel         contour              contour       pixel  */
+    /* center                                           center */
+
+    /* drop-out mode    scan conversion rules (as defined in OpenType) */
+    /* --------------------------------------------------------------- */
+    /*  0                1, 2, 3                                       */
+    /*  1                1, 2, 4                                       */
+    /*  2                1, 2                                          */
+    /*  3                same as mode 2                                */
+    /*  4                1, 2, 5                                       */
+    /*  5                1, 2, 6                                       */
+    /*  6, 7             same as mode 2                                */
+
+    e1  = CEILING( x1 );
+    e2  = FLOOR  ( x2 );
+    pxl = e1;
+
+    if ( e1 > e2 )
+    {
+      Int  dropOutControl = left->flags & 7;
+
+
+      if ( e1 == e2 + ras.precision )
+      {
+        switch ( dropOutControl )
+        {
+        case 0: /* simple drop-outs including stubs */
+          pxl = e2;
+          break;
+
+        case 4: /* smart drop-outs including stubs */
+          pxl = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+          break;
+
+        case 1: /* simple drop-outs excluding stubs */
+        case 5: /* smart drop-outs excluding stubs  */
+
+          /* Drop-out Control Rules #4 and #6 */
+
+          /* The specification neither provides an exact definition */
+          /* of a `stub' nor gives exact rules to exclude them.     */
+          /*                                                        */
+          /* Here the constraints we use to recognize a stub.       */
+          /*                                                        */
+          /*  upper stub:                                           */
+          /*                                                        */
+          /*   - P_Left and P_Right are in the same contour         */
+          /*   - P_Right is the successor of P_Left in that contour */
+          /*   - y is the top of P_Left and P_Right                 */
+          /*                                                        */
+          /*  lower stub:                                           */
+          /*                                                        */
+          /*   - P_Left and P_Right are in the same contour         */
+          /*   - P_Left is the successor of P_Right in that contour */
+          /*   - y is the bottom of P_Left                          */
+          /*                                                        */
+          /* We draw a stub if the following constraints are met.   */
+          /*                                                        */
+          /*   - for an upper or lower stub, there is top or bottom */
+          /*     overshoot, respectively                            */
+          /*   - the covered interval is greater or equal to a half */
+          /*     pixel                                              */
+
+          /* upper stub test */
+          if ( left->next == right                &&
+               left->height <= 0                  &&
+               !( left->flags & Overshoot_Top   &&
+                  x2 - x1 >= ras.precision_half ) )
+            return;
+
+          /* lower stub test */
+          if ( right->next == left                 &&
+               left->start == y                    &&
+               !( left->flags & Overshoot_Bottom &&
+                  x2 - x1 >= ras.precision_half  ) )
+            return;
+
+          if ( dropOutControl == 1 )
+            pxl = e2;
+          else
+            pxl = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+          break;
+
+        default: /* modes 2, 3, 6, 7 */
+          return;  /* no drop-out control */
+        }
+
+        /* undocumented but confirmed: If the drop-out would result in a  */
+        /* pixel outside of the bounding box, use the pixel inside of the */
+        /* bounding box instead                                           */
+        if ( pxl < 0 )
+          pxl = e1;
+        else if ( TRUNC( pxl ) >= ras.bWidth )
+          pxl = e2;
+
+        /* check that the other pixel isn't set */
+        e1 = pxl == e1 ? e2 : e1;
+
+        e1 = TRUNC( e1 );
+
+        c1 = (Short)( e1 >> 3 );
+        f1 = (Short)( e1 &  7 );
+
+        if ( e1 >= 0 && e1 < ras.bWidth                      &&
+             ras.bTarget[ras.traceOfs + c1] & ( 0x80 >> f1 ) )
+          return;
+      }
+      else
+        return;
+    }
+
+    e1 = TRUNC( pxl );
+
+    if ( e1 >= 0 && e1 < ras.bWidth )
+    {
+      c1 = (Short)( e1 >> 3 );
+      f1 = (Short)( e1 & 7 );
+
+      if ( ras.gray_min_x > c1 )
+        ras.gray_min_x = c1;
+      if ( ras.gray_max_x < c1 )
+        ras.gray_max_x = c1;
+
+      ras.bTarget[ras.traceOfs + c1] |= (char)( 0x80 >> f1 );
+    }
+  }
+
+
+  static void
+  Vertical_Sweep_Step( RAS_ARG )
+  {
+    ras.traceOfs += ras.traceIncr;
+  }
+
+
+  /***********************************************************************/
+  /*                                                                     */
+  /*  Horizontal Sweep Procedure Set                                     */
+  /*                                                                     */
+  /*  These four routines are used during the horizontal black/white     */
+  /*  sweep phase by the generic Draw_Sweep() function.                  */
+  /*                                                                     */
+  /***********************************************************************/
+
+  static void
+  Horizontal_Sweep_Init( RAS_ARGS Short*  min,
+                                  Short*  max )
+  {
+    /* nothing, really */
+    FT_UNUSED_RASTER;
+    FT_UNUSED( min );
+    FT_UNUSED( max );
+  }
+
+
+  static void
+  Horizontal_Sweep_Span( RAS_ARGS Short       y,
+                                  FT_F26Dot6  x1,
+                                  FT_F26Dot6  x2,
+                                  PProfile    left,
+                                  PProfile    right )
+  {
+    Long   e1, e2;
+    PByte  bits;
+    Byte   f1;
+
+    FT_UNUSED( left );
+    FT_UNUSED( right );
+
+
+    if ( x2 - x1 < ras.precision )
+    {
+      e1 = CEILING( x1 );
+      e2 = FLOOR  ( x2 );
+
+      if ( e1 == e2 )
+      {
+        bits = ras.bTarget + ( y >> 3 );
+        f1   = (Byte)( 0x80 >> ( y & 7 ) );
+
+        e1 = TRUNC( e1 );
+
+        if ( e1 >= 0 && e1 < ras.target.rows )
+        {
+          PByte  p;
+
+
+          p = bits - e1 * ras.target.pitch;
+          if ( ras.target.pitch > 0 )
+            p += ( ras.target.rows - 1 ) * ras.target.pitch;
+
+          p[0] |= f1;
+        }
+      }
+    }
+  }
+
+
+  static void
+  Horizontal_Sweep_Drop( RAS_ARGS Short       y,
+                                  FT_F26Dot6  x1,
+                                  FT_F26Dot6  x2,
+                                  PProfile    left,
+                                  PProfile    right )
+  {
+    Long   e1, e2, pxl;
+    PByte  bits;
+    Byte   f1;
+
+
+    /* During the horizontal sweep, we only take care of drop-outs */
+
+    /* e1     +       <-- pixel center */
+    /*        |                        */
+    /* x1  ---+-->    <-- contour      */
+    /*        |                        */
+    /*        |                        */
+    /* x2  <--+---    <-- contour      */
+    /*        |                        */
+    /*        |                        */
+    /* e2     +       <-- pixel center */
+
+    e1  = CEILING( x1 );
+    e2  = FLOOR  ( x2 );
+    pxl = e1;
+
+    if ( e1 > e2 )
+    {
+      Int  dropOutControl = left->flags & 7;
+
+
+      if ( e1 == e2 + ras.precision )
+      {
+        switch ( dropOutControl )
+        {
+        case 0: /* simple drop-outs including stubs */
+          pxl = e2;
+          break;
+
+        case 4: /* smart drop-outs including stubs */
+          pxl = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+          break;
+
+        case 1: /* simple drop-outs excluding stubs */
+        case 5: /* smart drop-outs excluding stubs  */
+          /* see Vertical_Sweep_Drop for details */
+
+          /* rightmost stub test */
+          if ( left->next == right                &&
+               left->height <= 0                  &&
+               !( left->flags & Overshoot_Top   &&
+                  x2 - x1 >= ras.precision_half ) )
+            return;
+
+          /* leftmost stub test */
+          if ( right->next == left                 &&
+               left->start == y                    &&
+               !( left->flags & Overshoot_Bottom &&
+                  x2 - x1 >= ras.precision_half  ) )
+            return;
+
+          if ( dropOutControl == 1 )
+            pxl = e2;
+          else
+            pxl = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+          break;
+
+        default: /* modes 2, 3, 6, 7 */
+          return;  /* no drop-out control */
+        }
+
+        /* undocumented but confirmed: If the drop-out would result in a  */
+        /* pixel outside of the bounding box, use the pixel inside of the */
+        /* bounding box instead                                           */
+        if ( pxl < 0 )
+          pxl = e1;
+        else if ( TRUNC( pxl ) >= ras.target.rows )
+          pxl = e2;
+
+        /* check that the other pixel isn't set */
+        e1 = pxl == e1 ? e2 : e1;
+
+        e1 = TRUNC( e1 );
+
+        bits = ras.bTarget + ( y >> 3 );
+        f1   = (Byte)( 0x80 >> ( y & 7 ) );
+
+        bits -= e1 * ras.target.pitch;
+        if ( ras.target.pitch > 0 )
+          bits += ( ras.target.rows - 1 ) * ras.target.pitch;
+
+        if ( e1 >= 0              &&
+             e1 < ras.target.rows &&
+             *bits & f1           )
+          return;
+      }
+      else
+        return;
+    }
+
+    bits = ras.bTarget + ( y >> 3 );
+    f1   = (Byte)( 0x80 >> ( y & 7 ) );
+
+    e1 = TRUNC( pxl );
+
+    if ( e1 >= 0 && e1 < ras.target.rows )
+    {
+      bits -= e1 * ras.target.pitch;
+      if ( ras.target.pitch > 0 )
+        bits += ( ras.target.rows - 1 ) * ras.target.pitch;
+
+      bits[0] |= f1;
+    }
+  }
+
+
+  static void
+  Horizontal_Sweep_Step( RAS_ARG )
+  {
+    /* Nothing, really */
+    FT_UNUSED_RASTER;
+  }
+
+
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  Vertical Gray Sweep Procedure Set                                    */
+  /*                                                                       */
+  /*  These two routines are used during the vertical gray-levels sweep    */
+  /*  phase by the generic Draw_Sweep() function.                          */
+  /*                                                                       */
+  /*  NOTES                                                                */
+  /*                                                                       */
+  /*  - The target pixmap's width *must* be a multiple of 4.               */
+  /*                                                                       */
+  /*  - You have to use the function Vertical_Sweep_Span() for the gray    */
+  /*    span call.                                                         */
+  /*                                                                       */
+  /*************************************************************************/
+
+  static void
+  Vertical_Gray_Sweep_Init( RAS_ARGS Short*  min,
+                                     Short*  max )
+  {
+    Long  pitch, byte_len;
+
+
+    *min = *min & -2;
+    *max = ( *max + 3 ) & -2;
+
+    ras.traceOfs  = 0;
+    pitch         = ras.target.pitch;
+    byte_len      = -pitch;
+    ras.traceIncr = (Short)byte_len;
+    ras.traceG    = ( *min / 2 ) * byte_len;
+
+    if ( pitch > 0 )
+    {
+      ras.traceG += ( ras.target.rows - 1 ) * pitch;
+      byte_len    = -byte_len;
+    }
+
+    ras.gray_min_x =  (Short)byte_len;
+    ras.gray_max_x = -(Short)byte_len;
+  }
+
+
+  static void
+  Vertical_Gray_Sweep_Step( RAS_ARG )
+  {
+    Int     c1, c2;
+    PByte   pix, bit, bit2;
+    short*  count = (short*)count_table;
+    Byte*   grays;
+
+
+    ras.traceOfs += ras.gray_width;
+
+    if ( ras.traceOfs > ras.gray_width )
+    {
+      pix   = ras.gTarget + ras.traceG + ras.gray_min_x * 4;
+      grays = ras.grays;
+
+      if ( ras.gray_max_x >= 0 )
+      {
+        Long  last_pixel = ras.target.width - 1;
+        Int   last_cell  = last_pixel >> 2;
+        Int   last_bit   = last_pixel & 3;
+        Bool  over       = 0;
+
+
+        if ( ras.gray_max_x >= last_cell && last_bit != 3 )
+        {
+          ras.gray_max_x = last_cell - 1;
+          over = 1;
+        }
+
+        if ( ras.gray_min_x < 0 )
+          ras.gray_min_x = 0;
+
+        bit  = ras.bTarget + ras.gray_min_x;
+        bit2 = bit + ras.gray_width;
+
+        c1 = ras.gray_max_x - ras.gray_min_x;
+
+        while ( c1 >= 0 )
+        {
+          c2 = count[*bit] + count[*bit2];
+
+          if ( c2 )
+          {
+            pix[0] = grays[(c2 >> 12) & 0x000F];
+            pix[1] = grays[(c2 >> 8 ) & 0x000F];
+            pix[2] = grays[(c2 >> 4 ) & 0x000F];
+            pix[3] = grays[ c2        & 0x000F];
+
+            *bit  = 0;
+            *bit2 = 0;
+          }
+
+          bit++;
+          bit2++;
+          pix += 4;
+          c1--;
+        }
+
+        if ( over )
+        {
+          c2 = count[*bit] + count[*bit2];
+          if ( c2 )
+          {
+            switch ( last_bit )
+            {
+            case 2:
+              pix[2] = grays[(c2 >> 4 ) & 0x000F];
+            case 1:
+              pix[1] = grays[(c2 >> 8 ) & 0x000F];
+            default:
+              pix[0] = grays[(c2 >> 12) & 0x000F];
+            }
+
+            *bit  = 0;
+            *bit2 = 0;
+          }
+        }
+      }
+
+      ras.traceOfs = 0;
+      ras.traceG  += ras.traceIncr;
+
+      ras.gray_min_x =  32000;
+      ras.gray_max_x = -32000;
+    }
+  }
+
+
+  static void
+  Horizontal_Gray_Sweep_Span( RAS_ARGS Short       y,
+                                       FT_F26Dot6  x1,
+                                       FT_F26Dot6  x2,
+                                       PProfile    left,
+                                       PProfile    right )
+  {
+    /* nothing, really */
+    FT_UNUSED_RASTER;
+    FT_UNUSED( y );
+    FT_UNUSED( x1 );
+    FT_UNUSED( x2 );
+    FT_UNUSED( left );
+    FT_UNUSED( right );
+  }
+
+
+  static void
+  Horizontal_Gray_Sweep_Drop( RAS_ARGS Short       y,
+                                       FT_F26Dot6  x1,
+                                       FT_F26Dot6  x2,
+                                       PProfile    left,
+                                       PProfile    right )
+  {
+    Long   e1, e2;
+    PByte  pixel;
+    Byte   color;
+
+
+    /* During the horizontal sweep, we only take care of drop-outs */
+
+    e1 = CEILING( x1 );
+    e2 = FLOOR  ( x2 );
+
+    if ( e1 > e2 )
+    {
+      Int  dropOutControl = left->flags & 7;
+
+
+      if ( e1 == e2 + ras.precision )
+      {
+        switch ( dropOutControl )
+        {
+        case 0: /* simple drop-outs including stubs */
+          e1 = e2;
+          break;
+
+        case 4: /* smart drop-outs including stubs */
+          e1 = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+          break;
+
+        case 1: /* simple drop-outs excluding stubs */
+        case 5: /* smart drop-outs excluding stubs  */
+          /* see Vertical_Sweep_Drop for details */
+
+          /* rightmost stub test */
+          if ( left->next == right && left->height <= 0 )
+            return;
+
+          /* leftmost stub test */
+          if ( right->next == left && left->start == y )
+            return;
+
+          if ( dropOutControl == 1 )
+            e1 = e2;
+          else
+            e1 = FLOOR( ( x1 + x2 - 1 ) / 2 + ras.precision_half );
+
+          break;
+
+        default: /* modes 2, 3, 6, 7 */
+          return;  /* no drop-out control */
+        }
+      }
+      else
+        return;
+    }
+
+    if ( e1 >= 0 )
+    {
+      if ( x2 - x1 >= ras.precision_half )
+        color = ras.grays[2];
+      else
+        color = ras.grays[1];
+
+      e1 = TRUNC( e1 ) / 2;
+      if ( e1 < ras.target.rows )
+      {
+        pixel = ras.gTarget - e1 * ras.target.pitch + y / 2;
+        if ( ras.target.pitch > 0 )
+          pixel += ( ras.target.rows - 1 ) * ras.target.pitch;
+
+        if ( pixel[0] == ras.grays[0] )
+          pixel[0] = color;
+      }
+    }
+  }
+
+
+#endif /* FT_RASTER_OPTION_ANTI_ALIASING */
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /*  Generic Sweep Drawing routine                                        */
+  /*                                                                       */
+  /*************************************************************************/
+
+  static Bool
+  Draw_Sweep( RAS_ARG )
+  {
+    Short         y, y_change, y_height;
+
+    PProfile      P, Q, P_Left, P_Right;
+
+    Short         min_Y, max_Y, top, bottom, dropouts;
+
+    Long          x1, x2, xs, e1, e2;
+
+    TProfileList  waiting;
+    TProfileList  draw_left, draw_right;
+
+
+    /* initialize empty linked lists */
+
+    Init_Linked( &waiting );
+
+    Init_Linked( &draw_left  );
+    Init_Linked( &draw_right );
+
+    /* first, compute min and max Y */
+
+    P     = ras.fProfile;
+    max_Y = (Short)TRUNC( ras.minY );
+    min_Y = (Short)TRUNC( ras.maxY );
+
+    while ( P )
+    {
+      Q = P->link;
+
+      bottom = (Short)P->start;
+      top    = (Short)( P->start + P->height - 1 );
+
+      if ( min_Y > bottom )
+        min_Y = bottom;
+      if ( max_Y < top )
+        max_Y = top;
+
+      P->X = 0;
+      InsNew( &waiting, P );
+
+      P = Q;
+    }
+
+    /* check the Y-turns */
+    if ( ras.numTurns == 0 )
+    {
+      ras.error = Raster_Err_Invalid;
+      return FAILURE;
+    }
+
+    /* now initialize the sweep */
+
+    ras.Proc_Sweep_Init( RAS_VARS &min_Y, &max_Y );
+
+    /* then compute the distance of each profile from min_Y */
+
+    P = waiting;
+
+    while ( P )
+    {
+      P->countL = (UShort)( P->start - min_Y );
+      P = P->link;
+    }
+
+    /* let's go */
+
+    y        = min_Y;
+    y_height = 0;
+
+    if ( ras.numTurns > 0                     &&
+         ras.sizeBuff[-ras.numTurns] == min_Y )
+      ras.numTurns--;
+
+    while ( ras.numTurns > 0 )
+    {
+      /* check waiting list for new activations */
+
+      P = waiting;
+
+      while ( P )
+      {
+        Q = P->link;
+        P->countL -= y_height;
+        if ( P->countL == 0 )
+        {
+          DelOld( &waiting, P );
+
+          if ( P->flags & Flow_Up )
+            InsNew( &draw_left,  P );
+          else
+            InsNew( &draw_right, P );
+        }
+
+        P = Q;
+      }
+
+      /* sort the drawing lists */
+
+      Sort( &draw_left );
+      Sort( &draw_right );
+
+      y_change = (Short)ras.sizeBuff[-ras.numTurns--];
+      y_height = (Short)( y_change - y );
+
+      while ( y < y_change )
+      {
+        /* let's trace */
+
+        dropouts = 0;
+
+        P_Left  = draw_left;
+        P_Right = draw_right;
+
+        while ( P_Left )
+        {
+          x1 = P_Left ->X;
+          x2 = P_Right->X;
+
+          if ( x1 > x2 )
+          {
+            xs = x1;
+            x1 = x2;
+            x2 = xs;
+          }
+
+          e1 = FLOOR( x1 );
+          e2 = CEILING( x2 );
+
+          if ( x2 - x1 <= ras.precision &&
+               e1 != x1 && e2 != x2     )
+          {
+            if ( e1 > e2 || e2 == e1 + ras.precision )
+            {
+              Int  dropOutControl = P_Left->flags & 7;
+
+
+              if ( dropOutControl != 2 )
+              {
+                /* a drop-out was detected */
+
+                P_Left ->X = x1;
+                P_Right->X = x2;
+
+                /* mark profile for drop-out processing */
+                P_Left->countL = 1;
+                dropouts++;
+              }
+
+              goto Skip_To_Next;
+            }
+          }
+
+          ras.Proc_Sweep_Span( RAS_VARS y, x1, x2, P_Left, P_Right );
+
+        Skip_To_Next:
+
+          P_Left  = P_Left->link;
+          P_Right = P_Right->link;
+        }
+
+        /* handle drop-outs _after_ the span drawing --       */
+        /* drop-out processing has been moved out of the loop */
+        /* for performance tuning                             */
+        if ( dropouts > 0 )
+          goto Scan_DropOuts;
+
+      Next_Line:
+
+        ras.Proc_Sweep_Step( RAS_VAR );
+
+        y++;
+
+        if ( y < y_change )
+        {
+          Sort( &draw_left  );
+          Sort( &draw_right );
+        }
+      }
+
+      /* now finalize the profiles that need it */
+
+      P = draw_left;
+      while ( P )
+      {
+        Q = P->link;
+        if ( P->height == 0 )
+          DelOld( &draw_left, P );
+        P = Q;
+      }
+
+      P = draw_right;
+      while ( P )
+      {
+        Q = P->link;
+        if ( P->height == 0 )
+          DelOld( &draw_right, P );
+        P = Q;
+      }
+    }
+
+    /* for gray-scaling, flush the bitmap scanline cache */
+    while ( y <= max_Y )
+    {
+      ras.Proc_Sweep_Step( RAS_VAR );
+      y++;
+    }
+
+    return SUCCESS;
+
+  Scan_DropOuts:
+
+    P_Left  = draw_left;
+    P_Right = draw_right;
+
+    while ( P_Left )
+    {
+      if ( P_Left->countL )
+      {
+        P_Left->countL = 0;
+#if 0
+        dropouts--;  /* -- this is useful when debugging only */
+#endif
+        ras.Proc_Sweep_Drop( RAS_VARS y,
+                                      P_Left->X,
+                                      P_Right->X,
+                                      P_Left,
+                                      P_Right );
+      }
+
+      P_Left  = P_Left->link;
+      P_Right = P_Right->link;
+    }
+
+    goto Next_Line;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Render_Single_Pass                                                 */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Perform one sweep with sub-banding.                                */
+  /*                                                                       */
+  /* <Input>                                                               */
+  /*    flipped :: If set, flip the direction of the outline.              */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    Renderer error code.                                               */
+  /*                                                                       */
+  static int
+  Render_Single_Pass( RAS_ARGS Bool  flipped )
+  {
+    Short  i, j, k;
+
+
+    while ( ras.band_top >= 0 )
+    {
+      ras.maxY = (Long)ras.band_stack[ras.band_top].y_max * ras.precision;
+      ras.minY = (Long)ras.band_stack[ras.band_top].y_min * ras.precision;
+
+      ras.top = ras.buff;
+
+      ras.error = Raster_Err_None;
+
+      if ( Convert_Glyph( RAS_VARS flipped ) )
+      {
+        if ( ras.error != Raster_Err_Overflow )
+          return FAILURE;
+
+        ras.error = Raster_Err_None;
+
+        /* sub-banding */
+
+#ifdef DEBUG_RASTER
+        ClearBand( RAS_VARS TRUNC( ras.minY ), TRUNC( ras.maxY ) );
+#endif
+
+        i = ras.band_stack[ras.band_top].y_min;
+        j = ras.band_stack[ras.band_top].y_max;
+
+        k = (Short)( ( i + j ) / 2 );
+
+        if ( ras.band_top >= 7 || k < i )
+        {
+          ras.band_top = 0;
+          ras.error    = Raster_Err_Invalid;
+
+          return ras.error;
+        }
+
+        ras.band_stack[ras.band_top + 1].y_min = k;
+        ras.band_stack[ras.band_top + 1].y_max = j;
+
+        ras.band_stack[ras.band_top].y_max = (Short)( k - 1 );
+
+        ras.band_top++;
+      }
+      else
+      {
+        if ( ras.fProfile )
+          if ( Draw_Sweep( RAS_VAR ) )
+             return ras.error;
+        ras.band_top--;
+      }
+    }
+
+    return SUCCESS;
+  }
+
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Render_Glyph                                                       */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Render a glyph in a bitmap.  Sub-banding if needed.                */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    FreeType error code.  0 means success.                             */
+  /*                                                                       */
+  FT_LOCAL_DEF( FT_Error )
+  Render_Glyph( RAS_ARG )
+  {
+    FT_Error  error;
+
+
+    Set_High_Precision( RAS_VARS ras.outline.flags &
+                                 FT_OUTLINE_HIGH_PRECISION );
+    ras.scale_shift = ras.precision_shift;
+
+    if ( ras.outline.flags & FT_OUTLINE_IGNORE_DROPOUTS )
+      ras.dropOutControl = 2;
+    else
+    {
+      if ( ras.outline.flags & FT_OUTLINE_SMART_DROPOUTS )
+        ras.dropOutControl = 4;
+      else
+        ras.dropOutControl = 0;
+
+      if ( !( ras.outline.flags & FT_OUTLINE_INCLUDE_STUBS ) )
+        ras.dropOutControl += 1;
+    }
+
+    ras.second_pass = (FT_Byte)( !( ras.outline.flags &
+                                    FT_OUTLINE_SINGLE_PASS ) );
+
+    /* Vertical Sweep */
+    ras.Proc_Sweep_Init = Vertical_Sweep_Init;
+    ras.Proc_Sweep_Span = Vertical_Sweep_Span;
+    ras.Proc_Sweep_Drop = Vertical_Sweep_Drop;
+    ras.Proc_Sweep_Step = Vertical_Sweep_Step;
+
+    ras.band_top            = 0;
+    ras.band_stack[0].y_min = 0;
+    ras.band_stack[0].y_max = (short)( ras.target.rows - 1 );
+
+    ras.bWidth  = (unsigned short)ras.target.width;
+    ras.bTarget = (Byte*)ras.target.buffer;
+
+    if ( ( error = Render_Single_Pass( RAS_VARS 0 ) ) != 0 )
+      return error;
+
+    /* Horizontal Sweep */
+    if ( ras.second_pass && ras.dropOutControl != 2 )
+    {
+      ras.Proc_Sweep_Init = Horizontal_Sweep_Init;
+      ras.Proc_Sweep_Span = Horizontal_Sweep_Span;
+      ras.Proc_Sweep_Drop = Horizontal_Sweep_Drop;
+      ras.Proc_Sweep_Step = Horizontal_Sweep_Step;
+
+      ras.band_top            = 0;
+      ras.band_stack[0].y_min = 0;
+      ras.band_stack[0].y_max = (short)( ras.target.width - 1 );
+
+      if ( ( error = Render_Single_Pass( RAS_VARS 1 ) ) != 0 )
+        return error;
+    }
+
+    return Raster_Err_None;
+  }
+
+
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+
+  /*************************************************************************/
+  /*                                                                       */
+  /* <Function>                                                            */
+  /*    Render_Gray_Glyph                                                  */
+  /*                                                                       */
+  /* <Description>                                                         */
+  /*    Render a glyph with grayscaling.  Sub-banding if needed.           */
+  /*                                                                       */
+  /* <Return>                                                              */
+  /*    FreeType error code.  0 means success.                             */
+  /*                                                                       */
+  FT_LOCAL_DEF( FT_Error )
+  Render_Gray_Glyph( RAS_ARG )
+  {
+    Long      pixel_width;
+    FT_Error  error;
+
+
+    Set_High_Precision( RAS_VARS ras.outline.flags &
+                                 FT_OUTLINE_HIGH_PRECISION );
+    ras.scale_shift = ras.precision_shift + 1;
+
+    if ( ras.outline.flags & FT_OUTLINE_IGNORE_DROPOUTS )
+      ras.dropOutControl = 2;
+    else
+    {
+      if ( ras.outline.flags & FT_OUTLINE_SMART_DROPOUTS )
+        ras.dropOutControl = 4;
+      else
+        ras.dropOutControl = 0;
+
+      if ( !( ras.outline.flags & FT_OUTLINE_INCLUDE_STUBS ) )
+        ras.dropOutControl += 1;
+    }
+
+    ras.second_pass = !( ras.outline.flags & FT_OUTLINE_SINGLE_PASS );
+
+    /* Vertical Sweep */
+
+    ras.band_top            = 0;
+    ras.band_stack[0].y_min = 0;
+    ras.band_stack[0].y_max = 2 * ras.target.rows - 1;
+
+    ras.bWidth  = ras.gray_width;
+    pixel_width = 2 * ( ( ras.target.width + 3 ) >> 2 );
+
+    if ( ras.bWidth > pixel_width )
+      ras.bWidth = pixel_width;
+
+    ras.bWidth  = ras.bWidth * 8;
+    ras.bTarget = (Byte*)ras.gray_lines;
+    ras.gTarget = (Byte*)ras.target.buffer;
+
+    ras.Proc_Sweep_Init = Vertical_Gray_Sweep_Init;
+    ras.Proc_Sweep_Span = Vertical_Sweep_Span;
+    ras.Proc_Sweep_Drop = Vertical_Sweep_Drop;
+    ras.Proc_Sweep_Step = Vertical_Gray_Sweep_Step;
+
+    error = Render_Single_Pass( RAS_VARS 0 );
+    if ( error )
+      return error;
+
+    /* Horizontal Sweep */
+    if ( ras.second_pass && ras.dropOutControl != 2 )
+    {
+      ras.Proc_Sweep_Init = Horizontal_Sweep_Init;
+      ras.Proc_Sweep_Span = Horizontal_Gray_Sweep_Span;
+      ras.Proc_Sweep_Drop = Horizontal_Gray_Sweep_Drop;
+      ras.Proc_Sweep_Step = Horizontal_Sweep_Step;
+
+      ras.band_top            = 0;
+      ras.band_stack[0].y_min = 0;
+      ras.band_stack[0].y_max = ras.target.width * 2 - 1;
+
+      error = Render_Single_Pass( RAS_VARS 1 );
+      if ( error )
+        return error;
+    }
+
+    return Raster_Err_None;
+  }
+
+#else /* !FT_RASTER_OPTION_ANTI_ALIASING */
+
+  FT_LOCAL_DEF( FT_Error )
+  Render_Gray_Glyph( RAS_ARG )
+  {
+    FT_UNUSED_RASTER;
+
+    return Raster_Err_Unsupported;
+  }
+
+#endif /* !FT_RASTER_OPTION_ANTI_ALIASING */
+
+
+  static void
+  ft_black_init( PRaster  raster )
+  {
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+    FT_UInt  n;
+
+
+    /* set default 5-levels gray palette */
+    for ( n = 0; n < 5; n++ )
+      raster->grays[n] = n * 255 / 4;
+
+    raster->gray_width = RASTER_GRAY_LINES / 2;
+#else
+    FT_UNUSED( raster );
+#endif
+  }
+
+
+  /**** RASTER OBJECT CREATION: In standalone mode, we simply use *****/
+  /****                         a static object.                  *****/
+
+
+#ifdef _STANDALONE_
+
+
+  static int
+  ft_black_new( void*       memory,
+                FT_Raster  *araster )
+  {
+     static TRaster  the_raster;
+     FT_UNUSED( memory );
+
+
+     *araster = (FT_Raster)&the_raster;
+     FT_MEM_ZERO( &the_raster, sizeof ( the_raster ) );
+     ft_black_init( &the_raster );
+
+     return 0;
+  }
+
+
+  static void
+  ft_black_done( FT_Raster  raster )
+  {
+    /* nothing */
+    FT_UNUSED( raster );
+  }
+
+
+#else /* !_STANDALONE_ */
+
+
+  static int
+  ft_black_new( FT_Memory   memory,
+                PRaster    *araster )
+  {
+    FT_Error  error;
+    PRaster   raster = NULL;
+
+
+    *araster = 0;
+    if ( !FT_NEW( raster ) )
+    {
+      raster->memory = memory;
+      ft_black_init( raster );
+
+      *araster = raster;
+    }
+
+    return error;
+  }
+
+
+  static void
+  ft_black_done( PRaster  raster )
+  {
+    FT_Memory  memory = (FT_Memory)raster->memory;
+    FT_FREE( raster );
+  }
+
+
+#endif /* !_STANDALONE_ */
+
+
+  static void
+  ft_black_reset( PRaster  raster,
+                  char*    pool_base,
+                  long     pool_size )
+  {
+    if ( raster )
+    {
+      if ( pool_base && pool_size >= (long)sizeof(TWorker) + 2048 )
+      {
+        PWorker  worker = (PWorker)pool_base;
+
+
+        raster->buffer      = pool_base + ( ( sizeof ( *worker ) + 7 ) & ~7 );
+        raster->buffer_size = pool_base + pool_size - (char*)raster->buffer;
+        raster->worker      = worker;
+      }
+      else
+      {
+        raster->buffer      = NULL;
+        raster->buffer_size = 0;
+        raster->worker      = NULL;
+      }
+    }
+  }
+
+
+  static void
+  ft_black_set_mode( PRaster        raster,
+                     unsigned long  mode,
+                     const char*    palette )
+  {
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+
+    if ( mode == FT_MAKE_TAG( 'p', 'a', 'l', '5' ) )
+    {
+      /* set 5-levels gray palette */
+      raster->grays[0] = palette[0];
+      raster->grays[1] = palette[1];
+      raster->grays[2] = palette[2];
+      raster->grays[3] = palette[3];
+      raster->grays[4] = palette[4];
+    }
+
+#else
+
+    FT_UNUSED( raster );
+    FT_UNUSED( mode );
+    FT_UNUSED( palette );
+
+#endif
+  }
+
+
+  static int
+  ft_black_render( PRaster                  raster,
+                   const FT_Raster_Params*  params )
+  {
+    const FT_Outline*  outline    = (const FT_Outline*)params->source;
+    const FT_Bitmap*   target_map = params->target;
+    PWorker            worker;
+
+
+    if ( !raster || !raster->buffer || !raster->buffer_size )
+      return Raster_Err_Not_Ini;
+
+    if ( !outline )
+      return Raster_Err_Invalid;
+
+    /* return immediately if the outline is empty */
+    if ( outline->n_points == 0 || outline->n_contours <= 0 )
+      return Raster_Err_None;
+
+    if ( !outline->contours || !outline->points )
+      return Raster_Err_Invalid;
+
+    if ( outline->n_points !=
+           outline->contours[outline->n_contours - 1] + 1 )
+      return Raster_Err_Invalid;
+
+    worker = raster->worker;
+
+    /* this version of the raster does not support direct rendering, sorry */
+    if ( params->flags & FT_RASTER_FLAG_DIRECT )
+      return Raster_Err_Unsupported;
+
+    if ( !target_map )
+      return Raster_Err_Invalid;
+
+    /* nothing to do */
+    if ( !target_map->width || !target_map->rows )
+      return Raster_Err_None;
+
+    if ( !target_map->buffer )
+      return Raster_Err_Invalid;
+
+    ras.outline = *outline;
+    ras.target  = *target_map;
+
+    worker->buff       = (PLong) raster->buffer;
+    worker->sizeBuff   = worker->buff +
+                           raster->buffer_size / sizeof ( Long );
+#ifdef FT_RASTER_OPTION_ANTI_ALIASING
+    worker->grays      = raster->grays;
+    worker->gray_width = raster->gray_width;
+
+    FT_MEM_ZERO( worker->gray_lines, worker->gray_width * 2 );
+#endif
+
+    return ( params->flags & FT_RASTER_FLAG_AA )
+           ? Render_Gray_Glyph( RAS_VAR )
+           : Render_Glyph( RAS_VAR );
+  }
+
+
+  FT_DEFINE_RASTER_FUNCS( ft_standard_raster,
+    FT_GLYPH_FORMAT_OUTLINE,
+    (FT_Raster_New_Func)     ft_black_new,
+    (FT_Raster_Reset_Func)   ft_black_reset,
+    (FT_Raster_Set_Mode_Func)ft_black_set_mode,
+    (FT_Raster_Render_Func)  ft_black_render,
+    (FT_Raster_Done_Func)    ft_black_done
+  )
+
+
+/* END */