blob: 96aaffa25c150c2f30d54b246252161917515c88 [file] [log] [blame]
/*******************************************************************
*
* ftxgsub.c
*
* TrueType Open GSUB table support.
*
* Copyright 1996-2000 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.
*
******************************************************************/
/* XXX There is *a lot* of duplicated code (cf. formats 5 and 6), but
I don't care currently. I believe that it would be possible to
save about 50% of TTO code by carefully designing the structures,
sharing as much as possible with extensive use of macros. This
is something for a volunteer :-) */
#define EXPORT_FUNC
#include "ftxopen.h"
#include "ftxopenf.h"
#include "fterrcompat.h"
#include FT_TRUETYPE_TAGS_H
#include FT_INTERNAL_STREAM_H
#include FT_INTERNAL_MEMORY_H
#include FT_INTERNAL_TRUETYPE_TYPES_H
#define GSUB_ID Build_Extension_ID( 'G', 'S', 'U', 'B' )
#define ADD_String( in, num_in, out, num_out, glyph_data, component, ligID ) \
( ( error = TT_GSUB_Add_String( (in), (num_in), \
(out), (num_out), \
(glyph_data), (component), (ligID) \
) ) != TT_Err_Ok )
static FT_Error Do_Glyph_Lookup( TTO_GSUBHeader* gsub,
FT_UShort lookup_index,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort context_length,
int nesting_level );
/**********************
* Auxiliary functions
**********************/
/* The following function copies `num_out' elements from `glyph_data'
to `out', advancing the array pointer in the `in' structure by
`num_in' elements, and in `out' by `num_out' elements. If the
string (resp. the properties) array in `out' is empty or too
small, it allocates resp. reallocates the string (and properties)
array. Finally, it sets the `length' field of `out' equal to
`pos' of the `out' structure.
If `component' is 0xFFFF, the value `in->component[in->pos]'
will be copied `num_out' times, otherwise `component' itself will
be used to fill `out->component'.
If `ligID' is 0xFFFF, the value `in->lig_IDs[in->pos]' will be
copied `num_out' times, otherwise `ligID' itself will be used to
fill `out->ligIDs'.
The properties (if defined) for all replaced glyphs are taken
from the glyph at position `in->pos'.
The logClusters[] value for the glyph at position in->pos is used
for all replacement glyphs */
EXPORT_FUNC
FT_Error TT_GSUB_Add_String( TTO_GSUB_String* in,
FT_UShort num_in,
TTO_GSUB_String* out,
FT_UShort num_out,
FT_UShort* glyph_data,
FT_UShort component,
FT_UShort ligID )
{
FT_Memory memory = in->memory;
FT_Error error;
FT_UShort i;
FT_UShort p_in;
FT_UShort*p_out;
/* sanity check */
if ( !in || !out ||
in->length == 0 || in->pos >= in->length ||
in->length < in->pos + num_in )
return TT_Err_Invalid_Argument;
if ( out->pos + num_out >= out->allocated )
{
FT_ULong size = out->pos + num_out + 256L;
/* The following works because all fields in `out' must be
initialized to zero (including the `string' field) for the
first use. */
if ( REALLOC_ARRAY( out->string, out->allocated, size, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( out->components, out->allocated, size, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( out->ligIDs, out->allocated, size, FT_UShort ) )
return error;
if ( in->properties )
if ( REALLOC_ARRAY( out->properties, out->allocated, size, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( out->logClusters, out->allocated, size, FT_Int ) )
return error;
out->allocated = size;
}
if ( num_out )
{
MEM_Copy( &out->string[out->pos], glyph_data,
num_out * sizeof ( FT_UShort ) );
if ( component == 0xFFFF )
component = in->components[in->pos];
p_out = out->components;
for ( i = out->pos; i < out->pos + num_out; i++ )
p_out[i] = component;
p_out = out->ligIDs;
if ( ligID == 0xFFFF )
ligID = in->ligIDs[in->pos];
for ( i = out->pos; i < out->pos + num_out; i++ )
p_out[i] = ligID;
if ( in->properties )
{
p_in = in->properties[in->pos];
p_out = out->properties;
for ( i = out->pos; i < out->pos + num_out; i++ )
p_out[i] = p_in;
}
for ( i = out->pos; i < out->pos + num_out; i++ )
out->logClusters[i] = in->logClusters[in->pos];
}
in->pos += num_in;
out->pos += num_out;
out->length = out->pos;
return TT_Err_Ok;
}
#if 0
/**********************
* Extension Functions
**********************/
static FT_Error GSUB_Create( void* ext,
PFace face )
{
DEFINE_LOAD_LOCALS( face->stream );
TTO_GSUBHeader* gsub = (TTO_GSUBHeader*)ext;
Long table;
/* by convention */
if ( !gsub )
return TT_Err_Ok;
/* a null offset indicates that there is no GSUB table */
gsub->offset = 0;
/* we store the start offset and the size of the subtable */
table = TT_LookUp_Table( face, TTAG_GSUB );
if ( table < 0 )
return TT_Err_Ok; /* The table is optional */
if ( FILE_Seek( face->dirTables[table].Offset ) ||
ACCESS_Frame( 4L ) )
return error;
gsub->offset = FILE_Pos() - 4L; /* undo ACCESS_Frame() */
gsub->Version = GET_ULong();
FORGET_Frame();
gsub->loaded = FALSE;
return TT_Err_Ok;
}
static FT_Error GSUB_Destroy( void* ext,
PFace face )
{
TTO_GSUBHeader* gsub = (TTO_GSUBHeader*)ext;
/* by convention */
if ( !gsub )
return TT_Err_Ok;
if ( gsub->loaded )
{
Free_LookupList( &gsub->LookupList, GSUB, memory );
Free_FeatureList( &gsub->FeatureList, memory );
Free_ScriptList( &gsub->ScriptList, memory );
}
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_Init_GSUB_Extension( TT_Engine engine )
{
PEngine_Instance _engine = HANDLE_Engine( engine );
if ( !_engine )
return TT_Err_Invalid_Engine;
return TT_Register_Extension( _engine,
GSUB_ID,
sizeof ( TTO_GSUBHeader ),
GSUB_Create,
GSUB_Destroy );
}
#endif
EXPORT_FUNC
FT_Error TT_Load_GSUB_Table( FT_Face face,
TTO_GSUBHeader** retptr,
TTO_GDEFHeader* gdef )
{
FT_Stream stream = face->stream;
FT_Memory memory = face->memory;
FT_Error error;
FT_ULong cur_offset, new_offset, base_offset;
TT_Face tt_face = (TT_Face)face;
FT_UShort i, num_lookups;
TTO_GSUBHeader* gsub;
TTO_Lookup* lo;
if ( !retptr )
return TT_Err_Invalid_Argument;
if (( error = tt_face->goto_table( tt_face, TTAG_GSUB, stream, 0 ) ))
return error;
base_offset = FILE_Pos();
if ( ALLOC ( gsub, sizeof( *gsub ) ) )
return error;
gsub->memory = memory;
/* skip version */
if ( FILE_Seek( base_offset + 4L ) ||
ACCESS_Frame( 2L ) )
goto Fail4;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ScriptList( &gsub->ScriptList,
stream ) ) != TT_Err_Ok )
goto Fail4;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail3;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_FeatureList( &gsub->FeatureList,
stream ) ) != TT_Err_Ok )
goto Fail3;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_LookupList( &gsub->LookupList,
stream, GSUB ) ) != TT_Err_Ok )
goto Fail2;
gsub->gdef = gdef; /* can be NULL */
/* We now check the LookupFlags for values larger than 0xFF to find
out whether we need to load the `MarkAttachClassDef' field of the
GDEF table -- this hack is necessary for OpenType 1.2 tables since
the version field of the GDEF table hasn't been incremented.
For constructed GDEF tables, we only load it if
`MarkAttachClassDef_offset' is not zero (nevertheless, a build of
a constructed mark attach table is not supported currently). */
if ( gdef &&
gdef->MarkAttachClassDef_offset && !gdef->MarkAttachClassDef.loaded )
{
lo = gsub->LookupList.Lookup;
num_lookups = gsub->LookupList.LookupCount;
for ( i = 0; i < num_lookups; i++ )
{
if ( lo[i].LookupFlag & IGNORE_SPECIAL_MARKS )
{
if ( FILE_Seek( gdef->MarkAttachClassDef_offset ) ||
( error = Load_ClassDefinition( &gdef->MarkAttachClassDef,
256, stream ) ) != TT_Err_Ok )
goto Fail1;
break;
}
}
}
*retptr = gsub;
return TT_Err_Ok;
Fail1:
Free_LookupList( &gsub->LookupList, GSUB, memory );
Fail2:
Free_FeatureList( &gsub->FeatureList, memory );
Fail3:
Free_ScriptList( &gsub->ScriptList, memory );
Fail4:
FREE ( gsub );
return error;
}
EXPORT_FUNC
FT_Error TT_Done_GSUB_Table( TTO_GSUBHeader* gsub )
{
FT_Memory memory = gsub->memory;
Free_LookupList( &gsub->LookupList, GSUB, memory );
Free_FeatureList( &gsub->FeatureList, memory );
Free_ScriptList( &gsub->ScriptList, memory );
FREE( gsub );
return TT_Err_Ok;
}
/*****************************
* SubTable related functions
*****************************/
/* LookupType 1 */
/* SingleSubstFormat1 */
/* SingleSubstFormat2 */
FT_Error Load_SingleSubst( TTO_SingleSubst* ss,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_ULong cur_offset, new_offset, base_offset;
FT_UShort* s;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 4L ) )
return error;
ss->SubstFormat = GET_UShort();
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &ss->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
switch ( ss->SubstFormat )
{
case 1:
if ( ACCESS_Frame( 2L ) )
goto Fail2;
ss->ssf.ssf1.DeltaGlyphID = GET_UShort();
FORGET_Frame();
break;
case 2:
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = ss->ssf.ssf2.GlyphCount = GET_UShort();
FORGET_Frame();
ss->ssf.ssf2.Substitute = NULL;
if ( ALLOC_ARRAY( ss->ssf.ssf2.Substitute, count, FT_UShort ) )
goto Fail2;
s = ss->ssf.ssf2.Substitute;
if ( ACCESS_Frame( count * 2L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
s[n] = GET_UShort();
FORGET_Frame();
break;
default:
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
return TT_Err_Ok;
Fail1:
FREE( s );
Fail2:
Free_Coverage( &ss->Coverage, memory );
return error;
}
void Free_SingleSubst( TTO_SingleSubst* ss,
FT_Memory memory )
{
switch ( ss->SubstFormat )
{
case 1:
break;
case 2:
FREE( ss->ssf.ssf2.Substitute );
break;
}
Free_Coverage( &ss->Coverage, memory );
}
static FT_Error Lookup_SingleSubst( TTO_SingleSubst* ss,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
TTO_GDEFHeader* gdef )
{
FT_UShort index, value[1], property;
FT_Error error;
if ( context_length != 0xFFFF && context_length < 1 )
return TTO_Err_Not_Covered;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
error = Coverage_Index( &ss->Coverage, in->string[in->pos], &index );
if ( error )
return error;
switch ( ss->SubstFormat )
{
case 1:
value[0] = ( in->string[in->pos] + ss->ssf.ssf1.DeltaGlyphID ) & 0xFFFF;
if ( ADD_String( in, 1, out, 1, value, 0xFFFF, 0xFFFF ) )
return error;
break;
case 2:
if ( index >= ss->ssf.ssf2.GlyphCount )
return TTO_Err_Invalid_GSUB_SubTable;
value[0] = ss->ssf.ssf2.Substitute[index];
if ( ADD_String( in, 1, out, 1, value, 0xFFFF, 0xFFFF ) )
return error;
break;
default:
return TTO_Err_Invalid_GSUB_SubTable;
}
if ( gdef && gdef->NewGlyphClasses )
{
/* we inherit the old glyph class to the substituted glyph */
error = Add_Glyph_Property( gdef, value[0], property );
if ( error && error != TTO_Err_Not_Covered )
return error;
}
return TT_Err_Ok;
}
/* LookupType 2 */
/* Sequence */
static FT_Error Load_Sequence( TTO_Sequence* s,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* sub;
if ( ACCESS_Frame( 2L ) )
return error;
count = s->GlyphCount = GET_UShort();
FORGET_Frame();
s->Substitute = NULL;
if ( count )
{
if ( ALLOC_ARRAY( s->Substitute, count, FT_UShort ) )
return error;
sub = s->Substitute;
if ( ACCESS_Frame( count * 2L ) )
{
FREE( sub );
return error;
}
for ( n = 0; n < count; n++ )
sub[n] = GET_UShort();
FORGET_Frame();
}
return TT_Err_Ok;
}
static void Free_Sequence( TTO_Sequence* s,
FT_Memory memory )
{
FREE( s->Substitute );
}
/* MultipleSubstFormat1 */
FT_Error Load_MultipleSubst( TTO_MultipleSubst* ms,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_Sequence* s;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 4L ) )
return error;
ms->SubstFormat = GET_UShort(); /* should be 1 */
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &ms->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = ms->SequenceCount = GET_UShort();
FORGET_Frame();
ms->Sequence = NULL;
if ( ALLOC_ARRAY( ms->Sequence, count, TTO_Sequence ) )
goto Fail2;
s = ms->Sequence;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Sequence( &s[n], stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_Sequence( &s[m], memory );
FREE( s );
Fail2:
Free_Coverage( &ms->Coverage, memory );
return error;
}
void Free_MultipleSubst( TTO_MultipleSubst* ms,
FT_Memory memory )
{
FT_UShort n, count;
TTO_Sequence* s;
if ( ms->Sequence )
{
count = ms->SequenceCount;
s = ms->Sequence;
for ( n = 0; n < count; n++ )
Free_Sequence( &s[n], memory );
FREE( s );
}
Free_Coverage( &ms->Coverage, memory );
}
static FT_Error Lookup_MultipleSubst( TTO_MultipleSubst* ms,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
TTO_GDEFHeader* gdef )
{
FT_Error error;
FT_UShort index, property, n, count;
FT_UShort*s;
if ( context_length != 0xFFFF && context_length < 1 )
return TTO_Err_Not_Covered;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
error = Coverage_Index( &ms->Coverage, in->string[in->pos], &index );
if ( error )
return error;
if ( index >= ms->SequenceCount )
return TTO_Err_Invalid_GSUB_SubTable;
count = ms->Sequence[index].GlyphCount;
s = ms->Sequence[index].Substitute;
if ( ADD_String( in, 1, out, count, s, 0xFFFF, 0xFFFF ) )
return error;
if ( gdef && gdef->NewGlyphClasses )
{
/* this is a guess only ... */
if ( property == TTO_LIGATURE )
property = TTO_BASE_GLYPH;
for ( n = 0; n < count; n++ )
{
error = Add_Glyph_Property( gdef, s[n], property );
if ( error && error != TTO_Err_Not_Covered )
return error;
}
}
return TT_Err_Ok;
}
/* LookupType 3 */
/* AlternateSet */
static FT_Error Load_AlternateSet( TTO_AlternateSet* as,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* a;
if ( ACCESS_Frame( 2L ) )
return error;
count = as->GlyphCount = GET_UShort();
FORGET_Frame();
as->Alternate = NULL;
if ( ALLOC_ARRAY( as->Alternate, count, FT_UShort ) )
return error;
a = as->Alternate;
if ( ACCESS_Frame( count * 2L ) )
{
FREE( a );
return error;
}
for ( n = 0; n < count; n++ )
a[n] = GET_UShort();
FORGET_Frame();
return TT_Err_Ok;
}
static void Free_AlternateSet( TTO_AlternateSet* as,
FT_Memory memory )
{
FREE( as->Alternate );
}
/* AlternateSubstFormat1 */
FT_Error Load_AlternateSubst( TTO_AlternateSubst* as,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_AlternateSet* aset;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 4L ) )
return error;
as->SubstFormat = GET_UShort(); /* should be 1 */
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &as->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = as->AlternateSetCount = GET_UShort();
FORGET_Frame();
as->AlternateSet = NULL;
if ( ALLOC_ARRAY( as->AlternateSet, count, TTO_AlternateSet ) )
goto Fail2;
aset = as->AlternateSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_AlternateSet( &aset[n], stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_AlternateSet( &aset[m], memory );
FREE( aset );
Fail2:
Free_Coverage( &as->Coverage, memory );
return error;
}
void Free_AlternateSubst( TTO_AlternateSubst* as,
FT_Memory memory )
{
FT_UShort n, count;
TTO_AlternateSet* aset;
if ( as->AlternateSet )
{
count = as->AlternateSetCount;
aset = as->AlternateSet;
for ( n = 0; n < count; n++ )
Free_AlternateSet( &aset[n], memory );
FREE( aset );
}
Free_Coverage( &as->Coverage, memory );
}
static FT_Error Lookup_AlternateSubst( TTO_GSUBHeader* gsub,
TTO_AlternateSubst* as,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
TTO_GDEFHeader* gdef )
{
FT_Error error;
FT_UShort index, alt_index, property;
TTO_AlternateSet aset;
if ( context_length != 0xFFFF && context_length < 1 )
return TTO_Err_Not_Covered;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
error = Coverage_Index( &as->Coverage, in->string[in->pos], &index );
if ( error )
return error;
aset = as->AlternateSet[index];
/* we use a user-defined callback function to get the alternate index */
if ( gsub->altfunc )
alt_index = (gsub->altfunc)( out->pos, in->string[in->pos],
aset.GlyphCount, aset.Alternate,
gsub->data );
else
alt_index = 0;
if ( ADD_String( in, 1, out, 1, &aset.Alternate[alt_index],
0xFFFF, 0xFFFF ) )
return error;
if ( gdef && gdef->NewGlyphClasses )
{
/* we inherit the old glyph class to the substituted glyph */
error = Add_Glyph_Property( gdef, aset.Alternate[alt_index],
property );
if ( error && error != TTO_Err_Not_Covered )
return error;
}
return TT_Err_Ok;
}
/* LookupType 4 */
/* Ligature */
static FT_Error Load_Ligature( TTO_Ligature* l,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* c;
if ( ACCESS_Frame( 4L ) )
return error;
l->LigGlyph = GET_UShort();
l->ComponentCount = GET_UShort();
FORGET_Frame();
l->Component = NULL;
count = l->ComponentCount - 1; /* only ComponentCount - 1 elements */
if ( ALLOC_ARRAY( l->Component, count, FT_UShort ) )
return error;
c = l->Component;
if ( ACCESS_Frame( count * 2L ) )
{
FREE( c );
return error;
}
for ( n = 0; n < count; n++ )
c[n] = GET_UShort();
FORGET_Frame();
return TT_Err_Ok;
}
static void Free_Ligature( TTO_Ligature* l,
FT_Memory memory )
{
FREE( l->Component );
}
/* LigatureSet */
static FT_Error Load_LigatureSet( TTO_LigatureSet* ls,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_Ligature* l;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 2L ) )
return error;
count = ls->LigatureCount = GET_UShort();
FORGET_Frame();
ls->Ligature = NULL;
if ( ALLOC_ARRAY( ls->Ligature, count, TTO_Ligature ) )
return error;
l = ls->Ligature;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Ligature( &l[n], stream ) ) != TT_Err_Ok )
goto Fail;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail:
for ( m = 0; m < n; m++ )
Free_Ligature( &l[m], memory );
FREE( l );
return error;
}
static void Free_LigatureSet( TTO_LigatureSet* ls,
FT_Memory memory )
{
FT_UShort n, count;
TTO_Ligature* l;
if ( ls->Ligature )
{
count = ls->LigatureCount;
l = ls->Ligature;
for ( n = 0; n < count; n++ )
Free_Ligature( &l[n], memory );
FREE( l );
}
}
/* LigatureSubstFormat1 */
FT_Error Load_LigatureSubst( TTO_LigatureSubst* ls,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_LigatureSet* lset;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 4L ) )
return error;
ls->SubstFormat = GET_UShort(); /* should be 1 */
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &ls->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = ls->LigatureSetCount = GET_UShort();
FORGET_Frame();
ls->LigatureSet = NULL;
if ( ALLOC_ARRAY( ls->LigatureSet, count, TTO_LigatureSet ) )
goto Fail2;
lset = ls->LigatureSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_LigatureSet( &lset[n], stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_LigatureSet( &lset[m], memory );
FREE( lset );
Fail2:
Free_Coverage( &ls->Coverage, memory );
return error;
}
void Free_LigatureSubst( TTO_LigatureSubst* ls,
FT_Memory memory )
{
FT_UShort n, count;
TTO_LigatureSet* lset;
if ( ls->LigatureSet )
{
count = ls->LigatureSetCount;
lset = ls->LigatureSet;
for ( n = 0; n < count; n++ )
Free_LigatureSet( &lset[n], memory );
FREE( lset );
}
Free_Coverage( &ls->Coverage, memory );
}
static FT_Error Lookup_LigatureSubst( TTO_LigatureSubst* ls,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
TTO_GDEFHeader* gdef )
{
FT_UShort index, property;
FT_Error error;
FT_UShort numlig, i, j, is_mark, first_is_mark = FALSE;
FT_UShort* s_in;
FT_UShort* c;
TTO_Ligature* lig;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
if ( property == TTO_MARK || property & IGNORE_SPECIAL_MARKS )
first_is_mark = TRUE;
error = Coverage_Index( &ls->Coverage, in->string[in->pos], &index );
if ( error )
return error;
if ( index >= ls->LigatureSetCount )
return TTO_Err_Invalid_GSUB_SubTable;
lig = ls->LigatureSet[index].Ligature;
for ( numlig = ls->LigatureSet[index].LigatureCount;
numlig;
numlig--, lig++ )
{
if ( in->pos + lig->ComponentCount > in->length )
continue; /* Not enough glyphs in input */
s_in = &in->string[in->pos];
c = lig->Component;
is_mark = first_is_mark;
if ( context_length != 0xFFFF && context_length < lig->ComponentCount )
break;
for ( i = 1, j = 1; i < lig->ComponentCount; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( in->pos + j < in->length )
j++;
else
break;
}
if ( !( property == TTO_MARK || property & IGNORE_SPECIAL_MARKS ) )
is_mark = FALSE;
if ( s_in[j] != c[i - 1] )
break;
}
if ( i == lig->ComponentCount )
{
if ( gdef && gdef->NewGlyphClasses )
{
/* this is just a guess ... */
error = Add_Glyph_Property( gdef, lig->LigGlyph,
is_mark ? TTO_MARK : TTO_LIGATURE );
if ( error && error != TTO_Err_Not_Covered )
return error;
}
if ( i == j )
{
/* We don't use a new ligature ID if there are no skipped
glyphs and the ligature already has an ID. */
if ( in->ligIDs[in->pos] )
{
if ( ADD_String( in, i, out, 1, &lig->LigGlyph,
0xFFFF, 0xFFFF ) )
return error;
}
else
{
if ( ADD_String( in, i, out, 1, &lig->LigGlyph,
0xFFFF, in->max_ligID ) )
return error;
(in->max_ligID)++;
}
}
else
{
if ( ADD_String( in, 1, out, 1, &lig->LigGlyph,
0xFFFF, in->max_ligID ) )
return error;
/* Now we must do a second loop to copy the skipped glyphs to
`out' and assign component values to it. We start with the
glyph after the first component. Glyphs between component
i and i+1 belong to component i. Together with the ligID
value it is later possible to check whether a specific
component value really belongs to a given ligature. */
for ( i = 0; i < lig->ComponentCount - 1; i++ )
{
while ( CHECK_Property( gdef, in->string[in->pos],
flags, &property ) )
if ( ADD_String( in, 1, out, 1, &in->string[in->pos],
i, in->max_ligID ) )
return error;
(in->pos)++;
}
(in->max_ligID)++;
}
return TT_Err_Ok;
}
}
return TTO_Err_Not_Covered;
}
/* Do the actual substitution for a context substitution (either format
5 or 6). This is only called after we've determined that the input
matches the subrule. */
static FT_Error Do_ContextSubst( TTO_GSUBHeader* gsub,
FT_UShort GlyphCount,
FT_UShort SubstCount,
TTO_SubstLookupRecord* subst,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
int nesting_level )
{
FT_Error error;
FT_UShort i, old_pos;
i = 0;
while ( i < GlyphCount )
{
if ( SubstCount && i == subst->SequenceIndex )
{
old_pos = in->pos;
/* Do a substitution */
error = Do_Glyph_Lookup( gsub, subst->LookupListIndex, in, out,
GlyphCount, nesting_level );
subst++;
SubstCount--;
i += in->pos - old_pos;
if ( error == TTO_Err_Not_Covered )
{
/* XXX "can't happen" -- but don't count on it */
if ( ADD_String( in, 1, out, 1, &in->string[in->pos],
0xFFFF, 0xFFFF ) )
return error;
i++;
}
else if ( error )
return error;
}
else
{
/* No substitution for this index */
if ( ADD_String( in, 1, out, 1, &in->string[in->pos],
0xFFFF, 0xFFFF ) )
return error;
i++;
}
}
return TT_Err_Ok;
}
/* LookupType 5 */
/* SubRule */
static FT_Error Load_SubRule( TTO_SubRule* sr,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* i;
TTO_SubstLookupRecord* slr;
if ( ACCESS_Frame( 4L ) )
return error;
sr->GlyphCount = GET_UShort();
sr->SubstCount = GET_UShort();
FORGET_Frame();
sr->Input = NULL;
count = sr->GlyphCount - 1; /* only GlyphCount - 1 elements */
if ( ALLOC_ARRAY( sr->Input, count, FT_UShort ) )
return error;
i = sr->Input;
if ( ACCESS_Frame( count * 2L ) )
goto Fail2;
for ( n = 0; n < count; n++ )
i[n] = GET_UShort();
FORGET_Frame();
sr->SubstLookupRecord = NULL;
count = sr->SubstCount;
if ( ALLOC_ARRAY( sr->SubstLookupRecord, count, TTO_SubstLookupRecord ) )
goto Fail2;
slr = sr->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
FREE( i );
return error;
}
static void Free_SubRule( TTO_SubRule* sr,
FT_Memory memory )
{
FREE( sr->SubstLookupRecord );
FREE( sr->Input );
}
/* SubRuleSet */
static FT_Error Load_SubRuleSet( TTO_SubRuleSet* srs,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_SubRule* sr;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 2L ) )
return error;
count = srs->SubRuleCount = GET_UShort();
FORGET_Frame();
srs->SubRule = NULL;
if ( ALLOC_ARRAY( srs->SubRule, count, TTO_SubRule ) )
return error;
sr = srs->SubRule;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_SubRule( &sr[n], stream ) ) != TT_Err_Ok )
goto Fail;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail:
for ( m = 0; m < n; m++ )
Free_SubRule( &sr[m], memory );
FREE( sr );
return error;
}
static void Free_SubRuleSet( TTO_SubRuleSet* srs,
FT_Memory memory )
{
FT_UShort n, count;
TTO_SubRule* sr;
if ( srs->SubRule )
{
count = srs->SubRuleCount;
sr = srs->SubRule;
for ( n = 0; n < count; n++ )
Free_SubRule( &sr[n], memory );
FREE( sr );
}
}
/* ContextSubstFormat1 */
static FT_Error Load_ContextSubst1( TTO_ContextSubstFormat1* csf1,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_SubRuleSet* srs;
base_offset = FILE_Pos() - 2L;
if ( ACCESS_Frame( 2L ) )
return error;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &csf1->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = csf1->SubRuleSetCount = GET_UShort();
FORGET_Frame();
csf1->SubRuleSet = NULL;
if ( ALLOC_ARRAY( csf1->SubRuleSet, count, TTO_SubRuleSet ) )
goto Fail2;
srs = csf1->SubRuleSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_SubRuleSet( &srs[n], stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_SubRuleSet( &srs[m], memory );
FREE( srs );
Fail2:
Free_Coverage( &csf1->Coverage, memory );
return error;
}
static void Free_Context1( TTO_ContextSubstFormat1* csf1,
FT_Memory memory )
{
FT_UShort n, count;
TTO_SubRuleSet* srs;
if ( csf1->SubRuleSet )
{
count = csf1->SubRuleSetCount;
srs = csf1->SubRuleSet;
for ( n = 0; n < count; n++ )
Free_SubRuleSet( &srs[n], memory );
FREE( srs );
}
Free_Coverage( &csf1->Coverage, memory );
}
/* SubClassRule */
static FT_Error Load_SubClassRule( TTO_ContextSubstFormat2* csf2,
TTO_SubClassRule* scr,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* c;
TTO_SubstLookupRecord* slr;
FT_Bool* d;
if ( ACCESS_Frame( 4L ) )
return error;
scr->GlyphCount = GET_UShort();
scr->SubstCount = GET_UShort();
if ( scr->GlyphCount > csf2->MaxContextLength )
csf2->MaxContextLength = scr->GlyphCount;
FORGET_Frame();
scr->Class = NULL;
count = scr->GlyphCount - 1; /* only GlyphCount - 1 elements */
if ( ALLOC_ARRAY( scr->Class, count, FT_UShort ) )
return error;
c = scr->Class;
d = csf2->ClassDef.Defined;
if ( ACCESS_Frame( count * 2L ) )
goto Fail2;
for ( n = 0; n < count; n++ )
{
c[n] = GET_UShort();
/* We check whether the specific class is used at all. If not,
class 0 is used instead. */
if ( !d[c[n]] )
c[n] = 0;
}
FORGET_Frame();
scr->SubstLookupRecord = NULL;
count = scr->SubstCount;
if ( ALLOC_ARRAY( scr->SubstLookupRecord, count, TTO_SubstLookupRecord ) )
goto Fail2;
slr = scr->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
FREE( c );
return error;
}
static void Free_SubClassRule( TTO_SubClassRule* scr,
FT_Memory memory )
{
FREE( scr->SubstLookupRecord );
FREE( scr->Class );
}
/* SubClassSet */
static FT_Error Load_SubClassSet( TTO_ContextSubstFormat2* csf2,
TTO_SubClassSet* scs,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_SubClassRule* scr;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 2L ) )
return error;
count = scs->SubClassRuleCount = GET_UShort();
FORGET_Frame();
scs->SubClassRule = NULL;
if ( ALLOC_ARRAY( scs->SubClassRule, count, TTO_SubClassRule ) )
return error;
scr = scs->SubClassRule;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_SubClassRule( csf2, &scr[n],
stream ) ) != TT_Err_Ok )
goto Fail;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail:
for ( m = 0; m < n; m++ )
Free_SubClassRule( &scr[m], memory );
FREE( scr );
return error;
}
static void Free_SubClassSet( TTO_SubClassSet* scs,
FT_Memory memory )
{
FT_UShort n, count;
TTO_SubClassRule* scr;
if ( scs->SubClassRule )
{
count = scs->SubClassRuleCount;
scr = scs->SubClassRule;
for ( n = 0; n < count; n++ )
Free_SubClassRule( &scr[n], memory );
FREE( scr );
}
}
/* ContextSubstFormat2 */
static FT_Error Load_ContextSubst2( TTO_ContextSubstFormat2* csf2,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_SubClassSet* scs;
base_offset = FILE_Pos() - 2;
if ( ACCESS_Frame( 2L ) )
return error;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &csf2->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 4L ) )
goto Fail3;
new_offset = GET_UShort() + base_offset;
/* `SubClassSetCount' is the upper limit for class values, thus we
read it now to make an additional safety check. */
count = csf2->SubClassSetCount = GET_UShort();
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ClassDefinition( &csf2->ClassDef, count,
stream ) ) != TT_Err_Ok )
goto Fail3;
(void)FILE_Seek( cur_offset );
csf2->SubClassSet = NULL;
csf2->MaxContextLength = 0;
if ( ALLOC_ARRAY( csf2->SubClassSet, count, TTO_SubClassSet ) )
goto Fail2;
scs = csf2->SubClassSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
if ( new_offset != base_offset ) /* not a NULL offset */
{
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_SubClassSet( csf2, &scs[n],
stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
else
{
/* we create a SubClassSet table with no entries */
csf2->SubClassSet[n].SubClassRuleCount = 0;
csf2->SubClassSet[n].SubClassRule = NULL;
}
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_SubClassSet( &scs[m], memory );
FREE( scs );
Fail2:
Free_ClassDefinition( &csf2->ClassDef, memory );
Fail3:
Free_Coverage( &csf2->Coverage, memory );
return error;
}
static void Free_Context2( TTO_ContextSubstFormat2* csf2,
FT_Memory memory )
{
FT_UShort n, count;
TTO_SubClassSet* scs;
if ( csf2->SubClassSet )
{
count = csf2->SubClassSetCount;
scs = csf2->SubClassSet;
for ( n = 0; n < count; n++ )
Free_SubClassSet( &scs[n], memory );
FREE( scs );
}
Free_ClassDefinition( &csf2->ClassDef, memory );
Free_Coverage( &csf2->Coverage, memory );
}
/* ContextSubstFormat3 */
static FT_Error Load_ContextSubst3( TTO_ContextSubstFormat3* csf3,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_Coverage* c;
TTO_SubstLookupRecord* slr;
base_offset = FILE_Pos() - 2L;
if ( ACCESS_Frame( 4L ) )
return error;
csf3->GlyphCount = GET_UShort();
csf3->SubstCount = GET_UShort();
FORGET_Frame();
csf3->Coverage = NULL;
count = csf3->GlyphCount;
if ( ALLOC_ARRAY( csf3->Coverage, count, TTO_Coverage ) )
return error;
c = csf3->Coverage;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail2;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &c[n], stream ) ) != TT_Err_Ok )
goto Fail2;
(void)FILE_Seek( cur_offset );
}
csf3->SubstLookupRecord = NULL;
count = csf3->SubstCount;
if ( ALLOC_ARRAY( csf3->SubstLookupRecord, count,
TTO_SubstLookupRecord ) )
goto Fail2;
slr = csf3->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
for ( m = 0; m < n; m++ )
Free_Coverage( &c[m], memory );
FREE( c );
return error;
}
static void Free_Context3( TTO_ContextSubstFormat3* csf3,
FT_Memory memory )
{
FT_UShort n, count;
TTO_Coverage* c;
FREE( csf3->SubstLookupRecord );
if ( csf3->Coverage )
{
count = csf3->GlyphCount;
c = csf3->Coverage;
for ( n = 0; n < count; n++ )
Free_Coverage( &c[n], memory );
FREE( c );
}
}
/* ContextSubst */
FT_Error Load_ContextSubst( TTO_ContextSubst* cs,
FT_Stream stream )
{
FT_Error error;
if ( ACCESS_Frame( 2L ) )
return error;
cs->SubstFormat = GET_UShort();
FORGET_Frame();
switch ( cs->SubstFormat )
{
case 1:
return Load_ContextSubst1( &cs->csf.csf1, stream );
case 2:
return Load_ContextSubst2( &cs->csf.csf2, stream );
case 3:
return Load_ContextSubst3( &cs->csf.csf3, stream );
default:
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
return TT_Err_Ok; /* never reached */
}
void Free_ContextSubst( TTO_ContextSubst* cs,
FT_Memory memory )
{
switch ( cs->SubstFormat )
{
case 1:
Free_Context1( &cs->csf.csf1, memory );
break;
case 2:
Free_Context2( &cs->csf.csf2, memory );
break;
case 3:
Free_Context3( &cs->csf.csf3, memory );
break;
}
}
static FT_Error Lookup_ContextSubst1(
TTO_GSUBHeader* gsub,
TTO_ContextSubstFormat1* csf1,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_UShort index, property;
FT_UShort i, j, k, numsr;
FT_Error error;
FT_UShort* s_in;
TTO_SubRule* sr;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
error = Coverage_Index( &csf1->Coverage, in->string[in->pos], &index );
if ( error )
return error;
sr = csf1->SubRuleSet[index].SubRule;
numsr = csf1->SubRuleSet[index].SubRuleCount;
for ( k = 0; k < numsr; k++ )
{
if ( context_length != 0xFFFF && context_length < sr[k].GlyphCount )
continue;
if ( in->pos + sr[k].GlyphCount > in->length )
continue; /* context is too long */
s_in = &in->string[in->pos];
for ( i = 1, j = 1; i < sr[k].GlyphCount; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( in->pos + j < in->length )
j++;
else
break;
}
if ( s_in[j] != sr[k].Input[i - 1] )
break;
}
if ( i == sr[k].GlyphCount )
return Do_ContextSubst( gsub, sr[k].GlyphCount,
sr[k].SubstCount, sr[k].SubstLookupRecord,
in, out,
nesting_level );
}
return TTO_Err_Not_Covered;
}
static FT_Error Lookup_ContextSubst2(
TTO_GSUBHeader* gsub,
TTO_ContextSubstFormat2* csf2,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_UShort index, property;
FT_Error error;
FT_Memory memory = gsub->memory;
FT_UShort i, j, k, known_classes;
FT_UShort* classes;
FT_UShort* s_in;
FT_UShort* cl;
TTO_SubClassSet* scs;
TTO_SubClassRule* sr;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
/* Note: The coverage table in format 2 doesn't give an index into
anything. It just lets us know whether or not we need to
do any lookup at all. */
error = Coverage_Index( &csf2->Coverage, in->string[in->pos], &index );
if ( error )
return error;
if ( ALLOC_ARRAY( classes, csf2->MaxContextLength, FT_UShort ) )
return error;
error = Get_Class( &csf2->ClassDef, in->string[in->pos],
&classes[0], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End;
known_classes = 0;
scs = &csf2->SubClassSet[classes[0]];
if ( !scs )
{
error = TTO_Err_Invalid_GSUB_SubTable;
goto End;
}
for ( k = 0; k < scs->SubClassRuleCount; k++ )
{
sr = &scs->SubClassRule[k];
if ( context_length != 0xFFFF && context_length < sr->GlyphCount )
continue;
if ( in->pos + sr->GlyphCount > in->length )
continue; /* context is too long */
s_in = &in->string[in->pos];
cl = sr->Class;
/* Start at 1 because [0] is implied */
for ( i = 1, j = 1; i < sr->GlyphCount; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
goto End;
if ( in->pos + j < in->length )
j++;
else
break;
}
if ( i > known_classes )
{
/* Keeps us from having to do this for each rule */
error = Get_Class( &csf2->ClassDef, s_in[j], &classes[i], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End;
known_classes = i;
}
if ( cl[i - 1] != classes[i] )
break;
}
if ( i == sr->GlyphCount )
{
error = Do_ContextSubst( gsub, sr->GlyphCount,
sr->SubstCount, sr->SubstLookupRecord,
in, out,
nesting_level );
goto End;
}
}
error = TTO_Err_Not_Covered;
End:
FREE( classes );
return error;
}
static FT_Error Lookup_ContextSubst3(
TTO_GSUBHeader* gsub,
TTO_ContextSubstFormat3* csf3,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_Error error;
FT_UShort index, i, j, property;
FT_UShort* s_in;
TTO_Coverage* c;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
if ( context_length != 0xFFFF && context_length < csf3->GlyphCount )
return TTO_Err_Not_Covered;
if ( in->pos + csf3->GlyphCount > in->length )
return TTO_Err_Not_Covered; /* context is too long */
s_in = &in->string[in->pos];
c = csf3->Coverage;
for ( i = 1, j = 1; i < csf3->GlyphCount; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( in->pos + j < in->length )
j++;
else
return TTO_Err_Not_Covered;
}
error = Coverage_Index( &c[i], s_in[j], &index );
if ( error )
return error;
}
return Do_ContextSubst( gsub, csf3->GlyphCount,
csf3->SubstCount, csf3->SubstLookupRecord,
in, out,
nesting_level );
}
static FT_Error Lookup_ContextSubst( TTO_GSUBHeader* gsub,
TTO_ContextSubst* cs,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
switch ( cs->SubstFormat )
{
case 1:
return Lookup_ContextSubst1( gsub, &cs->csf.csf1, in, out,
flags, context_length, nesting_level );
case 2:
return Lookup_ContextSubst2( gsub, &cs->csf.csf2, in, out,
flags, context_length, nesting_level );
case 3:
return Lookup_ContextSubst3( gsub, &cs->csf.csf3, in, out,
flags, context_length, nesting_level );
default:
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
return TT_Err_Ok; /* never reached */
}
/* LookupType 6 */
/* ChainSubRule */
static FT_Error Load_ChainSubRule( TTO_ChainSubRule* csr,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* b;
FT_UShort* i;
FT_UShort* l;
TTO_SubstLookupRecord* slr;
if ( ACCESS_Frame( 2L ) )
return error;
csr->BacktrackGlyphCount = GET_UShort();
FORGET_Frame();
csr->Backtrack = NULL;
count = csr->BacktrackGlyphCount;
if ( ALLOC_ARRAY( csr->Backtrack, count, FT_UShort ) )
return error;
b = csr->Backtrack;
if ( ACCESS_Frame( count * 2L ) )
goto Fail4;
for ( n = 0; n < count; n++ )
b[n] = GET_UShort();
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail4;
csr->InputGlyphCount = GET_UShort();
FORGET_Frame();
csr->Input = NULL;
count = csr->InputGlyphCount - 1; /* only InputGlyphCount - 1 elements */
if ( ALLOC_ARRAY( csr->Input, count, FT_UShort ) )
goto Fail4;
i = csr->Input;
if ( ACCESS_Frame( count * 2L ) )
goto Fail3;
for ( n = 0; n < count; n++ )
i[n] = GET_UShort();
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail3;
csr->LookaheadGlyphCount = GET_UShort();
FORGET_Frame();
csr->Lookahead = NULL;
count = csr->LookaheadGlyphCount;
if ( ALLOC_ARRAY( csr->Lookahead, count, FT_UShort ) )
goto Fail3;
l = csr->Lookahead;
if ( ACCESS_Frame( count * 2L ) )
goto Fail2;
for ( n = 0; n < count; n++ )
l[n] = GET_UShort();
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail2;
csr->SubstCount = GET_UShort();
FORGET_Frame();
csr->SubstLookupRecord = NULL;
count = csr->SubstCount;
if ( ALLOC_ARRAY( csr->SubstLookupRecord, count, TTO_SubstLookupRecord ) )
goto Fail2;
slr = csr->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
FREE( l );
Fail3:
FREE( i );
Fail4:
FREE( b );
return error;
}
static void Free_ChainSubRule( TTO_ChainSubRule* csr,
FT_Memory memory )
{
FREE( csr->SubstLookupRecord );
FREE( csr->Lookahead );
FREE( csr->Input );
FREE( csr->Backtrack );
}
/* ChainSubRuleSet */
static FT_Error Load_ChainSubRuleSet( TTO_ChainSubRuleSet* csrs,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_ChainSubRule* csr;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 2L ) )
return error;
count = csrs->ChainSubRuleCount = GET_UShort();
FORGET_Frame();
csrs->ChainSubRule = NULL;
if ( ALLOC_ARRAY( csrs->ChainSubRule, count, TTO_ChainSubRule ) )
return error;
csr = csrs->ChainSubRule;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ChainSubRule( &csr[n], stream ) ) != TT_Err_Ok )
goto Fail;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail:
for ( m = 0; m < n; m++ )
Free_ChainSubRule( &csr[m], memory );
FREE( csr );
return error;
}
static void Free_ChainSubRuleSet( TTO_ChainSubRuleSet* csrs,
FT_Memory memory )
{
FT_UShort n, count;
TTO_ChainSubRule* csr;
if ( csrs->ChainSubRule )
{
count = csrs->ChainSubRuleCount;
csr = csrs->ChainSubRule;
for ( n = 0; n < count; n++ )
Free_ChainSubRule( &csr[n], memory );
FREE( csr );
}
}
/* ChainContextSubstFormat1 */
static FT_Error Load_ChainContextSubst1(
TTO_ChainContextSubstFormat1* ccsf1,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_ChainSubRuleSet* csrs;
base_offset = FILE_Pos() - 2L;
if ( ACCESS_Frame( 2L ) )
return error;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &ccsf1->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 2L ) )
goto Fail2;
count = ccsf1->ChainSubRuleSetCount = GET_UShort();
FORGET_Frame();
ccsf1->ChainSubRuleSet = NULL;
if ( ALLOC_ARRAY( ccsf1->ChainSubRuleSet, count, TTO_ChainSubRuleSet ) )
goto Fail2;
csrs = ccsf1->ChainSubRuleSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ChainSubRuleSet( &csrs[n], stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_ChainSubRuleSet( &csrs[m], memory );
FREE( csrs );
Fail2:
Free_Coverage( &ccsf1->Coverage, memory );
return error;
}
static void Free_ChainContext1( TTO_ChainContextSubstFormat1* ccsf1,
FT_Memory memory )
{
FT_UShort n, count;
TTO_ChainSubRuleSet* csrs;
if ( ccsf1->ChainSubRuleSet )
{
count = ccsf1->ChainSubRuleSetCount;
csrs = ccsf1->ChainSubRuleSet;
for ( n = 0; n < count; n++ )
Free_ChainSubRuleSet( &csrs[n], memory );
FREE( csrs );
}
Free_Coverage( &ccsf1->Coverage, memory );
}
/* ChainSubClassRule */
static FT_Error Load_ChainSubClassRule(
TTO_ChainContextSubstFormat2* ccsf2,
TTO_ChainSubClassRule* cscr,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, count;
FT_UShort* b;
FT_UShort* i;
FT_UShort* l;
TTO_SubstLookupRecord* slr;
FT_Bool* d;
if ( ACCESS_Frame( 2L ) )
return error;
cscr->BacktrackGlyphCount = GET_UShort();
FORGET_Frame();
if ( cscr->BacktrackGlyphCount > ccsf2->MaxBacktrackLength )
ccsf2->MaxBacktrackLength = cscr->BacktrackGlyphCount;
cscr->Backtrack = NULL;
count = cscr->BacktrackGlyphCount;
if ( ALLOC_ARRAY( cscr->Backtrack, count, FT_UShort ) )
return error;
b = cscr->Backtrack;
d = ccsf2->BacktrackClassDef.Defined;
if ( ACCESS_Frame( count * 2L ) )
goto Fail4;
for ( n = 0; n < count; n++ )
{
b[n] = GET_UShort();
/* We check whether the specific class is used at all. If not,
class 0 is used instead. */
if ( !d[b[n]] )
b[n] = 0;
}
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail4;
cscr->InputGlyphCount = GET_UShort();
FORGET_Frame();
if ( cscr->InputGlyphCount > ccsf2->MaxInputLength )
ccsf2->MaxInputLength = cscr->InputGlyphCount;
cscr->Input = NULL;
count = cscr->InputGlyphCount - 1; /* only InputGlyphCount - 1 elements */
if ( ALLOC_ARRAY( cscr->Input, count, FT_UShort ) )
goto Fail4;
i = cscr->Input;
d = ccsf2->InputClassDef.Defined;
if ( ACCESS_Frame( count * 2L ) )
goto Fail3;
for ( n = 0; n < count; n++ )
{
i[n] = GET_UShort();
if ( !d[i[n]] )
i[n] = 0;
}
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail3;
cscr->LookaheadGlyphCount = GET_UShort();
FORGET_Frame();
if ( cscr->LookaheadGlyphCount > ccsf2->MaxLookaheadLength )
ccsf2->MaxLookaheadLength = cscr->LookaheadGlyphCount;
cscr->Lookahead = NULL;
count = cscr->LookaheadGlyphCount;
if ( ALLOC_ARRAY( cscr->Lookahead, count, FT_UShort ) )
goto Fail3;
l = cscr->Lookahead;
d = ccsf2->LookaheadClassDef.Defined;
if ( ACCESS_Frame( count * 2L ) )
goto Fail2;
for ( n = 0; n < count; n++ )
{
l[n] = GET_UShort();
if ( !d[l[n]] )
l[n] = 0;
}
FORGET_Frame();
if ( ACCESS_Frame( 2L ) )
goto Fail2;
cscr->SubstCount = GET_UShort();
FORGET_Frame();
cscr->SubstLookupRecord = NULL;
count = cscr->SubstCount;
if ( ALLOC_ARRAY( cscr->SubstLookupRecord, count,
TTO_SubstLookupRecord ) )
goto Fail2;
slr = cscr->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
FREE( l );
Fail3:
FREE( i );
Fail4:
FREE( b );
return error;
}
static void Free_ChainSubClassRule( TTO_ChainSubClassRule* cscr,
FT_Memory memory )
{
FREE( cscr->SubstLookupRecord );
FREE( cscr->Lookahead );
FREE( cscr->Input );
FREE( cscr->Backtrack );
}
/* SubClassSet */
static FT_Error Load_ChainSubClassSet(
TTO_ChainContextSubstFormat2* ccsf2,
TTO_ChainSubClassSet* cscs,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_ChainSubClassRule* cscr;
base_offset = FILE_Pos();
if ( ACCESS_Frame( 2L ) )
return error;
count = cscs->ChainSubClassRuleCount = GET_UShort();
FORGET_Frame();
cscs->ChainSubClassRule = NULL;
if ( ALLOC_ARRAY( cscs->ChainSubClassRule, count,
TTO_ChainSubClassRule ) )
return error;
cscr = cscs->ChainSubClassRule;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ChainSubClassRule( ccsf2, &cscr[n],
stream ) ) != TT_Err_Ok )
goto Fail;
(void)FILE_Seek( cur_offset );
}
return TT_Err_Ok;
Fail:
for ( m = 0; m < n; m++ )
Free_ChainSubClassRule( &cscr[m], memory );
FREE( cscr );
return error;
}
static void Free_ChainSubClassSet( TTO_ChainSubClassSet* cscs,
FT_Memory memory )
{
FT_UShort n, count;
TTO_ChainSubClassRule* cscr;
if ( cscs->ChainSubClassRule )
{
count = cscs->ChainSubClassRuleCount;
cscr = cscs->ChainSubClassRule;
for ( n = 0; n < count; n++ )
Free_ChainSubClassRule( &cscr[n], memory );
FREE( cscr );
}
}
static FT_Error Load_EmptyOrClassDefinition( TTO_ClassDefinition* cd,
FT_UShort limit,
FT_ULong class_offset,
FT_ULong base_offset,
FT_Stream stream )
{
FT_Error error;
FT_ULong cur_offset;
cur_offset = FILE_Pos();
if ( class_offset )
{
if ( !FILE_Seek( class_offset + base_offset ) )
error = Load_ClassDefinition( cd, limit, stream );
}
else
error = Load_EmptyClassDefinition ( cd, stream );
if (error == TT_Err_Ok)
(void)FILE_Seek( cur_offset ); /* Changes error as a side-effect */
return error;
}
/* ChainContextSubstFormat2 */
static FT_Error Load_ChainContextSubst2(
TTO_ChainContextSubstFormat2* ccsf2,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n = 0, m, count;
FT_ULong cur_offset, new_offset, base_offset;
FT_ULong backtrack_offset, input_offset, lookahead_offset;
TTO_ChainSubClassSet* cscs;
base_offset = FILE_Pos() - 2;
if ( ACCESS_Frame( 2L ) )
return error;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &ccsf2->Coverage, stream ) ) != TT_Err_Ok )
return error;
(void)FILE_Seek( cur_offset );
if ( ACCESS_Frame( 8L ) )
goto Fail5;
backtrack_offset = GET_UShort();
input_offset = GET_UShort();
lookahead_offset = GET_UShort();
/* `ChainSubClassSetCount' is the upper limit for input class values,
thus we read it now to make an additional safety check. No limit
is known or needed for the other two class definitions */
count = ccsf2->ChainSubClassSetCount = GET_UShort();
FORGET_Frame();
if ( ( error = Load_EmptyOrClassDefinition( &ccsf2->BacktrackClassDef, 65535,
backtrack_offset, base_offset,
stream ) ) != TT_Err_Ok )
goto Fail5;
if ( ( error = Load_EmptyOrClassDefinition( &ccsf2->InputClassDef, count,
input_offset, base_offset,
stream ) ) != TT_Err_Ok )
goto Fail4;
if ( ( error = Load_EmptyOrClassDefinition( &ccsf2->LookaheadClassDef, 65535,
lookahead_offset, base_offset,
stream ) ) != TT_Err_Ok )
goto Fail3;
ccsf2->ChainSubClassSet = NULL;
ccsf2->MaxBacktrackLength = 0;
ccsf2->MaxInputLength = 0;
ccsf2->MaxLookaheadLength = 0;
if ( ALLOC_ARRAY( ccsf2->ChainSubClassSet, count, TTO_ChainSubClassSet ) )
goto Fail2;
cscs = ccsf2->ChainSubClassSet;
for ( n = 0; n < count; n++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail1;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
if ( new_offset != base_offset ) /* not a NULL offset */
{
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_ChainSubClassSet( ccsf2, &cscs[n],
stream ) ) != TT_Err_Ok )
goto Fail1;
(void)FILE_Seek( cur_offset );
}
else
{
/* we create a ChainSubClassSet table with no entries */
ccsf2->ChainSubClassSet[n].ChainSubClassRuleCount = 0;
ccsf2->ChainSubClassSet[n].ChainSubClassRule = NULL;
}
}
return TT_Err_Ok;
Fail1:
for ( m = 0; m < n; m++ )
Free_ChainSubClassSet( &cscs[m], memory );
FREE( cscs );
Fail2:
Free_ClassDefinition( &ccsf2->LookaheadClassDef, memory );
Fail3:
Free_ClassDefinition( &ccsf2->InputClassDef, memory );
Fail4:
Free_ClassDefinition( &ccsf2->BacktrackClassDef, memory );
Fail5:
Free_Coverage( &ccsf2->Coverage, memory );
return error;
}
static void Free_ChainContext2( TTO_ChainContextSubstFormat2* ccsf2,
FT_Memory memory )
{
FT_UShort n, count;
TTO_ChainSubClassSet* cscs;
if ( ccsf2->ChainSubClassSet )
{
count = ccsf2->ChainSubClassSetCount;
cscs = ccsf2->ChainSubClassSet;
for ( n = 0; n < count; n++ )
Free_ChainSubClassSet( &cscs[n], memory );
FREE( cscs );
}
Free_ClassDefinition( &ccsf2->LookaheadClassDef, memory );
Free_ClassDefinition( &ccsf2->InputClassDef, memory );
Free_ClassDefinition( &ccsf2->BacktrackClassDef, memory );
Free_Coverage( &ccsf2->Coverage, memory );
}
/* ChainContextSubstFormat3 */
static FT_Error Load_ChainContextSubst3(
TTO_ChainContextSubstFormat3* ccsf3,
FT_Stream stream )
{
FT_Error error;
FT_Memory memory = stream->memory;
FT_UShort n, nb = 0, ni =0, nl = 0, m, count;
FT_UShort backtrack_count, input_count, lookahead_count;
FT_ULong cur_offset, new_offset, base_offset;
TTO_Coverage* b;
TTO_Coverage* i;
TTO_Coverage* l;
TTO_SubstLookupRecord* slr;
base_offset = FILE_Pos() - 2L;
if ( ACCESS_Frame( 2L ) )
return error;
ccsf3->BacktrackGlyphCount = GET_UShort();
FORGET_Frame();
ccsf3->BacktrackCoverage = NULL;
backtrack_count = ccsf3->BacktrackGlyphCount;
if ( ALLOC_ARRAY( ccsf3->BacktrackCoverage, backtrack_count,
TTO_Coverage ) )
return error;
b = ccsf3->BacktrackCoverage;
for ( nb = 0; nb < backtrack_count; nb++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail4;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &b[nb], stream ) ) != TT_Err_Ok )
goto Fail4;
(void)FILE_Seek( cur_offset );
}
if ( ACCESS_Frame( 2L ) )
goto Fail4;
ccsf3->InputGlyphCount = GET_UShort();
FORGET_Frame();
ccsf3->InputCoverage = NULL;
input_count = ccsf3->InputGlyphCount;
if ( ALLOC_ARRAY( ccsf3->InputCoverage, input_count, TTO_Coverage ) )
goto Fail4;
i = ccsf3->InputCoverage;
for ( ni = 0; ni < input_count; ni++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail3;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &i[ni], stream ) ) != TT_Err_Ok )
goto Fail3;
(void)FILE_Seek( cur_offset );
}
if ( ACCESS_Frame( 2L ) )
goto Fail3;
ccsf3->LookaheadGlyphCount = GET_UShort();
FORGET_Frame();
ccsf3->LookaheadCoverage = NULL;
lookahead_count = ccsf3->LookaheadGlyphCount;
if ( ALLOC_ARRAY( ccsf3->LookaheadCoverage, lookahead_count,
TTO_Coverage ) )
goto Fail3;
l = ccsf3->LookaheadCoverage;
for ( nl = 0; nl < lookahead_count; nl++ )
{
if ( ACCESS_Frame( 2L ) )
goto Fail2;
new_offset = GET_UShort() + base_offset;
FORGET_Frame();
cur_offset = FILE_Pos();
if ( FILE_Seek( new_offset ) ||
( error = Load_Coverage( &l[nl], stream ) ) != TT_Err_Ok )
goto Fail2;
(void)FILE_Seek( cur_offset );
}
if ( ACCESS_Frame( 2L ) )
goto Fail2;
ccsf3->SubstCount = GET_UShort();
FORGET_Frame();
ccsf3->SubstLookupRecord = NULL;
count = ccsf3->SubstCount;
if ( ALLOC_ARRAY( ccsf3->SubstLookupRecord, count,
TTO_SubstLookupRecord ) )
goto Fail2;
slr = ccsf3->SubstLookupRecord;
if ( ACCESS_Frame( count * 4L ) )
goto Fail1;
for ( n = 0; n < count; n++ )
{
slr[n].SequenceIndex = GET_UShort();
slr[n].LookupListIndex = GET_UShort();
}
FORGET_Frame();
return TT_Err_Ok;
Fail1:
FREE( slr );
Fail2:
for ( m = 0; m < nl; m++ )
Free_Coverage( &l[m], memory );
FREE( l );
Fail3:
for ( m = 0; m < ni; m++ )
Free_Coverage( &i[m], memory );
FREE( i );
Fail4:
for ( m = 0; m < nb; m++ )
Free_Coverage( &b[m], memory );
FREE( b );
return error;
}
static void Free_ChainContext3( TTO_ChainContextSubstFormat3* ccsf3,
FT_Memory memory )
{
FT_UShort n, count;
TTO_Coverage* c;
FREE( ccsf3->SubstLookupRecord );
if ( ccsf3->LookaheadCoverage )
{
count = ccsf3->LookaheadGlyphCount;
c = ccsf3->LookaheadCoverage;
for ( n = 0; n < count; n++ )
Free_Coverage( &c[n], memory );
FREE( c );
}
if ( ccsf3->InputCoverage )
{
count = ccsf3->InputGlyphCount;
c = ccsf3->InputCoverage;
for ( n = 0; n < count; n++ )
Free_Coverage( &c[n], memory );
FREE( c );
}
if ( ccsf3->BacktrackCoverage )
{
count = ccsf3->BacktrackGlyphCount;
c = ccsf3->BacktrackCoverage;
for ( n = 0; n < count; n++ )
Free_Coverage( &c[n], memory );
FREE( c );
}
}
/* ChainContextSubst */
FT_Error Load_ChainContextSubst( TTO_ChainContextSubst* ccs,
FT_Stream stream )
{
FT_Error error;
if ( ACCESS_Frame( 2L ) )
return error;
ccs->SubstFormat = GET_UShort();
FORGET_Frame();
switch ( ccs->SubstFormat )
{
case 1:
return Load_ChainContextSubst1( &ccs->ccsf.ccsf1, stream );
case 2:
return Load_ChainContextSubst2( &ccs->ccsf.ccsf2, stream );
case 3:
return Load_ChainContextSubst3( &ccs->ccsf.ccsf3, stream );
default:
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
return TT_Err_Ok; /* never reached */
}
void Free_ChainContextSubst( TTO_ChainContextSubst* ccs,
FT_Memory memory )
{
switch ( ccs->SubstFormat )
{
case 1:
Free_ChainContext1( &ccs->ccsf.ccsf1, memory );
break;
case 2:
Free_ChainContext2( &ccs->ccsf.ccsf2, memory );
break;
case 3:
Free_ChainContext3( &ccs->ccsf.ccsf3, memory );
break;
}
}
static FT_Error Lookup_ChainContextSubst1(
TTO_GSUBHeader* gsub,
TTO_ChainContextSubstFormat1* ccsf1,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_UShort index, property;
FT_UShort i, j, k, num_csr, curr_pos;
FT_UShort bgc, igc, lgc;
FT_Error error;
FT_UShort* s_in;
TTO_ChainSubRule* csr;
TTO_ChainSubRule curr_csr;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
error = Coverage_Index( &ccsf1->Coverage, in->string[in->pos], &index );
if ( error )
return error;
csr = ccsf1->ChainSubRuleSet[index].ChainSubRule;
num_csr = ccsf1->ChainSubRuleSet[index].ChainSubRuleCount;
for ( k = 0; k < num_csr; k++ )
{
curr_csr = csr[k];
bgc = curr_csr.BacktrackGlyphCount;
igc = curr_csr.InputGlyphCount;
lgc = curr_csr.LookaheadGlyphCount;
if ( context_length != 0xFFFF && context_length < igc )
continue;
/* check whether context is too long; it is a first guess only */
if ( bgc > in->pos || in->pos + igc + lgc > in->length )
continue;
if ( bgc )
{
/* since we don't know in advance the number of glyphs to inspect,
we search backwards for matches in the backtrack glyph array */
curr_pos = 0;
s_in = &in->string[curr_pos];
for ( i = 0, j = in->pos - 1; i < bgc; i++, j-- )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( j > curr_pos )
j--;
else
break;
}
/* In OpenType 1.3, it is undefined whether the offsets of
backtrack glyphs is in logical order or not. Version 1.4
will clarify this:
Logical order - a b c d e f g h i j
i
Input offsets - 0 1
Backtrack offsets - 3 2 1 0
Lookahead offsets - 0 1 2 3 */
if ( s_in[j] != curr_csr.Backtrack[i] )
break;
}
if ( i != bgc )
continue;
}
curr_pos = in->pos;
s_in = &in->string[curr_pos];
/* Start at 1 because [0] is implied */
for ( i = 1, j = 1; i < igc; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( curr_pos + j < in->length )
j++;
else
break;
}
if ( s_in[j] != curr_csr.Input[i - 1] )
break;
}
if ( i != igc )
continue;
/* we are starting to check for lookahead glyphs right after the
last context glyph */
curr_pos += j;
s_in = &in->string[curr_pos];
for ( i = 0, j = 0; i < lgc; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( curr_pos + j < in->length )
j++;
else
break;
}
if ( s_in[j] != curr_csr.Lookahead[i] )
break;
}
if ( i == lgc )
return Do_ContextSubst( gsub, igc,
curr_csr.SubstCount,
curr_csr.SubstLookupRecord,
in, out,
nesting_level );
}
return TTO_Err_Not_Covered;
}
static FT_Error Lookup_ChainContextSubst2(
TTO_GSUBHeader* gsub,
TTO_ChainContextSubstFormat2* ccsf2,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_UShort index, property;
FT_Memory memory;
FT_Error error;
FT_UShort i, j, k, curr_pos;
FT_UShort bgc, igc, lgc;
FT_UShort known_backtrack_classes,
known_input_classes,
known_lookahead_classes;
FT_UShort* backtrack_classes;
FT_UShort* input_classes;
FT_UShort* lookahead_classes;
FT_UShort* s_in;
FT_UShort* bc;
FT_UShort* ic;
FT_UShort* lc;
TTO_ChainSubClassSet* cscs;
TTO_ChainSubClassRule ccsr;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
memory = gsub->memory;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
/* Note: The coverage table in format 2 doesn't give an index into
anything. It just lets us know whether or not we need to
do any lookup at all. */
error = Coverage_Index( &ccsf2->Coverage, in->string[in->pos], &index );
if ( error )
return error;
if ( ALLOC_ARRAY( backtrack_classes, ccsf2->MaxBacktrackLength, FT_UShort ) )
return error;
known_backtrack_classes = 0;
if ( ALLOC_ARRAY( input_classes, ccsf2->MaxInputLength, FT_UShort ) )
goto End3;
known_input_classes = 1;
if ( ALLOC_ARRAY( lookahead_classes, ccsf2->MaxLookaheadLength, FT_UShort ) )
goto End2;
known_lookahead_classes = 0;
error = Get_Class( &ccsf2->InputClassDef, in->string[in->pos],
&input_classes[0], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End1;
cscs = &ccsf2->ChainSubClassSet[input_classes[0]];
if ( !cscs )
{
error = TTO_Err_Invalid_GSUB_SubTable;
goto End1;
}
for ( k = 0; k < cscs->ChainSubClassRuleCount; k++ )
{
ccsr = cscs->ChainSubClassRule[k];
bgc = ccsr.BacktrackGlyphCount;
igc = ccsr.InputGlyphCount;
lgc = ccsr.LookaheadGlyphCount;
if ( context_length != 0xFFFF && context_length < igc )
continue;
/* check whether context is too long; it is a first guess only */
if ( bgc > in->pos || in->pos + igc + lgc > in->length )
continue;
if ( bgc )
{
/* Since we don't know in advance the number of glyphs to inspect,
we search backwards for matches in the backtrack glyph array.
Note that `known_backtrack_classes' starts at index 0. */
curr_pos = 0;
s_in = &in->string[curr_pos];
bc = ccsr.Backtrack;
for ( i = 0, j = in->pos - 1; i < bgc; i++, j-- )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
goto End1;
if ( j > curr_pos )
j--;
else
break;
}
if ( i >= known_backtrack_classes )
{
/* Keeps us from having to do this for each rule */
error = Get_Class( &ccsf2->BacktrackClassDef, s_in[j],
&backtrack_classes[i], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End1;
known_backtrack_classes = i;
}
if ( bc[i] != backtrack_classes[i] )
break;
}
if ( i != bgc )
continue;
}
curr_pos = in->pos;
s_in = &in->string[curr_pos];
ic = ccsr.Input;
/* Start at 1 because [0] is implied */
for ( i = 1, j = 1; i < igc; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
goto End1;
if ( curr_pos + j < in->length )
j++;
else
break;
}
if ( i >= known_input_classes )
{
error = Get_Class( &ccsf2->InputClassDef, s_in[j],
&input_classes[i], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End1;
known_input_classes = i;
}
if ( ic[i - 1] != input_classes[i] )
break;
}
if ( i != igc )
continue;
/* we are starting to check for lookahead glyphs right after the
last context glyph */
curr_pos += j;
s_in = &in->string[curr_pos];
lc = ccsr.Lookahead;
for ( i = 0, j = 0; i < lgc; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
goto End1;
if ( curr_pos + j < in->length )
j++;
else
break;
}
if ( i >= known_lookahead_classes )
{
error = Get_Class( &ccsf2->LookaheadClassDef, s_in[j],
&lookahead_classes[i], NULL );
if ( error && error != TTO_Err_Not_Covered )
goto End1;
known_lookahead_classes = i;
}
if ( lc[i] != lookahead_classes[i] )
break;
}
if ( i == lgc )
{
error = Do_ContextSubst( gsub, igc,
ccsr.SubstCount,
ccsr.SubstLookupRecord,
in, out,
nesting_level );
goto End1;
}
}
error = TTO_Err_Not_Covered;
End1:
FREE( lookahead_classes );
End2:
FREE( input_classes );
End3:
FREE( backtrack_classes );
return error;
}
static FT_Error Lookup_ChainContextSubst3(
TTO_GSUBHeader* gsub,
TTO_ChainContextSubstFormat3* ccsf3,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
FT_UShort index, i, j, curr_pos, property;
FT_UShort bgc, igc, lgc;
FT_Error error;
FT_UShort* s_in;
TTO_Coverage* bc;
TTO_Coverage* ic;
TTO_Coverage* lc;
TTO_GDEFHeader* gdef;
gdef = gsub->gdef;
if ( CHECK_Property( gdef, in->string[in->pos], flags, &property ) )
return error;
bgc = ccsf3->BacktrackGlyphCount;
igc = ccsf3->InputGlyphCount;
lgc = ccsf3->LookaheadGlyphCount;
if ( context_length != 0xFFFF && context_length < igc )
return TTO_Err_Not_Covered;
/* check whether context is too long; it is a first guess only */
if ( bgc > in->pos || in->pos + igc + lgc > in->length )
return TTO_Err_Not_Covered;
if ( bgc )
{
/* Since we don't know in advance the number of glyphs to inspect,
we search backwards for matches in the backtrack glyph array */
curr_pos = 0;
s_in = &in->string[curr_pos];
bc = ccsf3->BacktrackCoverage;
for ( i = 0, j = in->pos - 1; i < bgc; i++, j-- )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( j > curr_pos )
j--;
else
return TTO_Err_Not_Covered;
}
error = Coverage_Index( &bc[i], s_in[j], &index );
if ( error )
return error;
}
}
curr_pos = in->pos;
s_in = &in->string[curr_pos];
ic = ccsf3->InputCoverage;
for ( i = 0, j = 0; i < igc; i++, j++ )
{
/* We already called CHECK_Property for s_in[0] */
while ( j > 0 && CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( curr_pos + j < in->length )
j++;
else
return TTO_Err_Not_Covered;
}
error = Coverage_Index( &ic[i], s_in[j], &index );
if ( error )
return error;
}
/* we are starting for lookahead glyphs right after the last context
glyph */
curr_pos += j;
s_in = &in->string[curr_pos];
lc = ccsf3->LookaheadCoverage;
for ( i = 0, j = 0; i < lgc; i++, j++ )
{
while ( CHECK_Property( gdef, s_in[j], flags, &property ) )
{
if ( error && error != TTO_Err_Not_Covered )
return error;
if ( curr_pos + j < in->length )
j++;
else
return TTO_Err_Not_Covered;
}
error = Coverage_Index( &lc[i], s_in[j], &index );
if ( error )
return error;
}
return Do_ContextSubst( gsub, igc,
ccsf3->SubstCount,
ccsf3->SubstLookupRecord,
in, out,
nesting_level );
}
static FT_Error Lookup_ChainContextSubst(
TTO_GSUBHeader* gsub,
TTO_ChainContextSubst* ccs,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort flags,
FT_UShort context_length,
int nesting_level )
{
switch ( ccs->SubstFormat )
{
case 1:
return Lookup_ChainContextSubst1( gsub, &ccs->ccsf.ccsf1, in, out,
flags, context_length,
nesting_level );
case 2:
return Lookup_ChainContextSubst2( gsub, &ccs->ccsf.ccsf2, in, out,
flags, context_length,
nesting_level );
case 3:
return Lookup_ChainContextSubst3( gsub, &ccs->ccsf.ccsf3, in, out,
flags, context_length,
nesting_level );
default:
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
return TT_Err_Ok; /* never reached */
}
/***********
* GSUB API
***********/
EXPORT_FUNC
FT_Error TT_GSUB_Select_Script( TTO_GSUBHeader* gsub,
FT_ULong script_tag,
FT_UShort* script_index )
{
FT_UShort n;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
if ( !gsub || !script_index )
return TT_Err_Invalid_Argument;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
for ( n = 0; n < sl->ScriptCount; n++ )
if ( script_tag == sr[n].ScriptTag )
{
*script_index = n;
return TT_Err_Ok;
}
return TTO_Err_Not_Covered;
}
EXPORT_FUNC
FT_Error TT_GSUB_Select_Language( TTO_GSUBHeader* gsub,
FT_ULong language_tag,
FT_UShort script_index,
FT_UShort* language_index,
FT_UShort* req_feature_index )
{
FT_UShort n;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
TTO_Script* s;
TTO_LangSysRecord* lsr;
if ( !gsub || !language_index || !req_feature_index )
return TT_Err_Invalid_Argument;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
if ( script_index >= sl->ScriptCount )
return TT_Err_Invalid_Argument;
s = &sr[script_index].Script;
lsr = s->LangSysRecord;
for ( n = 0; n < s->LangSysCount; n++ )
if ( language_tag == lsr[n].LangSysTag )
{
*language_index = n;
*req_feature_index = lsr[n].LangSys.ReqFeatureIndex;
return TT_Err_Ok;
}
return TTO_Err_Not_Covered;
}
/* selecting 0xFFFF for language_index asks for the values of the
default language (DefaultLangSys) */
EXPORT_FUNC
FT_Error TT_GSUB_Select_Feature( TTO_GSUBHeader* gsub,
FT_ULong feature_tag,
FT_UShort script_index,
FT_UShort language_index,
FT_UShort* feature_index )
{
FT_UShort n;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
TTO_Script* s;
TTO_LangSysRecord* lsr;
TTO_LangSys* ls;
FT_UShort* fi;
TTO_FeatureList* fl;
TTO_FeatureRecord* fr;
if ( !gsub || !feature_index )
return TT_Err_Invalid_Argument;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
fl = &gsub->FeatureList;
fr = fl->FeatureRecord;
if ( script_index >= sl->ScriptCount )
return TT_Err_Invalid_Argument;
s = &sr[script_index].Script;
lsr = s->LangSysRecord;
if ( language_index == 0xFFFF )
ls = &s->DefaultLangSys;
else
{
if ( language_index >= s->LangSysCount )
return TT_Err_Invalid_Argument;
ls = &lsr[language_index].LangSys;
}
fi = ls->FeatureIndex;
for ( n = 0; n < ls->FeatureCount; n++ )
{
if ( fi[n] >= fl->FeatureCount )
return TTO_Err_Invalid_GSUB_SubTable_Format;
if ( feature_tag == fr[fi[n]].FeatureTag )
{
*feature_index = fi[n];
return TT_Err_Ok;
}
}
return TTO_Err_Not_Covered;
}
/* The next three functions return a null-terminated list */
EXPORT_FUNC
FT_Error TT_GSUB_Query_Scripts( TTO_GSUBHeader* gsub,
FT_ULong** script_tag_list )
{
FT_UShort n;
FT_Error error;
FT_Memory memory;
FT_ULong* stl;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
if ( !gsub || !script_tag_list )
return TT_Err_Invalid_Argument;
memory = gsub->memory;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
if ( ALLOC_ARRAY( stl, sl->ScriptCount + 1, FT_ULong ) )
return error;
for ( n = 0; n < sl->ScriptCount; n++ )
stl[n] = sr[n].ScriptTag;
stl[n] = 0;
*script_tag_list = stl;
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_Query_Languages( TTO_GSUBHeader* gsub,
FT_UShort script_index,
FT_ULong** language_tag_list )
{
FT_UShort n;
FT_Error error;
FT_Memory memory;
FT_ULong* ltl;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
TTO_Script* s;
TTO_LangSysRecord* lsr;
if ( !gsub || !language_tag_list )
return TT_Err_Invalid_Argument;
memory = gsub->memory;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
if ( script_index >= sl->ScriptCount )
return TT_Err_Invalid_Argument;
s = &sr[script_index].Script;
lsr = s->LangSysRecord;
if ( ALLOC_ARRAY( ltl, s->LangSysCount + 1, FT_ULong ) )
return error;
for ( n = 0; n < s->LangSysCount; n++ )
ltl[n] = lsr[n].LangSysTag;
ltl[n] = 0;
*language_tag_list = ltl;
return TT_Err_Ok;
}
/* selecting 0xFFFF for language_index asks for the values of the
default language (DefaultLangSys) */
EXPORT_FUNC
FT_Error TT_GSUB_Query_Features( TTO_GSUBHeader* gsub,
FT_UShort script_index,
FT_UShort language_index,
FT_ULong** feature_tag_list )
{
FT_UShort n;
FT_Error error;
FT_Memory memory;
FT_ULong* ftl;
TTO_ScriptList* sl;
TTO_ScriptRecord* sr;
TTO_Script* s;
TTO_LangSysRecord* lsr;
TTO_LangSys* ls;
FT_UShort* fi;
TTO_FeatureList* fl;
TTO_FeatureRecord* fr;
if ( !gsub || !feature_tag_list )
return TT_Err_Invalid_Argument;
memory = gsub->memory;
sl = &gsub->ScriptList;
sr = sl->ScriptRecord;
fl = &gsub->FeatureList;
fr = fl->FeatureRecord;
if ( script_index >= sl->ScriptCount )
return TT_Err_Invalid_Argument;
s = &sr[script_index].Script;
lsr = s->LangSysRecord;
if ( language_index == 0xFFFF )
ls = &s->DefaultLangSys;
else
{
if ( language_index >= s->LangSysCount )
return TT_Err_Invalid_Argument;
ls = &lsr[language_index].LangSys;
}
fi = ls->FeatureIndex;
if ( ALLOC_ARRAY( ftl, ls->FeatureCount + 1, FT_ULong ) )
return error;
for ( n = 0; n < ls->FeatureCount; n++ )
{
if ( fi[n] >= fl->FeatureCount )
{
FREE( ftl );
return TTO_Err_Invalid_GSUB_SubTable_Format;
}
ftl[n] = fr[fi[n]].FeatureTag;
}
ftl[n] = 0;
*feature_tag_list = ftl;
return TT_Err_Ok;
}
/* Do an individual subtable lookup. Returns TT_Err_Ok if substitution
has been done, or TTO_Err_Not_Covered if not. */
static FT_Error Do_Glyph_Lookup( TTO_GSUBHeader* gsub,
FT_UShort lookup_index,
TTO_GSUB_String* in,
TTO_GSUB_String* out,
FT_UShort context_length,
int nesting_level )
{
FT_Error error = TT_Err_Ok;
FT_UShort i, flags;
TTO_Lookup* lo;
nesting_level++;
if ( nesting_level > TTO_MAX_NESTING_LEVEL )
return TTO_Err_Too_Many_Nested_Contexts;
lo = &gsub->LookupList.Lookup[lookup_index];
flags = lo->LookupFlag;
for ( i = 0; i < lo->SubTableCount; i++ )
{
switch ( lo->LookupType )
{
case GSUB_LOOKUP_SINGLE:
error = Lookup_SingleSubst( &lo->SubTable[i].st.gsub.single,
in, out,
flags, context_length, gsub->gdef );
break;
case GSUB_LOOKUP_MULTIPLE:
error = Lookup_MultipleSubst( &lo->SubTable[i].st.gsub.multiple,
in, out,
flags, context_length, gsub->gdef );
break;
case GSUB_LOOKUP_ALTERNATE:
error = Lookup_AlternateSubst( gsub,
&lo->SubTable[i].st.gsub.alternate,
in, out,
flags, context_length, gsub->gdef );
break;
case GSUB_LOOKUP_LIGATURE:
error = Lookup_LigatureSubst( &lo->SubTable[i].st.gsub.ligature,
in, out,
flags, context_length, gsub->gdef );
break;
case GSUB_LOOKUP_CONTEXT:
error = Lookup_ContextSubst( gsub, &lo->SubTable[i].st.gsub.context,
in, out,
flags, context_length, nesting_level );
break;
case GSUB_LOOKUP_CHAIN:
error = Lookup_ChainContextSubst( gsub,
&lo->SubTable[i].st.gsub.chain,
in, out,
flags, context_length,
nesting_level );
break;
}
/* Check whether we have a successful substitution or an error other
than TTO_Err_Not_Covered */
if ( error != TTO_Err_Not_Covered )
return error;
}
return TTO_Err_Not_Covered;
}
/* apply one lookup to the input string object */
static FT_Error Do_String_Lookup( TTO_GSUBHeader* gsub,
FT_UShort lookup_index,
TTO_GSUB_String* in,
TTO_GSUB_String* out )
{
FT_Error error, retError = TTO_Err_Not_Covered;
FT_UShort* properties = gsub->LookupList.Properties;
FT_UShort* p_in = in->properties;
FT_UShort* s_in = in->string;
int nesting_level = 0;
while ( in->pos < in->length )
{
if ( ~p_in[in->pos] & properties[lookup_index] )
{
/* 0xFFFF indicates that we don't have a context length yet */
error = Do_Glyph_Lookup( gsub, lookup_index, in, out,
0xFFFF, nesting_level );
if ( error )
{
if ( error != TTO_Err_Not_Covered )
return error;
}
else
retError = error;
}
else
error = TTO_Err_Not_Covered;
if ( error == TTO_Err_Not_Covered )
if ( ADD_String( in, 1, out, 1, &s_in[in->pos], 0xFFFF, 0xFFFF ) )
return error;
}
return retError;
}
EXPORT_FUNC
FT_Error TT_GSUB_Add_Feature( TTO_GSUBHeader* gsub,
FT_UShort feature_index,
FT_UShort property )
{
FT_UShort i;
TTO_Feature feature;
FT_UShort* properties;
FT_UShort* index;
if ( !gsub ||
feature_index >= gsub->FeatureList.FeatureCount )
return TT_Err_Invalid_Argument;
properties = gsub->LookupList.Properties;
feature = gsub->FeatureList.FeatureRecord[feature_index].Feature;
index = feature.LookupListIndex;
for ( i = 0; i < feature.LookupListCount; i++ )
properties[index[i]] |= property;
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_Clear_Features( TTO_GSUBHeader* gsub )
{
FT_UShort i;
FT_UShort* properties;
if ( !gsub )
return TT_Err_Invalid_Argument;
properties = gsub->LookupList.Properties;
for ( i = 0; i < gsub->LookupList.LookupCount; i++ )
properties[i] = 0;
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_Register_Alternate_Function( TTO_GSUBHeader* gsub,
TTO_AltFunction altfunc,
void* data )
{
if ( !gsub )
return TT_Err_Invalid_Argument;
gsub->altfunc = altfunc;
gsub->data = data;
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_String_New( FT_Memory memory,
TTO_GSUB_String **result )
{
FT_Error error;
TTO_GSUB_String *str;
if ( ALLOC( str, sizeof( *str ) ) )
return error;
str->memory = memory;
str->length = 0;
str->allocated = 0;
str->pos = 0;
str->string = NULL;
str->properties = NULL;
str->components = NULL;
str->max_ligID = 0;
str->ligIDs = 0;
str->logClusters = 0;
*result = str;
return TT_Err_Ok;
}
EXPORT_DEF
FT_Error TT_GSUB_String_Set_Length( TTO_GSUB_String *str,
FT_ULong new_length)
{
FT_Memory memory = str->memory;
FT_Error error;
if ( new_length > str->allocated )
{
if ( REALLOC_ARRAY( str->string, str->allocated, new_length, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( str->properties, str->allocated, new_length, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( str->components, str->allocated, new_length, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( str->ligIDs, str->allocated, new_length, FT_UShort ) )
return error;
if ( REALLOC_ARRAY( str->logClusters, str->allocated, new_length, FT_Int ) )
return error;
str->allocated = new_length;
str->length = new_length;
}
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_String_Done( TTO_GSUB_String *str )
{
FT_Memory memory = str->memory;
FREE( str->string );
FREE( str->properties );
FREE( str->components );
FREE( str->ligIDs );
FREE( str->logClusters );
FREE( str );
return TT_Err_Ok;
}
EXPORT_FUNC
FT_Error TT_GSUB_Apply_String( TTO_GSUBHeader* gsub,
TTO_GSUB_String* in,
TTO_GSUB_String* out )
{
FT_Error error, retError = TTO_Err_Not_Covered;
FT_Memory memory = in->memory;
FT_UShort j;
TTO_GSUB_String tmp1;
TTO_GSUB_String* ptmp1;
TTO_GSUB_String tmp2;
TTO_GSUB_String* ptmp2;
TTO_GSUB_String* t;
FT_UShort* properties;
if ( !gsub ||
!in || !out || in->length == 0 || in->pos >= in->length )
return TT_Err_Invalid_Argument;
properties = gsub->LookupList.Properties;
tmp1.memory = memory;
tmp1.length = in->length;
tmp1.allocated = in->length;
tmp1.pos = in->pos;
tmp1.max_ligID = 1;
tmp1.string = NULL;
tmp1.properties = NULL;
tmp1.components = NULL;
tmp1.ligIDs = NULL;
tmp1.logClusters = NULL;
tmp2.memory = memory;
tmp2.allocated = 0;
tmp2.pos = 0;
tmp2.string = NULL;
tmp2.properties = NULL;
tmp2.components = NULL;
tmp2.ligIDs = NULL;
tmp2.logClusters = NULL;
ptmp1 = &tmp1;
ptmp2 = &tmp2;
if ( ALLOC_ARRAY( tmp1.string, tmp1.length, FT_UShort ) )
return error;
MEM_Copy( tmp1.string, in->string, in->length * sizeof ( FT_UShort ) );
/* make sure that we always have a `properties', `components', and
`ligIDs' array in the string object */
if ( ALLOC_ARRAY( tmp1.components, tmp1.length, FT_UShort ) )
goto End;
if ( ALLOC_ARRAY( tmp1.ligIDs, tmp1.length, FT_UShort ) )
goto End;
if ( ALLOC_ARRAY( tmp1.properties, tmp1.length, FT_UShort ) )
goto End;
if ( in->properties )
MEM_Copy( tmp1.properties, in->properties,
in->length * sizeof( FT_UShort ) );
if ( ALLOC_ARRAY( tmp1.logClusters, tmp1.length, FT_Int ) )
goto End;
MEM_Copy( tmp1.logClusters, in->logClusters,
in->length * sizeof( FT_Int ) );
for ( j = 0; j < gsub->LookupList.LookupCount; j++ )
if ( properties[j] )
{
error = Do_String_Lookup( gsub, j, ptmp1, ptmp2 );
if ( error )
{
if ( error != TTO_Err_Not_Covered )
goto End;
}
else
retError = error;
/* flipping `in' and `out', preparing the next loop */
ptmp1->pos = in->pos;
ptmp2->length = ptmp2->pos;
ptmp2->pos = in->pos;
ptmp2->max_ligID = ptmp1->max_ligID;
t = ptmp2;
ptmp2 = ptmp1;
ptmp1 = t;
}
End:
FREE( ptmp2->string );
FREE( ptmp2->properties );
FREE( ptmp2->components );
FREE( ptmp2->ligIDs );
FREE( ptmp2->logClusters );
if ( error && error != TTO_Err_Not_Covered )
{
FREE( ptmp1->string );
FREE( ptmp1->components );
FREE( ptmp1->ligIDs );
FREE( ptmp1->properties );
FREE( ptmp1->logClusters );
return error;
}
else
{
out->length = ptmp1->length;
out->pos = 0;
out->allocated = ptmp1->allocated;
out->string = ptmp1->string;
out->components = ptmp1->components;
out->ligIDs = ptmp1->ligIDs;
out->logClusters = ptmp1->logClusters;
if ( in->properties )
out->properties = ptmp1->properties;
else
{
FREE( ptmp1->properties );
out->properties = NULL;
}
return retError;
}
}
/* END */