//----------------------------------------------------------------------------
// FreeType2 pascal header
//----------------------------------------------------------------------------
// Anti-Grain Geometry - Version 2.4 (Public License)
// Copyright (C) 2002-2005 Maxim Shemanarev (http://www.antigrain.com)
//
// Anti-Grain Geometry - Version 2.4 Release Milano 3 (AggPas 2.4 RM3)
// Pascal Port By: Milan Marusinec alias Milano
// milan@marusinec.sk
// http://www.aggpas.org
// Copyright (c) 2005-2007
//
// Permission to copy, use, modify, sell and distribute this software
// is granted provided this copyright notice appears in all copies.
// This software is provided "as is" without express or implied
// warranty, and with no claim as to its suitability for any purpose.
//
//----------------------------------------------------------------------------
// Adapted by the UltraStar Deluxe Team
//----------------------------------------------------------------------------
unit freetype;
interface
{$IFDEF FPC}
{$MODE DELPHI }
{$PACKENUM 4} (* use 4-byte enums *)
{$PACKRECORDS C} (* C/C++-compatible record packing *)
{$ELSE}
{$MINENUMSIZE 4} (* use 4-byte enums *)
{$ENDIF}
uses
ctypes;
const
{$IF Defined(MSWINDOWS)}
ft_lib = 'libfreetype-6.dll';
{$ELSEIF Defined(DARWIN)}
ft_lib = 'libfreetype.dylib';
{$LINKLIB libfreetype}
{$ELSEIF Defined(UNIX)}
ft_lib = 'freetype.so';
{$IFEND}
type
FT_Byte = cuchar;
FT_Short = csshort;
FT_UShort = cushort;
FT_Int = csint;
FT_UInt = cuint;
FT_Int16 = cint16;
FT_UInt16 = cuint16;
FT_Int32 = cint32;
FT_UInt32 = cuint32;
FT_Long = cslong;
FT_ULong = culong;
FT_Fixed = cslong;
FT_Pos = cslong;
FT_Error = cint;
FT_F26Dot6 = cslong;
FT_String = cchar;
FT_Bool = cuchar;
PFT_Byte = ^FT_Byte;
PFT_Short = ^FT_Short;
PFT_String = ^FT_String;
TByteArray = array [0 .. (MaxInt div SizeOf(byte))-1] of byte;
PByteArray = ^TByteArray;
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_FACE_FLAG_XXX *)
(* *)
(* <Description> *)
(* A list of bit flags used in the `face_flags' field of the *)
(* @FT_FaceRec structure. They inform client applications of *)
(* properties of the corresponding face. *)
(* *)
(* <Values> *)
(* FT_FACE_FLAG_SCALABLE :: *)
(* Indicates that the face provides vectorial outlines. This *)
(* doesn't prevent embedded bitmaps, i.e., a face can have both *)
(* this bit and @FT_FACE_FLAG_FIXED_SIZES set. *)
(* *)
(* FT_FACE_FLAG_FIXED_SIZES :: *)
(* Indicates that the face contains `fixed sizes', i.e., bitmap *)
(* strikes for some given pixel sizes. See the `num_fixed_sizes' *)
(* and `available_sizes' fields of @FT_FaceRec. *)
(* *)
(* FT_FACE_FLAG_FIXED_WIDTH :: *)
(* Indicates that the face contains fixed-width characters (like *)
(* Courier, Lucido, MonoType, etc.). *)
(* *)
(* FT_FACE_FLAG_SFNT :: *)
(* Indicates that the face uses the `sfnt' storage scheme. For *)
(* now, this means TrueType and OpenType. *)
(* *)
(* FT_FACE_FLAG_HORIZONTAL :: *)
(* Indicates that the face contains horizontal glyph metrics. This *)
(* should be set for all common formats. *)
(* *)
(* FT_FACE_FLAG_VERTICAL :: *)
(* Indicates that the face contains vertical glyph metrics. This *)
(* is only available in some formats, not all of them. *)
(* *)
(* FT_FACE_FLAG_KERNING :: *)
(* Indicates that the face contains kerning information. If set, *)
(* the kerning distance can be retrieved through the function *)
(* @FT_Get_Kerning. Note that if unset, this function will always *)
(* return the vector (0,0). *)
(* *)
(* FT_FACE_FLAG_FAST_GLYPHS :: *)
(* THIS FLAG IS DEPRECATED. DO NOT USE OR TEST IT. *)
(* *)
(* FT_FACE_FLAG_MULTIPLE_MASTERS :: *)
(* Indicates that the font contains multiple masters and is capable *)
(* of interpolating between them. See the multiple-masters *)
(* specific API for details. *)
(* *)
(* FT_FACE_FLAG_GLYPH_NAMES :: *)
(* Indicates that the font contains glyph names that can be *)
(* retrieved through @FT_Get_Glyph_Name. Note that some TrueType *)
(* fonts contain broken glyph name tables. Use the function *)
(* @FT_Has_PS_Glyph_Names when needed. *)
(* *)
(* FT_FACE_FLAG_EXTERNAL_STREAM :: *)
(* Used internally by FreeType to indicate that a face's stream was *)
(* provided by the client application and should not be destroyed *)
(* when @FT_Done_Face is called. Don't read or test this flag. *)
(* *)
const
FT_FACE_FLAG_SCALABLE = 1 shl 0;
FT_FACE_FLAG_KERNING = 1 shl 6;
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Encoding *)
(* *)
(* <Description> *)
(* An enumeration used to specify encodings supported by charmaps. *)
(* Used in the @FT_Select_Charmap API function. *)
(* *)
(* <Note> *)
(* Because of 32-bit charcodes defined in Unicode (i.e., surrogates), *)
(* all character codes must be expressed as FT_Longs. *)
(* *)
(* The values of this type correspond to specific character *)
(* repertories (i.e. charsets), and not to text encoding methods *)
(* (like UTF-8, UTF-16, GB2312_EUC, etc.). *)
(* *)
(* Other encodings might be defined in the future. *)
(* *)
(* <Values> *)
(* FT_ENCODING_NONE :: *)
(* The encoding value 0 is reserved. *)
(* *)
(* FT_ENCODING_UNICODE :: *)
(* Corresponds to the Unicode character set. This value covers *)
(* all versions of the Unicode repertoire, including ASCII and *)
(* Latin-1. Most fonts include a Unicode charmap, but not all *)
(* of them. *)
(* *)
(* FT_ENCODING_MS_SYMBOL :: *)
(* Corresponds to the Microsoft Symbol encoding, used to encode *)
(* mathematical symbols in the 32..255 character code range. For *)
(* more information, see `http://www.ceviz.net/symbol.htm'. *)
(* *)
(* FT_ENCODING_SJIS :: *)
(* Corresponds to Japanese SJIS encoding. More info at *)
(* at `http://langsupport.japanreference.com/encoding.shtml'. *)
(* See note on multi-byte encodings below. *)
(* *)
(* FT_ENCODING_GB2312 :: *)
(* Corresponds to an encoding system for Simplified Chinese as used *)
(* used in mainland China. *)
(* *)
(* FT_ENCODING_BIG5 :: *)
(* Corresponds to an encoding system for Traditional Chinese as used *)
(* in Taiwan and Hong Kong. *)
(* *)
(* FT_ENCODING_WANSUNG :: *)
(* Corresponds to the Korean encoding system known as Wansung. *)
(* For more information see *)
(* `http://www.microsoft.com/typography/unicode/949.txt'. *)
(* *)
(* FT_ENCODING_JOHAB :: *)
(* The Korean standard character set (KS C-5601-1992), which *)
(* corresponds to MS Windows code page 1361. This character set *)
(* includes all possible Hangeul character combinations. *)
(* *)
(* FT_ENCODING_ADOBE_LATIN_1 :: *)
(* Corresponds to a Latin-1 encoding as defined in a Type 1 *)
(* Postscript font. It is limited to 256 character codes. *)
(* *)
(* FT_ENCODING_ADOBE_STANDARD :: *)
(* Corresponds to the Adobe Standard encoding, as found in Type 1, *)
(* CFF, and OpenType/CFF fonts. It is limited to 256 character *)
(* codes. *)
(* *)
(* FT_ENCODING_ADOBE_EXPERT :: *)
(* Corresponds to the Adobe Expert encoding, as found in Type 1, *)
(* CFF, and OpenType/CFF fonts. It is limited to 256 character *)
(* codes. *)
(* *)
(* FT_ENCODING_ADOBE_CUSTOM :: *)
(* Corresponds to a custom encoding, as found in Type 1, CFF, and *)
(* OpenType/CFF fonts. It is limited to 256 character codes. *)
(* *)
(* FT_ENCODING_APPLE_ROMAN :: *)
(* Corresponds to the 8-bit Apple roman encoding. Many TrueType and *)
(* OpenType fonts contain a charmap for this encoding, since older *)
(* versions of Mac OS are able to use it. *)
(* *)
(* FT_ENCODING_OLD_LATIN_2 :: *)
(* This value is deprecated and was never used nor reported by *)
(* FreeType. Don't use or test for it. *)
(* *)
(* FT_ENCODING_MS_SJIS :: *)
(* Same as FT_ENCODING_SJIS. Deprecated. *)
(* *)
(* FT_ENCODING_MS_GB2312 :: *)
(* Same as FT_ENCODING_GB2312. Deprecated. *)
(* *)
(* FT_ENCODING_MS_BIG5 :: *)
(* Same as FT_ENCODING_BIG5. Deprecated. *)
(* *)
(* FT_ENCODING_MS_WANSUNG :: *)
(* Same as FT_ENCODING_WANSUNG. Deprecated. *)
(* *)
(* FT_ENCODING_MS_JOHAB :: *)
(* Same as FT_ENCODING_JOHAB. Deprecated. *)
(* *)
(* <Note> *)
(* By default, FreeType automatically synthetizes a Unicode charmap *)
(* for Postscript fonts, using their glyph names dictionaries. *)
(* However, it will also report the encodings defined explicitly in *)
(* the font file, for the cases when they are needed, with the Adobe *)
(* values as well. *)
(* *)
(* FT_ENCODING_NONE is set by the BDF and PCF drivers if the charmap *)
(* is neither Unicode nor ISO-8859-1 (otherwise it is set to *)
(* FT_ENCODING_UNICODE). Use `FT_Get_BDF_Charset_ID' to find out *)
(* which encoding is really present. If, for example, the *)
(* `cs_registry' field is `KOI8' and the `cs_encoding' field is `R', *)
(* the font is encoded in KOI8-R. *)
(* *)
(* FT_ENCODING_NONE is always set (with a single exception) by the *)
(* winfonts driver. Use `FT_Get_WinFNT_Header' and examine the *)
(* `charset' field of the `FT_WinFNT_HeaderRec' structure to find out *)
(* which encoding is really present. For example, FT_WinFNT_ID_CP1251 *)
(* (204) means Windows code page 1251 (for Russian). *)
(* *)
(* FT_ENCODING_NONE is set if `platform_id' is `TT_PLATFORM_MACINTOSH' *)
(* and `encoding_id' is not `TT_MAC_ID_ROMAN' (otherwise it is set to *)
(* FT_ENCODING_APPLE_ROMAN). *)
(* *)
(* If `platform_id' is `TT_PLATFORM_MACINTOSH', use the function *)
(* `FT_Get_CMap_Language_ID' to query the Mac language ID which may be *)
(* needed to be able to distinguish Apple encoding variants. See *)
(* *)
(* http://www.unicode.org/Public/MAPPINGS/VENDORS/APPLE/README.TXT *)
(* *)
(* to get an idea how to do that. Basically, if the language ID is 0, *)
(* dont use it, otherwise subtract 1 from the language ID. Then *)
(* examine `encoding_id'. If, for example, `encoding_id' is *)
(* `TT_MAC_ID_ROMAN' and the language ID (minus 1) is *)
(* `TT_MAC_LANGID_GREEK', it is the Greek encoding, not Roman. *)
(* `TT_MAC_ID_ARABIC' with `TT_MAC_LANGID_FARSI' means the Farsi *)
(* variant the Arabic encoding. *)
(* *)
type
PFT_Encoding = ^FT_Encoding;
FT_Encoding = array[0..3] of char;
const
FT_ENCODING_NONE: FT_Encoding = (#0 ,#0 ,#0 ,#0 );
FT_ENCODING_MS_SYMBOL: FT_Encoding = ('s', 'y', 'm', 'b' );
FT_ENCODING_UNICODE: FT_Encoding = ('u', 'n', 'i', 'c' );
FT_ENCODING_SJIS: FT_Encoding = ('s', 'j', 'i', 's');
FT_ENCODING_GB2312: FT_Encoding = ('g', 'b', ' ', ' ');
FT_ENCODING_BIG5: FT_Encoding = ('b', 'i', 'g', '5');
FT_ENCODING_WANSUNG: FT_Encoding = ('w', 'a', 'n', 's');
FT_ENCODING_JOHAB: FT_Encoding = ('j', 'o', 'h', 'a');
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Glyph_Format *)
(* *)
(* <Description> *)
(* An enumeration type used to describe the format of a given glyph *)
(* image. Note that this version of FreeType only supports two image *)
(* formats, even though future font drivers will be able to register *)
(* their own format. *)
(* *)
(* <Values> *)
(* FT_GLYPH_FORMAT_NONE :: *)
(* The value 0 is reserved and does describe a glyph format. *)
(* *)
(* FT_GLYPH_FORMAT_COMPOSITE :: *)
(* The glyph image is a composite of several other images. This *)
(* format is _only_ used with @FT_LOAD_NO_RECURSE, and is used to *)
(* report compound glyphs (like accented characters). *)
(* *)
(* FT_GLYPH_FORMAT_BITMAP :: *)
(* The glyph image is a bitmap, and can be described as an *)
(* @FT_Bitmap. You generally need to access the `bitmap' field of *)
(* the @FT_GlyphSlotRec structure to read it. *)
(* *)
(* FT_GLYPH_FORMAT_OUTLINE :: *)
(* The glyph image is a vertorial outline made of line segments *)
(* and Bezier arcs; it can be described as an @FT_Outline; you *)
(* generally want to access the `outline' field of the *)
(* @FT_GlyphSlotRec structure to read it. *)
(* *)
(* FT_GLYPH_FORMAT_PLOTTER :: *)
(* The glyph image is a vectorial path with no inside/outside *)
(* contours. Some Type 1 fonts, like those in the Hershey family, *)
(* contain glyphs in this format. These are described as *)
(* @FT_Outline, but FreeType isn't currently capable of rendering *)
(* them correctly. *)
(* *)
type
FT_Glyph_Format = array[0..3] of char;
const
FT_GLYPH_FORMAT_NONE: FT_Glyph_Format = (#0, #0, #0, #0 );
FT_GLYPH_FORMAT_COMPOSITE: FT_Glyph_Format = ('c', 'o', 'm', 'p' );
FT_GLYPH_FORMAT_BITMAP: FT_Glyph_Format = ('b', 'i', 't', 's' );
FT_GLYPH_FORMAT_OUTLINE: FT_Glyph_Format = ('o', 'u', 't', 'l' );
FT_GLYPH_FORMAT_PLOTTER: FT_Glyph_Format = ('p', 'l', 'o', 't' );
(*************************************************************************)
(* *)
(* <Constant> *)
(* FT_STYLE_FLAG_XXX *)
(* *)
(* <Description> *)
(* A list of bit-flags used to indicate the style of a given face. *)
(* These are used in the `style_flags' field of @FT_FaceRec. *)
(* *)
(* <Values> *)
(* FT_STYLE_FLAG_ITALIC :: *)
(* Indicates that a given face is italicized. *)
(* *)
(* FT_STYLE_FLAG_BOLD :: *)
(* Indicates that a given face is bold. *)
(* *)
const
FT_STYLE_FLAG_ITALIC = 1 shl 0;
FT_STYLE_FLAG_BOLD = 1 shl 1;
(***************************************************************************
*
* @enum:
* FT_LOAD_XXX
*
* @description:
* A list of bit-field constants, used with @FT_Load_Glyph to indicate
* what kind of operations to perform during glyph loading.
*
* @values:
* FT_LOAD_DEFAULT ::
* Corresponding to 0, this value is used a default glyph load. In this
* case, the following will happen:
*
* 1. FreeType looks for a bitmap for the glyph corresponding to the
* face's current size. If one is found, the function returns. The
* bitmap data can be accessed from the glyph slot (see note below).
*
* 2. If no embedded bitmap is searched or found, FreeType looks for a
* scalable outline. If one is found, it is loaded from the font
* file, scaled to device pixels, then "hinted" to the pixel grid in
* order to optimize it. The outline data can be accessed from the
* glyph slot (see note below).
*
* Note that by default, the glyph loader doesn't render outlines into
* bitmaps. The following flags are used to modify this default
* behaviour to more specific and useful cases.
*
* FT_LOAD_NO_SCALE ::
* Don't scale the vector outline being loaded to 26.6 fractional
* pixels, but kept in font units. Note that this also disables
* hinting and the loading of embedded bitmaps. You should only use it
* when you want to retrieve the original glyph outlines in font units.
*
* FT_LOAD_NO_HINTING ::
* Don't hint glyph outlines after their scaling to device pixels.
* This generally generates "blurrier" glyphs in anti-aliased modes.
*
* This flag is ignored if @FT_LOAD_NO_SCALE is set.
*
* FT_LOAD_RENDER ::
* Render the glyph outline immediately into a bitmap before the glyph
* loader returns. By default, the glyph is rendered for the
* @FT_RENDER_MODE_NORMAL mode, which corresponds to 8-bit anti-aliased
* bitmaps using 256 opacity levels. You can use either
* @FT_LOAD_TARGET_MONO or @FT_LOAD_MONOCHROME to render 1-bit
* monochrome bitmaps.
*
* This flag is ignored if @FT_LOAD_NO_SCALE is set.
*
* FT_LOAD_NO_BITMAP ::
* Don't look for bitmaps when loading the glyph. Only scalable
* outlines will be loaded when available, and scaled, hinted, or
* rendered depending on other bit flags.
*
* This does not prevent you from rendering outlines to bitmaps
* with @FT_LOAD_RENDER, however.
*
* FT_LOAD_VERTICAL_LAYOUT ::
* Prepare the glyph image for vertical text layout. This basically
* means that `face.glyph.advance' will correspond to the vertical
* advance height (instead of the default horizontal advance width),
* and that the glyph image will be translated to match the vertical
* bearings positions.
*
* FT_LOAD_FORCE_AUTOHINT ::
* Force the use of the FreeType auto-hinter when a glyph outline is
* loaded. You shouldn't need this in a typical application, since it
* is mostly used to experiment with its algorithm.
*
* FT_LOAD_CROP_BITMAP ::
* Indicates that the glyph loader should try to crop the bitmap (i.e.,
* remove all space around its black bits) when loading it. This is
* only useful when loading embedded bitmaps in certain fonts, since
* bitmaps rendered with @FT_LOAD_RENDER are always cropped by default.
*
* FT_LOAD_PEDANTIC ::
* Indicates that the glyph loader should perform pedantic
* verifications during glyph loading, rejecting invalid fonts. This
* is mostly used to detect broken glyphs in fonts. By default,
* FreeType tries to handle broken fonts also.
*
* FT_LOAD_IGNORE_GLOBAL_ADVANCE_WIDTH ::
* Indicates that the glyph loader should ignore the global advance
* width defined in the font. As far as we know, this is only used by
* the X-TrueType font server, in order to deal correctly with the
* incorrect metrics contained in DynaLab's TrueType CJK fonts.
*
* FT_LOAD_NO_RECURSE ::
* This flag is only used internally. It merely indicates that the
* glyph loader should not load composite glyphs recursively. Instead,
* it should set the `num_subglyph' and `subglyphs' values of the glyph
* slot accordingly, and set "glyph->format" to
* @FT_GLYPH_FORMAT_COMPOSITE.
*
* The description of sub-glyphs is not available to client
* applications for now.
*
* FT_LOAD_IGNORE_TRANSFORM ::
* Indicates that the glyph loader should not try to transform the
* loaded glyph image. This doesn't prevent scaling, hinting, or
* rendering.
*
* FT_LOAD_MONOCHROME ::
* This flag is used with @FT_LOAD_RENDER to indicate that you want
* to render a 1-bit monochrome glyph bitmap from a vectorial outline.
*
* Note that this has no effect on the hinting algorithm used by the
* glyph loader. You should better use @FT_LOAD_TARGET_MONO if you
* want to render monochrome-optimized glyph images instead.
*
* FT_LOAD_LINEAR_DESIGN ::
* Return the linearly scaled metrics expressed in original font units
* instead of the default 16.16 pixel values.
*
* FT_LOAD_NO_AUTOHINT ::
* Indicates that the auto-hinter should never be used to hint glyph
* outlines. This doesn't prevent native format-specific hinters from
* being used. This can be important for certain fonts where unhinted
* output is better than auto-hinted one.
*
* FT_LOAD_TARGET_NORMAL ::
* Use hinting for @FT_RENDER_MODE_NORMAL.
*
* FT_LOAD_TARGET_LIGHT ::
* Use hinting for @FT_RENDER_MODE_LIGHT.
*
* FT_LOAD_TARGET_MONO ::
* Use hinting for @FT_RENDER_MODE_MONO.
*
* FT_LOAD_TARGET_LCD ::
* Use hinting for @FT_RENDER_MODE_LCD.
*
* FT_LOAD_TARGET_LCD_V ::
* Use hinting for @FT_RENDER_MODE_LCD_V.
*)
const
FT_LOAD_DEFAULT = $0000;
FT_LOAD_NO_SCALE = $0001;
FT_LOAD_NO_HINTING = $0002;
FT_LOAD_RENDER = $0004;
FT_LOAD_NO_BITMAP = $0008;
FT_LOAD_VERTICAL_LAYOUT = $0010;
FT_LOAD_FORCE_AUTOHINT = $0020;
FT_LOAD_CROP_BITMAP = $0040;
FT_LOAD_PEDANTIC = $0080;
FT_LOAD_IGNORE_GLOBAL_ADVANCE_WIDTH = $0200;
FT_LOAD_NO_RECURSE = $0400;
FT_LOAD_IGNORE_TRANSFORM = $0800;
FT_LOAD_MONOCHROME = $1000;
FT_LOAD_LINEAR_DESIGN = $2000;
(* temporary hack! *)
FT_LOAD_SBITS_ONLY = $4000;
FT_LOAD_NO_AUTOHINT = $8000;
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Render_Mode *)
(* *)
(* <Description> *)
(* An enumeration type that lists the render modes supported by *)
(* FreeType 2. Each mode corresponds to a specific type of scanline *)
(* conversion performed on the outline, as well as specific *)
(* hinting optimizations. *)
(* *)
(* For bitmap fonts the `bitmap->pixel_mode' field in the *)
(* @FT_GlyphSlotRec structure gives the format of the returned *)
(* bitmap. *)
(* *)
(* <Values> *)
(* FT_RENDER_MODE_NORMAL :: *)
(* This is the default render mode; it corresponds to 8-bit *)
(* anti-aliased bitmaps, using 256 levels of opacity. *)
(* *)
(* FT_RENDER_MODE_LIGHT :: *)
(* This is similar to @FT_RENDER_MODE_NORMAL -- you have to use *)
(* @FT_LOAD_TARGET_LIGHT in calls to @FT_Load_Glyph to get any *)
(* effect since the rendering process no longer influences the *)
(* positioning of glyph outlines. *)
(* *)
(* The resulting glyph shapes are more similar to the original, *)
(* while being a bit more fuzzy (`better shapes' instead of `better *)
(* contrast', so to say. *)
(* *)
(* FT_RENDER_MODE_MONO :: *)
(* This mode corresponds to 1-bit bitmaps. *)
(* *)
(* FT_RENDER_MODE_LCD :: *)
(* This mode corresponds to horizontal RGB/BGR sub-pixel displays, *)
(* like LCD-screens. It produces 8-bit bitmaps that are 3 times *)
(* the width of the original glyph outline in pixels, and which use *)
(* the @FT_PIXEL_MODE_LCD mode. *)
(* *)
(* FT_RENDER_MODE_LCD_V :: *)
(* This mode corresponds to vertical RGB/BGR sub-pixel displays *)
(* (like PDA screens, rotated LCD displays, etc.). It produces *)
(* 8-bit bitmaps that are 3 times the height of the original *)
(* glyph outline in pixels and use the @FT_PIXEL_MODE_LCD_V mode. *)
(* *)
(* <Note> *)
(* The LCD-optimized glyph bitmaps produced by FT_Render_Glyph are *)
(* _not filtered_ to reduce color-fringes. It is up to the caller to *)
(* perform this pass. *)
(* *)
type
FT_Render_Mode = FT_Int;
const
FT_RENDER_MODE_NORMAL = 0;
FT_RENDER_MODE_LIGHT = FT_RENDER_MODE_NORMAL + 1;
FT_RENDER_MODE_MONO = FT_RENDER_MODE_LIGHT + 1;
FT_RENDER_MODE_LCD = FT_RENDER_MODE_MONO + 1;
FT_RENDER_MODE_LCD_V = FT_RENDER_MODE_LCD + 1;
FT_RENDER_MODE_MAX = FT_RENDER_MODE_LCD_V + 1;
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Pixel_Mode *)
(* *)
(* <Description> *)
(* An enumeration type used to describe the format of pixels in a *)
(* given bitmap. Note that additional formats may be added in the *)
(* future. *)
(* *)
(* <Values> *)
(* FT_PIXEL_MODE_NONE :: *)
(* Value 0 is reserved. *)
(* *)
(* FT_PIXEL_MODE_MONO :: *)
(* A monochrome bitmap, using 1 bit per pixel. Note that pixels *)
(* are stored in most-significant order (MSB), which means that *)
(* the left-most pixel in a byte has value 128. *)
(* *)
(* FT_PIXEL_MODE_GRAY :: *)
(* An 8-bit bitmap, generally used to represent anti-aliased glyph *)
(* images. Each pixel is stored in one byte. Note that the number *)
(* of value `gray' levels is stored in the `num_bytes' field of *)
(* the @FT_Bitmap structure (it generally is 256). *)
(* *)
(* FT_PIXEL_MODE_GRAY2 :: *)
(* A 2-bit/pixel bitmap, used to represent embedded anti-aliased *)
(* bitmaps in font files according to the OpenType specification. *)
(* We haven't found a single font using this format, however. *)
(* *)
(* FT_PIXEL_MODE_GRAY4 :: *)
(* A 4-bit/pixel bitmap, used to represent embedded anti-aliased *)
(* bitmaps in font files according to the OpenType specification. *)
(* We haven't found a single font using this format, however. *)
(* *)
(* FT_PIXEL_MODE_LCD :: *)
(* An 8-bit bitmap, used to represent RGB or BGR decimated glyph *)
(* images used for display on LCD displays; the bitmap is three *)
(* times wider than the original glyph image. See also *)
(* @FT_RENDER_MODE_LCD. *)
(* *)
(* FT_PIXEL_MODE_LCD_V :: *)
(* An 8-bit bitmap, used to represent RGB or BGR decimated glyph *)
(* images used for display on rotated LCD displays; the bitmap *)
(* is three times taller than the original glyph image. See also *)
(* @FT_RENDER_MODE_LCD_V. *)
(* *)
type
FT_Pixel_Mode = byte;
const
FT_PIXEL_MODE_NONE = 0;
FT_PIXEL_MODE_MONO = FT_PIXEL_MODE_NONE + 1;
FT_PIXEL_MODE_GRAY = FT_PIXEL_MODE_MONO + 1;
FT_PIXEL_MODE_GRAY2 = FT_PIXEL_MODE_GRAY + 1;
FT_PIXEL_MODE_GRAY4 = FT_PIXEL_MODE_GRAY2 + 1;
FT_PIXEL_MODE_LCD = FT_PIXEL_MODE_GRAY4 + 1;
FT_PIXEL_MODE_LCD_V = FT_PIXEL_MODE_LCD + 1;
FT_PIXEL_MODE_MAX = FT_PIXEL_MODE_LCD_V + 1; (* do not remove *)
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Glyph_Metrics *)
(* *)
(* <Description> *)
(* A structure used to model the metrics of a single glyph. The *)
(* values are expressed in 26.6 fractional pixel format; if the flag *)
(* FT_LOAD_NO_SCALE is used, values are returned in font units *)
(* instead. *)
(* *)
(* <Fields> *)
(* width :: *)
(* The glyph's width. *)
(* *)
(* height :: *)
(* The glyph's height. *)
(* *)
(* horiBearingX :: *)
(* Left side bearing for horizontal layout. *)
(* *)
(* horiBearingY :: *)
(* Top side bearing for horizontal layout. *)
(* *)
(* horiAdvance :: *)
(* Advance width for horizontal layout. *)
(* *)
(* vertBearingX :: *)
(* Left side bearing for vertical layout. *)
(* *)
(* vertBearingY :: *)
(* Top side bearing for vertical layout. *)
(* *)
(* vertAdvance :: *)
(* Advance height for vertical layout. *)
(* *)
type
FT_Glyph_Metrics = record
width ,
height : FT_Pos;
horiBearingX ,
horiBearingY ,
horiAdvance : FT_Pos;
vertBearingX ,
vertBearingY ,
vertAdvance : FT_Pos;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Bitmap_Size *)
(* *)
(* <Description> *)
(* This structure models the size of a bitmap strike (i.e., a bitmap *)
(* instance of the font for a given resolution) in a fixed-size font *)
(* face. It is used for the `available_sizes' field of the *)
(* @FT_FaceRec structure. *)
(* *)
(* <Fields> *)
(* height :: The (vertical) baseline-to-baseline distance in pixels. *)
(* It makes most sense to define the height of a bitmap *)
(* font in this way. *)
(* *)
(* width :: The average width of the font (in pixels). Since the *)
(* algorithms to compute this value are different for the *)
(* various bitmap formats, it can only give an additional *)
(* hint if the `height' value isn't sufficient to select *)
(* the proper font. For monospaced fonts the average width *)
(* is the same as the maximum width. *)
(* *)
(* size :: The point size in 26.6 fractional format this font shall *)
(* represent (for a given vertical resolution). *)
(* *)
(* x_ppem :: The horizontal ppem value (in 26.6 fractional format). *)
(* *)
(* y_ppem :: The vertical ppem value (in 26.6 fractional format). *)
(* Usually, this is the `nominal' pixel height of the font. *)
(* *)
(* <Note> *)
(* The values in this structure are taken from the bitmap font. If *)
(* the font doesn't provide a parameter it is set to zero to indicate *)
(* that the information is not available. *)
(* *)
(* The following formula converts from dpi to ppem: *)
(* *)
(* ppem = size * dpi / 72 *)
(* *)
(* where `size' is in points. *)
(* *)
(* Windows FNT: *)
(* The `size' parameter is not reliable: There exist fonts (e.g., *)
(* app850.fon) which have a wrong size for some subfonts; x_ppem *)
(* and y_ppem are thus set equal to pixel width and height given in *)
(* in the Windows FNT header. *)
(* *)
(* TrueType embedded bitmaps: *)
(* `size', `width', and `height' values are not contained in the *)
(* bitmap strike itself. They are computed from the global font *)
(* parameters. *)
(* *)
PFT_Bitmap_Size = ^FT_Bitmap_Size;
FT_Bitmap_Size = record
height,
width : FT_Short;
size: FT_Pos;
x_ppem: FT_Pos;
y_ppem: FT_Pos;
end;
PAFT_Bitmap_Size = ^AFT_Bitmap_Size;
AFT_Bitmap_Size = array[0..High(Word)] of FT_Bitmap_Size;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Vector *)
(* *)
(* <Description> *)
(* A simple structure used to store a 2D vector; coordinates are of *)
(* the FT_Pos type. *)
(* *)
(* <Fields> *)
(* x :: The horizontal coordinate. *)
(* y :: The vertical coordinate. *)
(* *)
PFT_Vector = ^FT_Vector;
FT_Vector = record
x ,
y : FT_Pos;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Outline *)
(* *)
(* <Description> *)
(* This structure is used to describe an outline to the scan-line *)
(* converter. *)
(* *)
(* <Fields> *)
(* n_contours :: The number of contours in the outline. *)
(* *)
(* n_points :: The number of points in the outline. *)
(* *)
(* points :: A pointer to an array of `n_points' FT_Vector *)
(* elements, giving the outline's point coordinates. *)
(* *)
(* tags :: A pointer to an array of `n_points' chars, giving *)
(* each outline point's type. If bit 0 is unset, the *)
(* point is `off' the curve, i.e. a Bezier control *)
(* point, while it is `on' when set. *)
(* *)
(* Bit 1 is meaningful for `off' points only. If set, *)
(* it indicates a third-order Bezier arc control point; *)
(* and a second-order control point if unset. *)
(* *)
(* contours :: An array of `n_contours' shorts, giving the end *)
(* point of each contour within the outline. For *)
(* example, the first contour is defined by the points *)
(* `0' to `contours[0]', the second one is defined by *)
(* the points `contours[0]+1' to `contours[1]', etc. *)
(* *)
(* flags :: A set of bit flags used to characterize the outline *)
(* and give hints to the scan-converter and hinter on *)
(* how to convert/grid-fit it. See FT_Outline_Flags. *)
(* *)
PFT_Outline = ^FT_Outline;
FT_Outline = record
n_contours : FT_Short;
n_points : FT_Short;
points : PFT_Vector;
tags : PChar;
contours : PFT_Short;
flags : FT_Int;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Bitmap *)
(* *)
(* <Description> *)
(* A structure used to describe a bitmap or pixmap to the raster. *)
(* Note that we now manage pixmaps of various depths through the *)
(* `pixel_mode' field. *)
(* *)
(* <Fields> *)
(* rows :: The number of bitmap rows. *)
(* *)
(* width :: The number of pixels in bitmap row. *)
(* *)
(* pitch :: The pitch's absolute value is the number of bytes *)
(* taken by one bitmap row, including padding. *)
(* However, the pitch is positive when the bitmap has *)
(* a `down' flow, and negative when it has an `up' *)
(* flow. In all cases, the pitch is an offset to add *)
(* to a bitmap pointer in order to go down one row. *)
(* *)
(* buffer :: A typeless pointer to the bitmap buffer. This *)
(* value should be aligned on 32-bit boundaries in *)
(* most cases. *)
(* *)
(* num_grays :: This field is only used with *)
(* `FT_PIXEL_MODE_GRAY'; it gives the number of gray *)
(* levels used in the bitmap. *)
(* *)
(* pixel_mode :: The pixel mode, i.e., how pixel bits are stored. *)
(* See @FT_Pixel_Mode for possible values. *)
(* *)
(* palette_mode :: This field is only used with paletted pixel modes; *)
(* it indicates how the palette is stored. *)
(* *)
(* palette :: A typeless pointer to the bitmap palette; only *)
(* used for paletted pixel modes. *)
(* *)
(* <Note> *)
(* For now, the only pixel mode supported by FreeType are mono and *)
(* grays. However, drivers might be added in the future to support *)
(* more `colorful' options. *)
(* *)
(* When using pixel modes pal2, pal4 and pal8 with a void `palette' *)
(* field, a gray pixmap with respectively 4, 16, and 256 levels of *)
(* gray is assumed. This, in order to be compatible with some *)
(* embedded bitmap formats defined in the TrueType specification. *)
(* *)
(* Note that no font was found presenting such embedded bitmaps, so *)
(* this is currently completely unhandled by the library. *)
(* *)
PFT_Bitmap = ^FT_Bitmap;
FT_Bitmap = record
rows ,
width : FT_Int;
pitch : FT_Int;
buffer : PByteArray;
num_grays : FT_Short;
pixel_mode ,
palette_mode : byte;
palette : pointer;
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_Face *)
(* *)
(* <Description> *)
(* A handle to a given typographic face object. A face object models *)
(* a given typeface, in a given style. *)
(* *)
(* <Note> *)
(* Each face object also owns a single @FT_GlyphSlot object, as well *)
(* as one or more @FT_Size objects. *)
(* *)
(* Use @FT_New_Face or @FT_Open_Face to create a new face object from *)
(* a given filepathname or a custom input stream. *)
(* *)
(* Use @FT_Done_Face to destroy it (along with its slot and sizes). *)
(* *)
(* <Also> *)
(* The @FT_FaceRec details the publicly accessible fields of a given *)
(* face object. *)
(* *)
FT_Face = ^FT_FaceRec;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_CharMap *)
(* *)
(* <Description> *)
(* A handle to a given character map. A charmap is used to translate *)
(* character codes in a given encoding into glyph indexes for its *)
(* parent's face. Some font formats may provide several charmaps per *)
(* font. *)
(* *)
(* Each face object owns zero or more charmaps, but only one of them *)
(* can be "active" and used by @FT_Get_Char_Index or @FT_Load_Char. *)
(* *)
(* The list of available charmaps in a face is available through the *)
(* "face->num_charmaps" and "face->charmaps" fields of @FT_FaceRec. *)
(* *)
(* The currently active charmap is available as "face->charmap". *)
(* You should call @FT_Set_Charmap to change it. *)
(* *)
(* <Note> *)
(* When a new face is created (either through @FT_New_Face or *)
(* @FT_Open_Face), the library looks for a Unicode charmap within *)
(* the list and automatically activates it. *)
(* *)
(* <Also> *)
(* The @FT_CharMapRec details the publicly accessible fields of a *)
(* given character map. *)
(* *)
PFT_CharMap = ^FT_CharMap;
FT_CharMap = ^FT_CharMapRec;
PAFT_CharMap = ^FT_CharMap;
AFT_CharMap = array[0..High(Word)] of FT_CharMap;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_Library *)
(* *)
(* <Description> *)
(* A handle to a FreeType library instance. Each `library' is *)
(* completely independent from the others; it is the `root' of a set *)
(* of objects like fonts, faces, sizes, etc. *)
(* *)
(* It also embeds a memory manager (see @FT_Memory), as well as a *)
(* scan-line converter object (see @FT_Raster). *)
(* *)
(* <Note> *)
(* Library objects are normally created by @FT_Init_FreeType, and *)
(* destroyed with @FT_Done_FreeType. *)
(* *)
FT_Library = ^FT_LibraryRec;
FT_LibraryRec = record // internal
end;
(*************************************************************************)
(* *)
(* <Section> *)
(* glyph_management *)
(* *)
(* <Title> *)
(* Glyph Management *)
(* *)
(* <Abstract> *)
(* Generic interface to manage individual glyph data. *)
(* *)
(* <Description> *)
(* This section contains definitions used to manage glyph data *)
(* through generic FT_Glyph objects. Each of them can contain a *)
(* bitmap, a vector outline, or even images in other formats. *)
(* *)
(*************************************************************************)
(* forward declaration to a private type *)
PFT_Glyph_Class = ^FT_Glyph_Class;
FT_Glyph_Class = record // internal
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_Glyph *)
(* *)
(* <Description> *)
(* Handle to an object used to model generic glyph images. It is a *)
(* pointer to the @FT_GlyphRec structure and can contain a glyph *)
(* bitmap or pointer. *)
(* *)
(* <Note> *)
(* Glyph objects are not owned by the library. You must thus release *)
(* them manually (through @FT_Done_Glyph) _before_ calling *)
(* @FT_Done_FreeType. *)
(* *)
FT_Glyph = ^FT_GlyphRec;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_GlyphRec *)
(* *)
(* <Description> *)
(* The root glyph structure contains a given glyph image plus its *)
(* advance width in 16.16 fixed float format. *)
(* *)
(* <Fields> *)
(* library :: A handle to the FreeType library object. *)
(* *)
(* clazz :: A pointer to the glyph's class. Private. *)
(* *)
(* format :: The format of the glyph's image. *)
(* *)
(* advance :: A 16.16 vector that gives the glyph's advance width. *)
(* *)
FT_GlyphRec = record
library_: FT_Library;
clazz: PFT_Glyph_Class;
format: FT_Glyph_Format;
advance: FT_Vector;
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_BitmapGlyph *)
(* *)
(* <Description> *)
(* A handle to an object used to model a bitmap glyph image. This is *)
(* a sub-class of @FT_Glyph, and a pointer to @FT_BitmapGlyphRec. *)
(* *)
FT_BitmapGlyph = ^FT_BitmapGlyphRec;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_BitmapGlyphRec *)
(* *)
(* <Description> *)
(* A structure used for bitmap glyph images. This really is a *)
(* `sub-class' of `FT_GlyphRec'. *)
(* *)
(* <Fields> *)
(* root :: The root FT_Glyph fields. *)
(* *)
(* left :: The left-side bearing, i.e., the horizontal distance *)
(* from the current pen position to the left border of the *)
(* glyph bitmap. *)
(* *)
(* top :: The top-side bearing, i.e., the vertical distance from *)
(* the current pen position to the top border of the glyph *)
(* bitmap. This distance is positive for upwards-y! *)
(* *)
(* bitmap :: A descriptor for the bitmap. *)
(* *)
(* <Note> *)
(* You can typecast FT_Glyph to FT_BitmapGlyph if you have *)
(* glyph->format == FT_GLYPH_FORMAT_BITMAP. This lets you access *)
(* the bitmap's contents easily. *)
(* *)
(* The corresponding pixel buffer is always owned by the BitmapGlyph *)
(* and is thus created and destroyed with it. *)
(* *)
FT_BitmapGlyphRec = record
root: FT_GlyphRec;
left: FT_Int;
top: FT_Int;
bitmap: FT_Bitmap;
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_OutlineGlyph *)
(* *)
(* <Description> *)
(* A handle to an object used to model an outline glyph image. This *)
(* is a sub-class of @FT_Glyph, and a pointer to @FT_OutlineGlyphRec. *)
(* *)
FT_OutlineGlyph = ^FT_OutlineGlyphRec;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_OutlineGlyphRec *)
(* *)
(* <Description> *)
(* A structure used for outline (vectorial) glyph images. This *)
(* really is a `sub-class' of `FT_GlyphRec'. *)
(* *)
(* <Fields> *)
(* root :: The root FT_Glyph fields. *)
(* *)
(* outline :: A descriptor for the outline. *)
(* *)
(* <Note> *)
(* You can typecast FT_Glyph to FT_OutlineGlyph if you have *)
(* glyph->format == FT_GLYPH_FORMAT_OUTLINE. This lets you access *)
(* the outline's content easily. *)
(* *)
(* As the outline is extracted from a glyph slot, its coordinates are *)
(* expressed normally in 26.6 pixels, unless the flag *)
(* FT_LOAD_NO_SCALE was used in FT_Load_Glyph() or FT_Load_Char(). *)
(* *)
(* The outline's tables are always owned by the object and are *)
(* destroyed with it. *)
(* *)
FT_OutlineGlyphRec = record
root: FT_GlyphRec;
outline: FT_Outline;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_SubGlyph *)
(* *)
(* <Description> *)
(* The subglyph structure is an internal object used to describe *)
(* subglyphs (for example, in the case of composites). *)
(* *)
(* <Note> *)
(* The subglyph implementation is not part of the high-level API, *)
(* hence the forward structure declaration. *)
(* *)
FT_SubGlyph = ^FT_SubGlyphRec;
FT_SubGlyphRec = record // internal
end;
(*************************************************************************)
(* *)
(* <FuncType> *)
(* FT_Generic_Finalizer *)
(* *)
(* <Description> *)
(* Describes a function used to destroy the `client' data of any *)
(* FreeType object. See the description of the FT_Generic type for *)
(* details of usage. *)
(* *)
(* <Input> *)
(* The address of the FreeType object which is under finalization. *)
(* Its client data is accessed through its `generic' field. *)
(* *)
FT_Generic_Finalizer = procedure(AnObject : pointer ); cdecl;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Generic *)
(* *)
(* <Description> *)
(* Client applications often need to associate their own data to a *)
(* variety of FreeType core objects. For example, a text layout API *)
(* might want to associate a glyph cache to a given size object. *)
(* *)
(* Most FreeType object contains a `generic' field, of type *)
(* FT_Generic, which usage is left to client applications and font *)
(* servers. *)
(* *)
(* It can be used to store a pointer to client-specific data, as well *)
(* as the address of a `finalizer' function, which will be called by *)
(* FreeType when the object is destroyed (for example, the previous *)
(* client example would put the address of the glyph cache destructor *)
(* in the `finalizer' field). *)
(* *)
(* <Fields> *)
(* data :: A typeless pointer to any client-specified data. This *)
(* field is completely ignored by the FreeType library. *)
(* *)
(* finalizer :: A pointer to a `generic finalizer' function, which *)
(* will be called when the object is destroyed. If this *)
(* field is set to NULL, no code will be called. *)
(* *)
FT_Generic = record
data : pointer;
finalizer : FT_Generic_Finalizer;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_BBox *)
(* *)
(* <Description> *)
(* A structure used to hold an outline's bounding box, i.e., the *)
(* coordinates of its extrema in the horizontal and vertical *)
(* directions. *)
(* *)
(* <Fields> *)
(* xMin :: The horizontal minimum (left-most). *)
(* *)
(* yMin :: The vertical minimum (bottom-most). *)
(* *)
(* xMax :: The horizontal maximum (right-most). *)
(* *)
(* yMax :: The vertical maximum (top-most). *)
(* *)
PFT_BBox = ^FT_BBox;
FT_BBox = record
xMin, yMin : FT_Pos;
xMax, yMax : FT_Pos;
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_GlyphSlot *)
(* *)
(* <Description> *)
(* A handle to a given `glyph slot'. A slot is a container where it *)
(* is possible to load any one of the glyphs contained in its parent *)
(* face. *)
(* *)
(* In other words, each time you call @FT_Load_Glyph or *)
(* @FT_Load_Char, the slot's content is erased by the new glyph data, *)
(* i.e. the glyph's metrics, its image (bitmap or outline), and *)
(* other control information. *)
(* *)
(* <Also> *)
(* @FT_GlyphSlotRec details the publicly accessible glyph fields. *)
(* *)
FT_GlyphSlot = ^FT_GlyphSlotRec;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_GlyphSlotRec *)
(* *)
(* <Description> *)
(* FreeType root glyph slot class structure. A glyph slot is a *)
(* container where individual glyphs can be loaded, be they *)
(* vectorial or bitmap/graymaps. *)
(* *)
(* <Fields> *)
(* library :: A handle to the FreeType library instance *)
(* this slot belongs to. *)
(* *)
(* face :: A handle to the parent face object. *)
(* *)
(* next :: In some cases (like some font tools), several *)
(* glyph slots per face object can be a good *)
(* thing. As this is rare, the glyph slots are *)
(* listed through a direct, single-linked list *)
(* using its `next' field. *)
(* *)
(* generic :: A typeless pointer which is unused by the *)
(* FreeType library or any of its drivers. It *)
(* can be used by client applications to link *)
(* their own data to each glyph slot object. *)
(* *)
(* metrics :: The metrics of the last loaded glyph in the *)
(* slot. The returned values depend on the last *)
(* load flags (see the @FT_Load_Glyph API *)
(* function) and can be expressed either in 26.6 *)
(* fractional pixels or font units. *)
(* *)
(* Note that even when the glyph image is *)
(* transformed, the metrics are not. *)
(* *)
(* linearHoriAdvance :: For scalable formats only, this field holds *)
(* the linearly scaled horizontal advance width *)
(* for the glyph (i.e. the scaled and unhinted *)
(* value of the hori advance). This can be *)
(* important to perform correct WYSIWYG layout. *)
(* *)
(* Note that this value is expressed by default *)
(* in 16.16 pixels. However, when the glyph is *)
(* loaded with the FT_LOAD_LINEAR_DESIGN flag, *)
(* this field contains simply the value of the *)
(* advance in original font units. *)
(* *)
(* linearVertAdvance :: For scalable formats only, this field holds *)
(* the linearly scaled vertical advance height *)
(* for the glyph. See linearHoriAdvance for *)
(* comments. *)
(* *)
(* advance :: This is the transformed advance width for the *)
(* glyph. *)
(* *)
(* format :: This field indicates the format of the image *)
(* contained in the glyph slot. Typically *)
(* FT_GLYPH_FORMAT_BITMAP, *)
(* FT_GLYPH_FORMAT_OUTLINE, and *)
(* FT_GLYPH_FORMAT_COMPOSITE, but others are *)
(* possible. *)
(* *)
(* bitmap :: This field is used as a bitmap descriptor *)
(* when the slot format is *)
(* FT_GLYPH_FORMAT_BITMAP. Note that the *)
(* address and content of the bitmap buffer can *)
(* change between calls of @FT_Load_Glyph and a *)
(* few other functions. *)
(* *)
(* bitmap_left :: This is the bitmap's left bearing expressed *)
(* in integer pixels. Of course, this is only *)
(* valid if the format is *)
(* FT_GLYPH_FORMAT_BITMAP. *)
(* *)
(* bitmap_top :: This is the bitmap's top bearing expressed in *)
(* integer pixels. Remember that this is the *)
(* distance from the baseline to the top-most *)
(* glyph scanline, upwards y-coordinates being *)
(* *positive*. *)
(* *)
(* outline :: The outline descriptor for the current glyph *)
(* image if its format is *)
(* FT_GLYPH_FORMAT_OUTLINE. *)
(* *)
(* num_subglyphs :: The number of subglyphs in a composite glyph. *)
(* This field is only valid for the composite *)
(* glyph format that should normally only be *)
(* loaded with the @FT_LOAD_NO_RECURSE flag. *)
(* For now this is internal to FreeType. *)
(* *)
(* subglyphs :: An array of subglyph descriptors for *)
(* composite glyphs. There are `num_subglyphs' *)
(* elements in there. Currently internal to *)
(* FreeType. *)
(* *)
(* control_data :: Certain font drivers can also return the *)
(* control data for a given glyph image (e.g. *)
(* TrueType bytecode, Type 1 charstrings, etc.). *)
(* This field is a pointer to such data. *)
(* *)
(* control_len :: This is the length in bytes of the control *)
(* data. *)
(* *)
(* other :: Really wicked formats can use this pointer to *)
(* present their own glyph image to client apps. *)
(* Note that the app will need to know about the *)
(* image format. *)
(* *)
(* lsb_delta :: The difference between hinted and unhinted *)
(* left side bearing while autohinting is *)
(* active. Zero otherwise. *)
(* *)
(* rsb_delta :: The difference between hinted and unhinted *)
(* right side bearing while autohinting is *)
(* active. Zero otherwise. *)
(* *)
(* <Note> *)
(* If @FT_Load_Glyph is called with default flags (see *)
(* @FT_LOAD_DEFAULT) the glyph image is loaded in the glyph slot in *)
(* its native format (e.g. a vectorial outline for TrueType and *)
(* Type 1 formats). *)
(* *)
(* This image can later be converted into a bitmap by calling *)
(* @FT_Render_Glyph. This function finds the current renderer for *)
(* the native image's format then invokes it. *)
(* *)
(* The renderer is in charge of transforming the native image through *)
(* the slot's face transformation fields, then convert it into a *)
(* bitmap that is returned in `slot->bitmap'. *)
(* *)
(* Note that `slot->bitmap_left' and `slot->bitmap_top' are also used *)
(* to specify the position of the bitmap relative to the current pen *)
(* position (e.g. coordinates [0,0] on the baseline). Of course, *)
(* `slot->format' is also changed to `FT_GLYPH_FORMAT_BITMAP' . *)
(* *)
(* <Note> *)
(* Here a small pseudo code fragment which shows how to use *)
(* `lsb_delta' and `rsb_delta': *)
(* *)
(* { *)
(* FT_Pos origin_x = 0; *)
(* FT_Pos prev_rsb_delta = 0; *)
(* *)
(* *)
(* for all glyphs do *)
(* <compute kern between current and previous glyph and add it to *)
(* `origin_x'> *)
(* *)
(* <load glyph with `FT_Load_Glyph'> *)
(* *)
(* if ( prev_rsb_delta - face->glyph->lsb_delta >= 32 ) *)
(* origin_x -= 64; *)
(* else if ( prev_rsb_delta - face->glyph->lsb_delta < -32 ) *)
(* origin_x += 64; *)
(* *)
(* prev_rsb_delta = face->glyph->rsb_delta; *)
(* *)
(* <save glyph image, or render glyph, or ...> *)
(* *)
(* origin_x += face->glyph->advance.x; *)
(* endfor *)
(* } *)
(* *)
FT_GlyphSlotRec = record
alibrary : FT_Library;
face : FT_Face;
next : FT_GlyphSlot;
flags : FT_UInt;
generic : FT_Generic;
metrics : FT_Glyph_Metrics;
linearHoriAdvance ,
linearVertAdvance : FT_Fixed;
advance : FT_Vector;
format : FT_Glyph_Format;
bitmap : FT_Bitmap;
bitmap_left ,
bitmap_top : FT_Int;
outline : FT_Outline;
num_subglyphs : FT_UInt;
subglyphs : FT_SubGlyph;
control_data : pointer;
control_len : longint;
lsb_delta: FT_Pos;
rsb_delta: FT_Pos;
other : pointer;
//internal: FT_Slot_Internal;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_Size_Metrics *)
(* *)
(* <Description> *)
(* The size metrics structure returned scaled important distances for *)
(* a given size object. *)
(* *)
(* <Fields> *)
(* x_ppem :: The character width, expressed in integer pixels. *)
(* This is the width of the EM square expressed in *)
(* pixels, hence the term `ppem' (pixels per EM). *)
(* *)
(* y_ppem :: The character height, expressed in integer pixels. *)
(* This is the height of the EM square expressed in *)
(* pixels, hence the term `ppem' (pixels per EM). *)
(* *)
(* x_scale :: A simple 16.16 fixed point format coefficient used *)
(* to scale horizontal distances expressed in font *)
(* units to fractional (26.6) pixel coordinates. *)
(* *)
(* y_scale :: A simple 16.16 fixed point format coefficient used *)
(* to scale vertical distances expressed in font *)
(* units to fractional (26.6) pixel coordinates. *)
(* *)
(* ascender :: The ascender, expressed in 26.6 fixed point *)
(* pixels. Positive for ascenders above the *)
(* baseline. *)
(* *)
(* descender :: The descender, expressed in 26.6 fixed point *)
(* pixels. Negative for descenders below the *)
(* baseline. *)
(* *)
(* height :: The text height, expressed in 26.6 fixed point *)
(* pixels. Always positive. *)
(* *)
(* max_advance :: Maximum horizontal advance, expressed in 26.6 *)
(* fixed point pixels. Always positive. *)
(* *)
(* <Note> *)
(* For scalable fonts, the values of `ascender', `descender', and *)
(* `height' are scaled versions of `face->ascender', *)
(* `face->descender', and `face->height', respectively. *)
(* *)
(* Unfortunately, due to glyph hinting, these values might not be *)
(* exact for certain fonts. They thus must be treated as unreliable *)
(* with an error margin of at least one pixel! *)
(* *)
(* Indeed, the only way to get the exact pixel ascender and descender *)
(* is to render _all_ glyphs. As this would be a definite *)
(* performance hit, it is up to client applications to perform such *)
(* computations. *)
(* *)
FT_Size_Metrics = record
x_ppem ,
y_ppem : FT_UShort;
x_scale ,
y_scale : FT_Fixed;
ascender ,
descender : FT_Pos;
height : FT_Pos;
max_advance : FT_Pos;
end;
(*************************************************************************)
(* *)
(* <Type> *)
(* FT_Size *)
(* *)
(* <Description> *)
(* A handle to a given size object. Such an object models the data *)
(* that depends on the current _resolution_ and _character size_ in a *)
(* given @FT_Face. *)
(* *)
(* <Note> *)
(* Each face object owns one or more sizes. There is however a *)
(* single _active_ size for the face at any time that will be used by *)
(* functions like @FT_Load_Glyph, @FT_Get_Kerning, etc. *)
(* *)
(* You can use the @FT_Activate_Size API to change the current *)
(* active size of any given face. *)
(* *)
(* <Also> *)
(* The @FT_SizeRec structure details the publicly accessible fields *)
(* of a given face object. *)
(* *)
FT_Size = ^FT_SizeRec;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_SizeRec *)
(* *)
(* <Description> *)
(* FreeType root size class structure. A size object models the *)
(* resolution and pointsize dependent data of a given face. *)
(* *)
(* <Fields> *)
(* face :: Handle to the parent face object. *)
(* *)
(* generic :: A typeless pointer, which is unused by the FreeType *)
(* library or any of its drivers. It can be used by *)
(* client applications to link their own data to each size *)
(* object. *)
(* *)
(* metrics :: Metrics for this size object. This field is read-only. *)
(* *)
FT_SizeRec = record
face : FT_Face;
generic : FT_Generic;
metrics : FT_Size_Metrics;
//internal : FT_Size_Internal;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_FaceRec *)
(* *)
(* <Description> *)
(* FreeType root face class structure. A face object models the *)
(* resolution and point-size independent data found in a font file. *)
(* *)
(* <Fields> *)
(* num_faces :: In the case where the face is located in a *)
(* collection (i.e., a file which embeds *)
(* several faces), this is the total number of *)
(* faces found in the resource. 1 by default. *)
(* Accessing non-existent face indices causes *)
(* an error. *)
(* *)
(* face_index :: The index of the face in its font file. *)
(* Usually, this is 0 for all normal font *)
(* formats. It can be > 0 in the case of *)
(* collections (which embed several fonts in a *)
(* single resource/file). *)
(* *)
(* face_flags :: A set of bit flags that give important *)
(* information about the face; see the *)
(* @FT_FACE_FLAG_XXX constants for details. *)
(* *)
(* style_flags :: A set of bit flags indicating the style of *)
(* the face (i.e., italic, bold, underline, *)
(* etc). See the @FT_STYLE_FLAG_XXX *)
(* constants. *)
(* *)
(* num_glyphs :: The total number of glyphs in the face. *)
(* *)
(* family_name :: The face's family name. This is an ASCII *)
(* string, usually in English, which describes *)
(* the typeface's family (like `Times New *)
(* Roman', `Bodoni', `Garamond', etc). This *)
(* is a least common denominator used to list *)
(* fonts. Some formats (TrueType & OpenType) *)
(* provide localized and Unicode versions of *)
(* this string. Applications should use the *)
(* format specific interface to access them. *)
(* *)
(* style_name :: The face's style name. This is an ASCII *)
(* string, usually in English, which describes *)
(* the typeface's style (like `Italic', *)
(* `Bold', `Condensed', etc). Not all font *)
(* formats provide a style name, so this field *)
(* is optional, and can be set to NULL. As *)
(* for `family_name', some formats provide *)
(* localized/Unicode versions of this string. *)
(* Applications should use the format specific *)
(* interface to access them. *)
(* *)
(* num_fixed_sizes :: The number of fixed sizes available in this *)
(* face. This should be set to 0 for scalable *)
(* fonts, unless its face includes a set of *)
(* glyphs (called a `strike') for the *)
(* specified sizes. *)
(* *)
(* available_sizes :: An array of sizes specifying the available *)
(* bitmap/graymap sizes that are contained in *)
(* in the font face. Should be set to NULL if *)
(* the field `num_fixed_sizes' is set to 0. *)
(* *)
(* num_charmaps :: The total number of character maps in the *)
(* face. *)
(* *)
(* charmaps :: A table of pointers to the face's charmaps. *)
(* Used to scan the list of available charmaps *)
(* -- this table might change after a call to *)
(* @FT_Attach_File or @FT_Attach_Stream (e.g. *)
(* if used to hook an additional encoding or *)
(* CMap to the face object). *)
(* *)
(* generic :: A field reserved for client uses. See the *)
(* @FT_Generic type description. *)
(* *)
(* bbox :: The font bounding box. Coordinates are *)
(* expressed in font units (see units_per_EM). *)
(* The box is large enough to contain any *)
(* glyph from the font. Thus, bbox.yMax can *)
(* be seen as the `maximal ascender', *)
(* bbox.yMin as the `minimal descender', and *)
(* the maximal glyph width is given by *)
(* `bbox.xMax-bbox.xMin' (not to be confused *)
(* with the maximal _advance_width_). Only *)
(* relevant for scalable formats. *)
(* *)
(* units_per_EM :: The number of font units per EM square for *)
(* this face. This is typically 2048 for *)
(* TrueType fonts, 1000 for Type1 fonts, and *)
(* should be set to the (unrealistic) value 1 *)
(* for fixed-sizes fonts. Only relevant for *)
(* scalable formats. *)
(* *)
(* ascender :: The face's ascender is the vertical *)
(* distance from the baseline to the topmost *)
(* point of any glyph in the face. This *)
(* field's value is positive, expressed in *)
(* font units. Some font designs use a value *)
(* different from `bbox.yMax'. Only relevant *)
(* for scalable formats. *)
(* *)
(* descender :: The face's descender is the vertical *)
(* distance from the baseline to the *)
(* bottommost point of any glyph in the face. *)
(* This field's value is *negative* for values *)
(* below the baseline. It is expressed in *)
(* font units. Some font designs use a value *)
(* different from `bbox.yMin'. Only relevant *)
(* for scalable formats. *)
(* *)
(* height :: The face's height is the vertical distance *)
(* from one baseline to the next when writing *)
(* several lines of text. Its value is always *)
(* positive, expressed in font units. The *)
(* value can be computed as *)
(* `ascender+descender+line_gap' where the *)
(* value of `line_gap' is also called *)
(* `external leading'. Only relevant for *)
(* scalable formats. *)
(* *)
(* max_advance_width :: The maximal advance width, in font units, *)
(* for all glyphs in this face. This can be *)
(* used to make word wrapping computations *)
(* faster. Only relevant for scalable *)
(* formats. *)
(* *)
(* max_advance_height :: The maximal advance height, in font units, *)
(* for all glyphs in this face. This is only *)
(* relevant for vertical layouts, and should *)
(* be set to the `height' for fonts that do *)
(* not provide vertical metrics. Only *)
(* relevant for scalable formats. *)
(* *)
(* underline_position :: The position, in font units, of the *)
(* underline line for this face. It's the *)
(* center of the underlining stem. Only *)
(* relevant for scalable formats. *)
(* *)
(* underline_thickness :: The thickness, in font units, of the *)
(* underline for this face. Only relevant for *)
(* scalable formats. *)
(* *)
(* glyph :: The face's associated glyph slot(s). This *)
(* object is created automatically with a new *)
(* face object. However, certain kinds of *)
(* applications (mainly tools like converters) *)
(* can need more than one slot to ease their *)
(* task. *)
(* *)
(* size :: The current active size for this face. *)
(* *)
(* charmap :: The current active charmap for this face. *)
(* *)
FT_FaceRec = record
num_faces : FT_Long;
face_index : FT_Long;
face_flags : FT_Long;
style_flags : FT_Long;
num_glyphs : FT_Long;
family_name : PFT_String;
style_name : PFT_String;
num_fixed_sizes : FT_Int;
available_sizes : PAFT_Bitmap_Size; // is array
num_charmaps : FT_Int;
charmaps : PAFT_CharMap; // is array
generic : FT_Generic;
(*# the following are only relevant to scalable outlines *)
bbox : FT_BBox;
units_per_EM : FT_UShort;
ascender : FT_Short;
descender : FT_Short;
height : FT_Short;
max_advance_width : FT_Short;
max_advance_height : FT_Short;
underline_position : FT_Short;
underline_thickness : FT_Short;
glyph : FT_GlyphSlot;
size : FT_Size;
charmap : FT_CharMap;
end;
(*************************************************************************)
(* *)
(* <Struct> *)
(* FT_CharMapRec *)
(* *)
(* <Description> *)
(* The base charmap structure. *)
(* *)
(* <Fields> *)
(* face :: A handle to the parent face object. *)
(* *)
(* encoding :: An @FT_Encoding tag identifying the charmap. Use *)
(* this with @FT_Select_Charmap. *)
(* *)
(* platform_id :: An ID number describing the platform for the *)
(* following encoding ID. This comes directly from *)
(* the TrueType specification and should be emulated *)
(* for other formats. *)
(* *)
(* encoding_id :: A platform specific encoding number. This also *)
(* comes from the TrueType specification and should be *)
(* emulated similarly. *)
(* *)
FT_CharMapRec = record
face : FT_Face;
encoding : FT_Encoding;
platform_id : FT_UShort;
encoding_id : FT_UShort;
end;
{ GLOBAL PROCEDURES }
(*************************************************************************)
(* *)
(* @macro: *)
(* FT_CURVE_TAG ( flag ) *)
(* *)
function FT_CURVE_TAG(flag: byte): byte;
const
FT_CURVE_TAG_ON = 1;
FT_CURVE_TAG_CONIC = 0;
FT_CURVE_TAG_CUBIC = 2;
(*************************************************************************)
(* *)
(* @macro: *)
(* FT_IS_SCALABLE( face ) *)
(* *)
(* @description: *)
(* A macro that returns true whenever a face object contains a *)
(* scalable font face (true for TrueType, Type 1, CID, and *)
(* OpenType/CFF font formats. *)
(* *)
function FT_IS_SCALABLE(face : FT_Face ) : cbool;
(*************************************************************************)
(* *)
(* @macro: *)
(* FT_HAS_KERNING( face ) *)
(* *)
(* @description: *)
(* A macro that returns true whenever a face object contains kerning *)
(* data that can be accessed with @FT_Get_Kerning. *)
(* *)
function FT_HAS_KERNING(face : FT_Face ) : cbool;
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Init_FreeType *)
(* *)
(* <Description> *)
(* Initializes a new FreeType library object. The set of modules *)
(* that are registered by this function is determined at build time. *)
(* *)
(* <Output> *)
(* alibrary :: A handle to a new library object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
function FT_Init_FreeType(out alibrary : FT_Library ) : FT_Error;
cdecl; external ft_lib name 'FT_Init_FreeType';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Done_FreeType *)
(* *)
(* <Description> *)
(* Destroys a given FreeType library object and all of its childs, *)
(* including resources, drivers, faces, sizes, etc. *)
(* *)
(* <Input> *)
(* library :: A handle to the target library object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
function FT_Done_FreeType(alibrary : FT_Library ) : FT_Error;
cdecl; external ft_lib name 'FT_Done_FreeType';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Attach_File *)
(* *)
(* <Description> *)
(* `Attaches' a given font file to an existing face. This is usually *)
(* to read additional information for a single face object. For *)
(* example, it is used to read the AFM files that come with Type 1 *)
(* fonts in order to add kerning data and other metrics. *)
(* *)
(* <InOut> *)
(* face :: The target face object. *)
(* *)
(* <Input> *)
(* filepathname :: An 8-bit pathname naming the `metrics' file. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* If your font file is in memory, or if you want to provide your *)
(* own input stream object, use @FT_Attach_Stream. *)
(* *)
(* The meaning of the `attach' action (i.e., what really happens when *)
(* the new file is read) is not fixed by FreeType itself. It really *)
(* depends on the font format (and thus the font driver). *)
(* *)
(* Client applications are expected to know what they are doing *)
(* when invoking this function. Most drivers simply do not implement *)
(* file attachments. *)
(* *)
function FT_Attach_File(face : FT_Face; filepathname : PChar ) : FT_Error;
cdecl; external ft_lib name 'FT_Attach_File';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_New_Memory_Face *)
(* *)
(* <Description> *)
(* Creates a new face object from a given resource and typeface index *)
(* using a font file already loaded into memory. *)
(* *)
(* <InOut> *)
(* library :: A handle to the library resource. *)
(* *)
(* <Input> *)
(* file_base :: A pointer to the beginning of the font data. *)
(* *)
(* file_size :: The size of the memory chunk used by the font data. *)
(* *)
(* face_index :: The index of the face within the resource. The *)
(* first face has index 0. *)
(* *)
(* <Output> *)
(* aface :: A handle to a new face object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* The font data bytes are used _directly_ by the @FT_Face object. *)
(* This means that they are not copied, and that the client is *)
(* responsible for releasing/destroying them _after_ the *)
(* corresponding call to @FT_Done_Face . *)
(* *)
(* Unlike FreeType 1.x, this function automatically creates a glyph *)
(* slot for the face object which can be accessed directly through *)
(* `face->glyph'. *)
(* *)
(* @FT_New_Memory_Face can be used to determine and/or check the font *)
(* format of a given font resource. If the `face_index' field is *)
(* negative, the function will _not_ return any face handle in *)
(* `aface'; the return value is 0 if the font format is recognized, *)
(* or non-zero otherwise. *)
(* *)
function FT_New_Memory_Face(
library_ : FT_Library;
file_base : PFT_Byte;
file_size ,
face_index : FT_Long;
out aface : FT_Face ) : FT_Error;
cdecl; external ft_lib name 'FT_New_Memory_Face';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_New_Face *)
(* *)
(* <Description> *)
(* Creates a new face object from a given resource and typeface index *)
(* using a pathname to the font file. *)
(* *)
(* <InOut> *)
(* library :: A handle to the library resource. *)
(* *)
(* <Input> *)
(* pathname :: A path to the font file. *)
(* *)
(* face_index :: The index of the face within the resource. The *)
(* first face has index 0. *)
(* *)
(* <Output> *)
(* aface :: A handle to a new face object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* Unlike FreeType 1.x, this function automatically creates a glyph *)
(* slot for the face object which can be accessed directly through *)
(* `face->glyph'. *)
(* *)
(* @FT_New_Face can be used to determine and/or check the font format *)
(* of a given font resource. If the `face_index' field is negative, *)
(* the function will _not_ return any face handle in `aface'; the *)
(* return value is 0 if the font format is recognized, or non-zero *)
(* otherwise. *)
(* *)
(* Each new face object created with this function also owns a *)
(* default @FT_Size object, accessible as `face->size'. *)
(* *)
function FT_New_Face(
library_ : FT_Library;
filepathname : PChar;
face_index : FT_Long;
out aface : FT_Face ) : FT_Error;
cdecl; external ft_lib name 'FT_New_Face';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Done_Face *)
(* *)
(* <Description> *)
(* Discards a given face object, as well as all of its child slots *)
(* and sizes. *)
(* *)
(* <Input> *)
(* face :: A handle to a target face object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
function FT_Done_Face(face : FT_Face ) : FT_Error;
cdecl; external ft_lib name 'FT_Done_Face';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Select_Charmap *)
(* *)
(* <Description> *)
(* Selects a given charmap by its encoding tag (as listed in *)
(* `freetype.h'). *)
(* *)
(* <InOut> *)
(* face :: A handle to the source face object. *)
(* *)
(* <Input> *)
(* encoding :: A handle to the selected charmap. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* This function will return an error if no charmap in the face *)
(* corresponds to the encoding queried here. *)
(* *)
function FT_Select_Charmap(face : FT_Face; encoding : FT_Encoding ) : FT_Error;
cdecl; external ft_lib name 'FT_Select_Charmap';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Get_Char_Index *)
(* *)
(* <Description> *)
(* Returns the glyph index of a given character code. This function *)
(* uses a charmap object to do the translation. *)
(* *)
(* <Input> *)
(* face :: A handle to the source face object. *)
(* *)
(* charcode :: The character code. *)
(* *)
(* <Return> *)
(* The glyph index. 0 means `undefined character code'. *)
(* *)
(* <Note> *)
(* FreeType computes its own glyph indices which are not necessarily *)
(* the same as used in the font in case the font is based on glyph *)
(* indices. Reason for this behaviour is to assure that index 0 is *)
(* never used, representing the missing glyph. *)
(* *)
function FT_Get_Char_Index(face : FT_Face; charcode : FT_ULong ) : FT_UInt;
cdecl; external ft_lib name 'FT_Get_Char_Index';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Load_Glyph *)
(* *)
(* <Description> *)
(* A function used to load a single glyph within a given glyph slot, *)
(* for a given size. *)
(* *)
(* <InOut> *)
(* face :: A handle to the target face object where the glyph *)
(* will be loaded. *)
(* *)
(* <Input> *)
(* glyph_index :: The index of the glyph in the font file. For *)
(* CID-keyed fonts (either in PS or in CFF format) *)
(* this argument specifies the CID value. *)
(* *)
(* load_flags :: A flag indicating what to load for this glyph. The *)
(* @FT_LOAD_XXX constants can be used to control the *)
(* glyph loading process (e.g., whether the outline *)
(* should be scaled, whether to load bitmaps or not, *)
(* whether to hint the outline, etc). *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* If the glyph image is not a bitmap, and if the bit flag *)
(* FT_LOAD_IGNORE_TRANSFORM is unset, the glyph image will be *)
(* transformed with the information passed to a previous call to *)
(* @FT_Set_Transform. *)
(* *)
(* Note that this also transforms the `face.glyph.advance' field, but *)
(* *not* the values in `face.glyph.metrics'. *)
(* *)
function FT_Load_Glyph(
face : FT_Face;
glyph_index : FT_UInt ;
load_flags : FT_Int32 ) : FT_Error;
cdecl; external ft_lib name 'FT_Load_Glyph';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Render_Glyph *)
(* *)
(* <Description> *)
(* Converts a given glyph image to a bitmap. It does so by *)
(* inspecting the glyph image format, find the relevant renderer, and *)
(* invoke it. *)
(* *)
(* <InOut> *)
(* slot :: A handle to the glyph slot containing the image to *)
(* convert. *)
(* *)
(* <Input> *)
(* render_mode :: This is the render mode used to render the glyph *)
(* image into a bitmap. See FT_Render_Mode for a list *)
(* of possible values. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
function FT_Render_Glyph(slot : FT_GlyphSlot; render_mode : FT_Render_Mode ) : FT_Error;
cdecl; external ft_lib name 'FT_Render_Glyph';
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Kerning_Mode *)
(* *)
(* <Description> *)
(* An enumeration used to specify which kerning values to return in *)
(* @FT_Get_Kerning. *)
(* *)
(* <Values> *)
(* FT_KERNING_DEFAULT :: Return scaled and grid-fitted kerning *)
(* distances (value is 0). *)
(* *)
(* FT_KERNING_UNFITTED :: Return scaled but un-grid-fitted kerning *)
(* distances. *)
(* *)
(* FT_KERNING_UNSCALED :: Return the kerning vector in original font *)
(* units. *)
(* *)
const
FT_KERNING_DEFAULT = 0;
FT_KERNING_UNFITTED = 1;
FT_KERNING_UNSCALED = 2;
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Get_Kerning *)
(* *)
(* <Description> *)
(* Returns the kerning vector between two glyphs of a same face. *)
(* *)
(* <Input> *)
(* face :: A handle to a source face object. *)
(* *)
(* left_glyph :: The index of the left glyph in the kern pair. *)
(* *)
(* right_glyph :: The index of the right glyph in the kern pair. *)
(* *)
(* kern_mode :: See @FT_Kerning_Mode for more information. *)
(* Determines the scale/dimension of the returned *)
(* kerning vector. *)
(* *)
(* <Output> *)
(* akerning :: The kerning vector. This is in font units for *)
(* scalable formats, and in pixels for fixed-sizes *)
(* formats. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* Only horizontal layouts (left-to-right & right-to-left) are *)
(* supported by this method. Other layouts, or more sophisticated *)
(* kernings, are out of the scope of this API function -- they can be *)
(* implemented through format-specific interfaces. *)
(* *)
function FT_Get_Kerning(
face : FT_Face;
left_glyph ,
right_glyph ,
kern_mode : FT_UInt;
out akerning : FT_Vector ) : FT_Error;
cdecl; external ft_lib name 'FT_Get_Kerning';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Set_Char_Size *)
(* *)
(* <Description> *)
(* Sets the character dimensions of a given face object. The *)
(* `char_width' and `char_height' values are used for the width and *)
(* height, respectively, expressed in 26.6 fractional points. *)
(* *)
(* If the horizontal or vertical resolution values are zero, a *)
(* default value of 72dpi is used. Similarly, if one of the *)
(* character dimensions is zero, its value is set equal to the other. *)
(* *)
(* <InOut> *)
(* face :: A handle to a target face object. *)
(* *)
(* <Input> *)
(* char_width :: The character width, in 26.6 fractional points. *)
(* *)
(* char_height :: The character height, in 26.6 fractional *)
(* points. *)
(* *)
(* horz_resolution :: The horizontal resolution. *)
(* *)
(* vert_resolution :: The vertical resolution. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* When dealing with fixed-size faces (i.e., non-scalable formats), *)
(* @FT_Set_Pixel_Sizes provides a more convenient interface. *)
(* *)
function FT_Set_Char_Size(
face : FT_Face;
char_width ,
char_height : FT_F26dot6;
horz_res ,
vert_res : FT_UInt) : FT_Error;
cdecl; external ft_lib name 'FT_Set_Char_Size';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Set_Pixel_Sizes *)
(* *)
(* <Description> *)
(* Sets the character dimensions of a given face object. The width *)
(* and height are expressed in integer pixels. *)
(* *)
(* If one of the character dimensions is zero, its value is set equal *)
(* to the other. *)
(* *)
(* <InOut> *)
(* face :: A handle to the target face object. *)
(* *)
(* <Input> *)
(* pixel_width :: The character width, in integer pixels. *)
(* *)
(* pixel_height :: The character height, in integer pixels. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* The values of `pixel_width' and `pixel_height' correspond to the *)
(* pixel values of the _typographic_ character size, which are NOT *)
(* necessarily the same as the dimensions of the glyph `bitmap *)
(* cells'. *)
(* *)
(* The `character size' is really the size of an abstract square *)
(* called the `EM', used to design the font. However, depending *)
(* on the font design, glyphs will be smaller or greater than the *)
(* EM. *)
(* *)
(* This means that setting the pixel size to, say, 8x8 doesn't *)
(* guarantee in any way that you will get glyph bitmaps that all fit *)
(* within an 8x8 cell (sometimes even far from it). *)
(* *)
(* For bitmap fonts, `pixel_height' usually is a reliable value for *)
(* the height of the bitmap cell. Drivers for bitmap font formats *)
(* which contain a single bitmap strike only (BDF, PCF, FNT) ignore *)
(* `pixel_width'. *)
(* *)
function FT_Set_Pixel_Sizes(
face : FT_Face;
pixel_width ,
pixel_height : FT_UInt ) : FT_Error;
cdecl; external ft_lib name 'FT_Set_Pixel_Sizes';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Get_Glyph *)
(* *)
(* <Description> *)
(* A function used to extract a glyph image from a slot. *)
(* *)
(* <Input> *)
(* slot :: A handle to the source glyph slot. *)
(* *)
(* <Output> *)
(* aglyph :: A handle to the glyph object. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
function FT_Get_Glyph(
slot: FT_GlyphSlot;
out aglyph: FT_Glyph ): FT_Error;
cdecl; external ft_lib name 'FT_Get_Glyph';
(*************************************************************************)
(* *)
(* <Enum> *)
(* FT_Glyph_BBox_Mode *)
(* *)
(* <Description> *)
(* The mode how the values of @FT_Glyph_Get_CBox are returned. *)
(* *)
(* <Values> *)
(* FT_GLYPH_BBOX_UNSCALED :: *)
(* Return unscaled font units. *)
(* *)
(* FT_GLYPH_BBOX_SUBPIXELS :: *)
(* Return unfitted 26.6 coordinates. *)
(* *)
(* FT_GLYPH_BBOX_GRIDFIT :: *)
(* Return grid-fitted 26.6 coordinates. *)
(* *)
(* FT_GLYPH_BBOX_TRUNCATE :: *)
(* Return coordinates in integer pixels. *)
(* *)
(* FT_GLYPH_BBOX_PIXELS :: *)
(* Return grid-fitted pixel coordinates. *)
(* *)
type
FT_Glyph_BBox_Mode = FT_UInt;
const
FT_GLYPH_BBOX_UNSCALED = 0;
FT_GLYPH_BBOX_SUBPIXELS = 0;
FT_GLYPH_BBOX_GRIDFIT = 1;
FT_GLYPH_BBOX_TRUNCATE = 2;
FT_GLYPH_BBOX_PIXELS = 3;
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Glyph_Get_CBox *)
(* *)
(* <Description> *)
(* Return a glyph's `control box'. The control box encloses all the *)
(* outline's points, including B�zier control points. Though it *)
(* coincides with the exact bounding box for most glyphs, it can be *)
(* slightly larger in some situations (like when rotating an outline *)
(* which contains B�zier outside arcs). *)
(* *)
(* Computing the control box is very fast, while getting the bounding *)
(* box can take much more time as it needs to walk over all segments *)
(* and arcs in the outline. To get the latter, you can use the *)
(* `ftbbox' component which is dedicated to this single task. *)
(* *)
(* <Input> *)
(* glyph :: A handle to the source glyph object. *)
(* *)
(* mode :: The mode which indicates how to interpret the returned *)
(* bounding box values. *)
(* *)
(* <Output> *)
(* acbox :: The glyph coordinate bounding box. Coordinates are *)
(* expressed in 1/64th of pixels if it is grid-fitted. *)
(* *)
(* <Note> *)
(* Coordinates are relative to the glyph origin, using the Y-upwards *)
(* convention. *)
(* *)
(* If the glyph has been loaded with @FT_LOAD_NO_SCALE, `bbox_mode' *)
(* must be set to @FT_GLYPH_BBOX_UNSCALED to get unscaled font *)
(* units in 26.6 pixel format. The value @FT_GLYPH_BBOX_SUBPIXELS *)
(* is another name for this constant. *)
(* *)
(* Note that the maximum coordinates are exclusive, which means that *)
(* one can compute the width and height of the glyph image (be it in *)
(* integer or 26.6 pixels) as: *)
(* *)
(* { *)
(* width = bbox.xMax - bbox.xMin; *)
(* height = bbox.yMax - bbox.yMin; *)
(* } *)
(* *)
(* Note also that for 26.6 coordinates, if `bbox_mode' is set to *)
(* @FT_GLYPH_BBOX_GRIDFIT, the coordinates will also be grid-fitted, *)
(* which corresponds to: *)
(* *)
(* { *)
(* bbox.xMin = FLOOR(bbox.xMin); *)
(* bbox.yMin = FLOOR(bbox.yMin); *)
(* bbox.xMax = CEILING(bbox.xMax); *)
(* bbox.yMax = CEILING(bbox.yMax); *)
(* } *)
(* *)
(* To get the bbox in pixel coordinates, set `bbox_mode' to *)
(* @FT_GLYPH_BBOX_TRUNCATE. *)
(* *)
(* To get the bbox in grid-fitted pixel coordinates, set `bbox_mode' *)
(* to @FT_GLYPH_BBOX_PIXELS. *)
(* *)
procedure FT_Glyph_Get_CBox( glyph: FT_Glyph;
bbox_mode: FT_UInt;
out acbox: FT_BBox );
cdecl; external ft_lib name 'FT_Glyph_Get_CBox';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Glyph_To_Bitmap *)
(* *)
(* <Description> *)
(* Converts a given glyph object to a bitmap glyph object. *)
(* *)
(* <InOut> *)
(* the_glyph :: A pointer to a handle to the target glyph. *)
(* *)
(* <Input> *)
(* render_mode :: An enumeration that describe how the data is *)
(* rendered. *)
(* *)
(* origin :: A pointer to a vector used to translate the glyph *)
(* image before rendering. Can be 0 (if no *)
(* translation). The origin is expressed in *)
(* 26.6 pixels. *)
(* *)
(* destroy :: A boolean that indicates that the original glyph *)
(* image should be destroyed by this function. It is *)
(* never destroyed in case of error. *)
(* *)
(* <Return> *)
(* FreeType error code. 0 means success. *)
(* *)
(* <Note> *)
(* The glyph image is translated with the `origin' vector before *)
(* rendering. *)
(* *)
(* The first parameter is a pointer to a FT_Glyph handle, that will *)
(* be replaced by this function. Typically, you would use (omitting *)
(* error handling): *)
(* *)
(* *)
(* { *)
(* FT_Glyph glyph; *)
(* FT_BitmapGlyph glyph_bitmap; *)
(* *)
(* *)
(* // load glyph *)
(* error = FT_Load_Char( face, glyph_index, FT_LOAD_DEFAUT ); *)
(* *)
(* // extract glyph image *)
(* error = FT_Get_Glyph( face->glyph, &glyph ); *)
(* *)
(* // convert to a bitmap (default render mode + destroy old) *)
(* if ( glyph->format != FT_GLYPH_FORMAT_BITMAP ) *)
(* { *)
(* error = FT_Glyph_To_Bitmap( &glyph, FT_RENDER_MODE_DEFAULT, *)
(* 0, 1 ); *)
(* if ( error ) // glyph unchanged *)
(* ... *)
(* } *)
(* *)
(* // access bitmap content by typecasting *)
(* glyph_bitmap = (FT_BitmapGlyph)glyph; *)
(* *)
(* // do funny stuff with it, like blitting/drawing *)
(* ... *)
(* *)
(* // discard glyph image (bitmap or not) *)
(* FT_Done_Glyph( glyph ); *)
(* } *)
(* *)
(* *)
(* This function does nothing if the glyph format isn't scalable. *)
(* *)
function FT_Glyph_To_Bitmap(var the_glyph: FT_Glyph;
render_mode: FT_Render_Mode;
origin: PFT_Vector;
destroy: FT_Bool ): FT_Error;
cdecl; external ft_lib name 'FT_Glyph_To_Bitmap';
(*************************************************************************)
(* *)
(* <Function> *)
(* FT_Done_Glyph *)
(* *)
(* <Description> *)
(* Destroys a given glyph. *)
(* *)
(* <Input> *)
(* glyph :: A handle to the target glyph object. *)
(* *)
procedure FT_Done_Glyph( glyph: FT_Glyph );
cdecl; external ft_lib name 'FT_Done_Glyph';
implementation
{ FT_CURVE_TAG }
function FT_CURVE_TAG(flag: byte): byte;
begin
result := flag and 3;
end;
{ FT_IS_SCALABLE }
function FT_IS_SCALABLE(face : FT_Face ) : cbool;
begin
result := cbool(face.face_flags and FT_FACE_FLAG_SCALABLE );
end;
{ FT_HAS_KERNING }
function FT_HAS_KERNING(face : FT_Face ) : cbool;
begin
result := cbool(face.face_flags and FT_FACE_FLAG_KERNING );
end;
end.