ref: 1e0cef9e72aea5df787853e1952166807f4656fc
dir: /src/psaux/afmparse.c/
/**************************************************************************** * * afmparse.c * * AFM parser (body). * * Copyright (C) 2006-2021 by * David Turner, Robert Wilhelm, and Werner Lemberg. * * This file is part of the FreeType project, and may only be used, * modified, and distributed under the terms of the FreeType project * license, LICENSE.TXT. By continuing to use, modify, or distribute * this file you indicate that you have read the license and * understand and accept it fully. * */ #include <freetype/freetype.h> #include <freetype/internal/ftdebug.h> #include <freetype/internal/psaux.h> #ifndef T1_CONFIG_OPTION_NO_AFM #include "afmparse.h" #include "psconv.h" #include "psauxerr.h" /************************************************************************** * * The macro FT_COMPONENT is used in trace mode. It is an implicit * parameter of the FT_TRACE() and FT_ERROR() macros, used to print/log * messages during execution. */ #undef FT_COMPONENT #define FT_COMPONENT afmparse /************************************************************************** * * AFM_Stream * * The use of AFM_Stream is largely inspired by parseAFM.[ch] from t1lib. * */ enum { AFM_STREAM_STATUS_NORMAL, AFM_STREAM_STATUS_EOC, AFM_STREAM_STATUS_EOL, AFM_STREAM_STATUS_EOF }; typedef struct AFM_StreamRec_ { FT_Byte* cursor; FT_Byte* base; FT_Byte* limit; FT_Int status; } AFM_StreamRec; #ifndef EOF #define EOF -1 #endif /* this works because empty lines are ignored */ #define AFM_IS_NEWLINE( ch ) ( (ch) == '\r' || (ch) == '\n' ) #define AFM_IS_EOF( ch ) ( (ch) == EOF || (ch) == '\x1a' ) #define AFM_IS_SPACE( ch ) ( (ch) == ' ' || (ch) == '\t' ) /* column separator; there is no `column' in the spec actually */ #define AFM_IS_SEP( ch ) ( (ch) == ';' ) #define AFM_GETC() \ ( ( (stream)->cursor < (stream)->limit ) ? *(stream)->cursor++ \ : EOF ) #define AFM_STREAM_KEY_BEGIN( stream ) \ (char*)( (stream)->cursor - 1 ) #define AFM_STREAM_KEY_LEN( stream, key ) \ (FT_Offset)( (char*)(stream)->cursor - key - 1 ) #define AFM_STATUS_EOC( stream ) \ ( (stream)->status >= AFM_STREAM_STATUS_EOC ) #define AFM_STATUS_EOL( stream ) \ ( (stream)->status >= AFM_STREAM_STATUS_EOL ) #define AFM_STATUS_EOF( stream ) \ ( (stream)->status >= AFM_STREAM_STATUS_EOF ) static int afm_stream_skip_spaces( AFM_Stream stream ) { int ch = 0; /* make stupid compiler happy */ if ( AFM_STATUS_EOC( stream ) ) return ';'; while ( 1 ) { ch = AFM_GETC(); if ( !AFM_IS_SPACE( ch ) ) break; } if ( AFM_IS_NEWLINE( ch ) ) stream->status = AFM_STREAM_STATUS_EOL; else if ( AFM_IS_SEP( ch ) ) stream->status = AFM_STREAM_STATUS_EOC; else if ( AFM_IS_EOF( ch ) ) stream->status = AFM_STREAM_STATUS_EOF; return ch; } /* read a key or value in current column */ static char* afm_stream_read_one( AFM_Stream stream ) { char* str; afm_stream_skip_spaces( stream ); if ( AFM_STATUS_EOC( stream ) ) return NULL; str = AFM_STREAM_KEY_BEGIN( stream ); while ( 1 ) { int ch = AFM_GETC(); if ( AFM_IS_SPACE( ch ) ) break; else if ( AFM_IS_NEWLINE( ch ) ) { stream->status = AFM_STREAM_STATUS_EOL; break; } else if ( AFM_IS_SEP( ch ) ) { stream->status = AFM_STREAM_STATUS_EOC; break; } else if ( AFM_IS_EOF( ch ) ) { stream->status = AFM_STREAM_STATUS_EOF; break; } } return str; } /* read a string (i.e., read to EOL) */ static char* afm_stream_read_string( AFM_Stream stream ) { char* str; afm_stream_skip_spaces( stream ); if ( AFM_STATUS_EOL( stream ) ) return NULL; str = AFM_STREAM_KEY_BEGIN( stream ); /* scan to eol */ while ( 1 ) { int ch = AFM_GETC(); if ( AFM_IS_NEWLINE( ch ) ) { stream->status = AFM_STREAM_STATUS_EOL; break; } else if ( AFM_IS_EOF( ch ) ) { stream->status = AFM_STREAM_STATUS_EOF; break; } } return str; } /************************************************************************** * * AFM_Parser * */ /* all keys defined in Ch. 7-10 of 5004.AFM_Spec.pdf */ typedef enum AFM_Token_ { AFM_TOKEN_ASCENDER, AFM_TOKEN_AXISLABEL, AFM_TOKEN_AXISTYPE, AFM_TOKEN_B, AFM_TOKEN_BLENDAXISTYPES, AFM_TOKEN_BLENDDESIGNMAP, AFM_TOKEN_BLENDDESIGNPOSITIONS, AFM_TOKEN_C, AFM_TOKEN_CC, AFM_TOKEN_CH, AFM_TOKEN_CAPHEIGHT, AFM_TOKEN_CHARWIDTH, AFM_TOKEN_CHARACTERSET, AFM_TOKEN_CHARACTERS, AFM_TOKEN_DESCENDER, AFM_TOKEN_ENCODINGSCHEME, AFM_TOKEN_ENDAXIS, AFM_TOKEN_ENDCHARMETRICS, AFM_TOKEN_ENDCOMPOSITES, AFM_TOKEN_ENDDIRECTION, AFM_TOKEN_ENDFONTMETRICS, AFM_TOKEN_ENDKERNDATA, AFM_TOKEN_ENDKERNPAIRS, AFM_TOKEN_ENDTRACKKERN, AFM_TOKEN_ESCCHAR, AFM_TOKEN_FAMILYNAME, AFM_TOKEN_FONTBBOX, AFM_TOKEN_FONTNAME, AFM_TOKEN_FULLNAME, AFM_TOKEN_ISBASEFONT, AFM_TOKEN_ISCIDFONT, AFM_TOKEN_ISFIXEDPITCH, AFM_TOKEN_ISFIXEDV, AFM_TOKEN_ITALICANGLE, AFM_TOKEN_KP, AFM_TOKEN_KPH, AFM_TOKEN_KPX, AFM_TOKEN_KPY, AFM_TOKEN_L, AFM_TOKEN_MAPPINGSCHEME, AFM_TOKEN_METRICSSETS, AFM_TOKEN_N, AFM_TOKEN_NOTICE, AFM_TOKEN_PCC, AFM_TOKEN_STARTAXIS, AFM_TOKEN_STARTCHARMETRICS, AFM_TOKEN_STARTCOMPOSITES, AFM_TOKEN_STARTDIRECTION, AFM_TOKEN_STARTFONTMETRICS, AFM_TOKEN_STARTKERNDATA, AFM_TOKEN_STARTKERNPAIRS, AFM_TOKEN_STARTKERNPAIRS0, AFM_TOKEN_STARTKERNPAIRS1, AFM_TOKEN_STARTTRACKKERN, AFM_TOKEN_STDHW, AFM_TOKEN_STDVW, AFM_TOKEN_TRACKKERN, AFM_TOKEN_UNDERLINEPOSITION, AFM_TOKEN_UNDERLINETHICKNESS, AFM_TOKEN_VV, AFM_TOKEN_VVECTOR, AFM_TOKEN_VERSION, AFM_TOKEN_W, AFM_TOKEN_W0, AFM_TOKEN_W0X, AFM_TOKEN_W0Y, AFM_TOKEN_W1, AFM_TOKEN_W1X, AFM_TOKEN_W1Y, AFM_TOKEN_WX, AFM_TOKEN_WY, AFM_TOKEN_WEIGHT, AFM_TOKEN_WEIGHTVECTOR, AFM_TOKEN_XHEIGHT, N_AFM_TOKENS, AFM_TOKEN_UNKNOWN } AFM_Token; static const char* const afm_key_table[N_AFM_TOKENS] = { "Ascender", "AxisLabel", "AxisType", "B", "BlendAxisTypes", "BlendDesignMap", "BlendDesignPositions", "C", "CC", "CH", "CapHeight", "CharWidth", "CharacterSet", "Characters", "Descender", "EncodingScheme", "EndAxis", "EndCharMetrics", "EndComposites", "EndDirection", "EndFontMetrics", "EndKernData", "EndKernPairs", "EndTrackKern", "EscChar", "FamilyName", "FontBBox", "FontName", "FullName", "IsBaseFont", "IsCIDFont", "IsFixedPitch", "IsFixedV", "ItalicAngle", "KP", "KPH", "KPX", "KPY", "L", "MappingScheme", "MetricsSets", "N", "Notice", "PCC", "StartAxis", "StartCharMetrics", "StartComposites", "StartDirection", "StartFontMetrics", "StartKernData", "StartKernPairs", "StartKernPairs0", "StartKernPairs1", "StartTrackKern", "StdHW", "StdVW", "TrackKern", "UnderlinePosition", "UnderlineThickness", "VV", "VVector", "Version", "W", "W0", "W0X", "W0Y", "W1", "W1X", "W1Y", "WX", "WY", "Weight", "WeightVector", "XHeight" }; /* * `afm_parser_read_vals' and `afm_parser_next_key' provide * high-level operations to an AFM_Stream. The rest of the * parser functions should use them without accessing the * AFM_Stream directly. */ FT_LOCAL_DEF( FT_Int ) afm_parser_read_vals( AFM_Parser parser, AFM_Value vals, FT_Int n ) { AFM_Stream stream = parser->stream; char* str; FT_Int i; if ( n > AFM_MAX_ARGUMENTS ) return 0; for ( i = 0; i < n; i++ ) { FT_Offset len; AFM_Value val = vals + i; if ( val->type == AFM_VALUE_TYPE_STRING ) str = afm_stream_read_string( stream ); else str = afm_stream_read_one( stream ); if ( !str ) break; len = AFM_STREAM_KEY_LEN( stream, str ); switch ( val->type ) { case AFM_VALUE_TYPE_STRING: case AFM_VALUE_TYPE_NAME: { FT_Memory memory = parser->memory; FT_Error error; if ( !FT_QALLOC( val->u.s, len + 1 ) ) { ft_memcpy( val->u.s, str, len ); val->u.s[len] = '\0'; } } break; case AFM_VALUE_TYPE_FIXED: val->u.f = PS_Conv_ToFixed( (FT_Byte**)(void*)&str, (FT_Byte*)str + len, 0 ); break; case AFM_VALUE_TYPE_INTEGER: val->u.i = PS_Conv_ToInt( (FT_Byte**)(void*)&str, (FT_Byte*)str + len ); break; case AFM_VALUE_TYPE_BOOL: val->u.b = FT_BOOL( len == 4 && !ft_strncmp( str, "true", 4 ) ); break; case AFM_VALUE_TYPE_INDEX: if ( parser->get_index ) val->u.i = parser->get_index( str, len, parser->user_data ); else val->u.i = 0; break; } } return i; } FT_LOCAL_DEF( char* ) afm_parser_next_key( AFM_Parser parser, FT_Bool line, FT_Offset* len ) { AFM_Stream stream = parser->stream; char* key = NULL; /* make stupid compiler happy */ if ( line ) { while ( 1 ) { /* skip current line */ if ( !AFM_STATUS_EOL( stream ) ) afm_stream_read_string( stream ); stream->status = AFM_STREAM_STATUS_NORMAL; key = afm_stream_read_one( stream ); /* skip empty line */ if ( !key && !AFM_STATUS_EOF( stream ) && AFM_STATUS_EOL( stream ) ) continue; break; } } else { while ( 1 ) { /* skip current column */ while ( !AFM_STATUS_EOC( stream ) ) afm_stream_read_one( stream ); stream->status = AFM_STREAM_STATUS_NORMAL; key = afm_stream_read_one( stream ); /* skip empty column */ if ( !key && !AFM_STATUS_EOF( stream ) && AFM_STATUS_EOC( stream ) ) continue; break; } } if ( len ) *len = ( key ) ? (FT_Offset)AFM_STREAM_KEY_LEN( stream, key ) : 0; return key; } static AFM_Token afm_tokenize( const char* key, FT_Offset len ) { int n; for ( n = 0; n < N_AFM_TOKENS; n++ ) { if ( *( afm_key_table[n] ) == *key ) { for ( ; n < N_AFM_TOKENS; n++ ) { if ( *( afm_key_table[n] ) != *key ) return AFM_TOKEN_UNKNOWN; if ( ft_strncmp( afm_key_table[n], key, len ) == 0 ) return (AFM_Token) n; } } } return AFM_TOKEN_UNKNOWN; } FT_LOCAL_DEF( FT_Error ) afm_parser_init( AFM_Parser parser, FT_Memory memory, FT_Byte* base, FT_Byte* limit ) { AFM_Stream stream = NULL; FT_Error error; if ( FT_NEW( stream ) ) return error; stream->cursor = stream->base = base; stream->limit = limit; /* don't skip the first line during the first call */ stream->status = AFM_STREAM_STATUS_EOL; parser->memory = memory; parser->stream = stream; parser->FontInfo = NULL; parser->get_index = NULL; return FT_Err_Ok; } FT_LOCAL( void ) afm_parser_done( AFM_Parser parser ) { FT_Memory memory = parser->memory; FT_FREE( parser->stream ); } static FT_Error afm_parser_read_int( AFM_Parser parser, FT_Int* aint ) { AFM_ValueRec val; val.type = AFM_VALUE_TYPE_INTEGER; if ( afm_parser_read_vals( parser, &val, 1 ) == 1 ) { *aint = val.u.i; return FT_Err_Ok; } else return FT_THROW( Syntax_Error ); } static FT_Error afm_parse_track_kern( AFM_Parser parser ) { AFM_FontInfo fi = parser->FontInfo; AFM_Stream stream = parser->stream; AFM_TrackKern tk; char* key; FT_Offset len; int n = -1; FT_Int tmp; if ( afm_parser_read_int( parser, &tmp ) ) goto Fail; if ( tmp < 0 ) { FT_ERROR(( "afm_parse_track_kern: invalid number of track kerns\n" )); goto Fail; } fi->NumTrackKern = (FT_UInt)tmp; FT_TRACE3(( "afm_parse_track_kern: %u track kern%s expected\n", fi->NumTrackKern, fi->NumTrackKern == 1 ? "" : "s" )); /* Rough sanity check: The minimum line length of the `TrackKern` */ /* command is 20 characters (including the EOL character). */ if ( (FT_ULong)( stream->limit - stream->cursor ) / 20 < fi->NumTrackKern ) { FT_ERROR(( "afm_parse_track_kern:" " number of track kern entries exceeds stream size\n" )); goto Fail; } if ( fi->NumTrackKern ) { FT_Memory memory = parser->memory; FT_Error error; if ( FT_QNEW_ARRAY( fi->TrackKerns, fi->NumTrackKern ) ) return error; } while ( ( key = afm_parser_next_key( parser, 1, &len ) ) != 0 ) { AFM_ValueRec shared_vals[5]; switch ( afm_tokenize( key, len ) ) { case AFM_TOKEN_TRACKKERN: n++; if ( n >= (int)fi->NumTrackKern ) { FT_ERROR(( "afm_parse_track_kern: too many track kern data\n" )); goto Fail; } tk = fi->TrackKerns + n; shared_vals[0].type = AFM_VALUE_TYPE_INTEGER; shared_vals[1].type = AFM_VALUE_TYPE_FIXED; shared_vals[2].type = AFM_VALUE_TYPE_FIXED; shared_vals[3].type = AFM_VALUE_TYPE_FIXED; shared_vals[4].type = AFM_VALUE_TYPE_FIXED; if ( afm_parser_read_vals( parser, shared_vals, 5 ) != 5 ) { FT_ERROR(( "afm_parse_track_kern:" " insufficient number of parameters for entry %d\n", n )); goto Fail; } tk->degree = shared_vals[0].u.i; tk->min_ptsize = shared_vals[1].u.f; tk->min_kern = shared_vals[2].u.f; tk->max_ptsize = shared_vals[3].u.f; tk->max_kern = shared_vals[4].u.f; break; case AFM_TOKEN_ENDTRACKKERN: case AFM_TOKEN_ENDKERNDATA: case AFM_TOKEN_ENDFONTMETRICS: tmp = n + 1; if ( (FT_UInt)tmp != fi->NumTrackKern ) { FT_TRACE1(( "afm_parse_track_kern: %s%d track kern entr%s seen\n", tmp == 0 ? "" : "only ", tmp, tmp == 1 ? "y" : "ies" )); fi->NumTrackKern = (FT_UInt)tmp; } else FT_TRACE3(( "afm_parse_track_kern: %d track kern entr%s seen\n", tmp, tmp == 1 ? "y" : "ies" )); return FT_Err_Ok; case AFM_TOKEN_UNKNOWN: break; default: goto Fail; } } Fail: return FT_THROW( Syntax_Error ); } #undef KERN_INDEX #define KERN_INDEX( g1, g2 ) ( ( (FT_ULong)g1 << 16 ) | g2 ) /* compare two kerning pairs */ FT_COMPARE_DEF( int ) afm_compare_kern_pairs( const void* a, const void* b ) { AFM_KernPair kp1 = (AFM_KernPair)a; AFM_KernPair kp2 = (AFM_KernPair)b; FT_ULong index1 = KERN_INDEX( kp1->index1, kp1->index2 ); FT_ULong index2 = KERN_INDEX( kp2->index1, kp2->index2 ); if ( index1 > index2 ) return 1; else if ( index1 < index2 ) return -1; else return 0; } static FT_Error afm_parse_kern_pairs( AFM_Parser parser ) { AFM_FontInfo fi = parser->FontInfo; AFM_Stream stream = parser->stream; AFM_KernPair kp; char* key; FT_Offset len; int n = -1; FT_Int tmp; if ( afm_parser_read_int( parser, &tmp ) ) goto Fail; if ( tmp < 0 ) { FT_ERROR(( "afm_parse_kern_pairs: invalid number of kern pairs\n" )); goto Fail; } fi->NumKernPair = (FT_UInt)tmp; FT_TRACE3(( "afm_parse_kern_pairs: %u kern pair%s expected\n", fi->NumKernPair, fi->NumKernPair == 1 ? "" : "s" )); /* Rough sanity check: The minimum line length of the `KP`, */ /* `KPH`,`KPX`, and `KPY` commands is 10 characters (including */ /* the EOL character). */ if ( (FT_ULong)( stream->limit - stream->cursor ) / 10 < fi->NumKernPair ) { FT_ERROR(( "afm_parse_kern_pairs:" " number of kern pairs exceeds stream size\n" )); goto Fail; } if ( fi->NumKernPair ) { FT_Memory memory = parser->memory; FT_Error error; if ( FT_QNEW_ARRAY( fi->KernPairs, fi->NumKernPair ) ) return error; } while ( ( key = afm_parser_next_key( parser, 1, &len ) ) != 0 ) { AFM_Token token = afm_tokenize( key, len ); switch ( token ) { case AFM_TOKEN_KP: case AFM_TOKEN_KPX: case AFM_TOKEN_KPY: { FT_Int r; AFM_ValueRec shared_vals[4]; n++; if ( n >= (int)fi->NumKernPair ) { FT_ERROR(( "afm_parse_kern_pairs: too many kern pairs\n" )); goto Fail; } kp = fi->KernPairs + n; shared_vals[0].type = AFM_VALUE_TYPE_INDEX; shared_vals[1].type = AFM_VALUE_TYPE_INDEX; shared_vals[2].type = AFM_VALUE_TYPE_INTEGER; shared_vals[3].type = AFM_VALUE_TYPE_INTEGER; r = afm_parser_read_vals( parser, shared_vals, 4 ); if ( r < 3 ) { FT_ERROR(( "afm_parse_kern_pairs:" " insufficient number of parameters for entry %d\n", n )); goto Fail; } /* index values can't be negative */ kp->index1 = shared_vals[0].u.u; kp->index2 = shared_vals[1].u.u; if ( token == AFM_TOKEN_KPY ) { kp->x = 0; kp->y = shared_vals[2].u.i; } else { kp->x = shared_vals[2].u.i; kp->y = ( token == AFM_TOKEN_KP && r == 4 ) ? shared_vals[3].u.i : 0; } } break; case AFM_TOKEN_ENDKERNPAIRS: case AFM_TOKEN_ENDKERNDATA: case AFM_TOKEN_ENDFONTMETRICS: tmp = n + 1; if ( (FT_UInt)tmp != fi->NumKernPair ) { FT_TRACE1(( "afm_parse_kern_pairs: %s%d kern pair%s seen\n", tmp == 0 ? "" : "only ", tmp, tmp == 1 ? "" : "s" )); fi->NumKernPair = (FT_UInt)tmp; } else FT_TRACE3(( "afm_parse_kern_pairs: %d kern pair%s seen\n", tmp, tmp == 1 ? "" : "s" )); ft_qsort( fi->KernPairs, fi->NumKernPair, sizeof ( AFM_KernPairRec ), afm_compare_kern_pairs ); return FT_Err_Ok; case AFM_TOKEN_UNKNOWN: break; default: goto Fail; } } Fail: return FT_THROW( Syntax_Error ); } static FT_Error afm_parse_kern_data( AFM_Parser parser ) { FT_Error error; char* key; FT_Offset len; int have_trackkern = 0; int have_kernpairs = 0; while ( ( key = afm_parser_next_key( parser, 1, &len ) ) != 0 ) { switch ( afm_tokenize( key, len ) ) { case AFM_TOKEN_STARTTRACKKERN: if ( have_trackkern ) { FT_ERROR(( "afm_parse_kern_data:" " invalid second horizontal track kern section\n" )); goto Fail; } error = afm_parse_track_kern( parser ); if ( error ) return error; have_trackkern = 1; break; case AFM_TOKEN_STARTKERNPAIRS: case AFM_TOKEN_STARTKERNPAIRS0: if ( have_kernpairs ) { FT_ERROR(( "afm_parse_kern_data:" " invalid second horizontal kern pair section\n" )); goto Fail; } error = afm_parse_kern_pairs( parser ); if ( error ) return error; have_kernpairs = 1; break; case AFM_TOKEN_ENDKERNDATA: case AFM_TOKEN_ENDFONTMETRICS: return FT_Err_Ok; case AFM_TOKEN_UNKNOWN: break; default: goto Fail; } } Fail: return FT_THROW( Syntax_Error ); } static FT_Error afm_parser_skip_section( AFM_Parser parser, FT_Int n, AFM_Token end_section ) { char* key; FT_Offset len; while ( n-- > 0 ) { key = afm_parser_next_key( parser, 1, NULL ); if ( !key ) goto Fail; } while ( ( key = afm_parser_next_key( parser, 1, &len ) ) != 0 ) { AFM_Token token = afm_tokenize( key, len ); if ( token == end_section || token == AFM_TOKEN_ENDFONTMETRICS ) return FT_Err_Ok; } Fail: return FT_THROW( Syntax_Error ); } FT_LOCAL_DEF( FT_Error ) afm_parser_parse( AFM_Parser parser ) { FT_Memory memory = parser->memory; AFM_FontInfo fi = parser->FontInfo; FT_Error error = FT_ERR( Syntax_Error ); char* key; FT_Offset len; FT_Int metrics_sets = 0; if ( !fi ) return FT_THROW( Invalid_Argument ); key = afm_parser_next_key( parser, 1, &len ); if ( !key || len != 16 || ft_strncmp( key, "StartFontMetrics", 16 ) != 0 ) return FT_THROW( Unknown_File_Format ); while ( ( key = afm_parser_next_key( parser, 1, &len ) ) != 0 ) { AFM_ValueRec shared_vals[4]; switch ( afm_tokenize( key, len ) ) { case AFM_TOKEN_METRICSSETS: if ( afm_parser_read_int( parser, &metrics_sets ) ) goto Fail; if ( metrics_sets != 0 && metrics_sets != 2 ) { error = FT_THROW( Unimplemented_Feature ); goto Fail; } break; case AFM_TOKEN_ISCIDFONT: shared_vals[0].type = AFM_VALUE_TYPE_BOOL; if ( afm_parser_read_vals( parser, shared_vals, 1 ) != 1 ) goto Fail; fi->IsCIDFont = shared_vals[0].u.b; break; case AFM_TOKEN_FONTBBOX: shared_vals[0].type = AFM_VALUE_TYPE_FIXED; shared_vals[1].type = AFM_VALUE_TYPE_FIXED; shared_vals[2].type = AFM_VALUE_TYPE_FIXED; shared_vals[3].type = AFM_VALUE_TYPE_FIXED; if ( afm_parser_read_vals( parser, shared_vals, 4 ) != 4 ) goto Fail; fi->FontBBox.xMin = shared_vals[0].u.f; fi->FontBBox.yMin = shared_vals[1].u.f; fi->FontBBox.xMax = shared_vals[2].u.f; fi->FontBBox.yMax = shared_vals[3].u.f; break; case AFM_TOKEN_ASCENDER: shared_vals[0].type = AFM_VALUE_TYPE_FIXED; if ( afm_parser_read_vals( parser, shared_vals, 1 ) != 1 ) goto Fail; fi->Ascender = shared_vals[0].u.f; break; case AFM_TOKEN_DESCENDER: shared_vals[0].type = AFM_VALUE_TYPE_FIXED; if ( afm_parser_read_vals( parser, shared_vals, 1 ) != 1 ) goto Fail; fi->Descender = shared_vals[0].u.f; break; case AFM_TOKEN_STARTCHARMETRICS: { FT_Int n = 0; if ( afm_parser_read_int( parser, &n ) ) goto Fail; error = afm_parser_skip_section( parser, n, AFM_TOKEN_ENDCHARMETRICS ); if ( error ) return error; } break; case AFM_TOKEN_STARTKERNDATA: error = afm_parse_kern_data( parser ); if ( error ) goto Fail; /* we only support kern data, so ... */ /* fall through */ case AFM_TOKEN_ENDFONTMETRICS: return FT_Err_Ok; default: break; } } Fail: FT_FREE( fi->TrackKerns ); fi->NumTrackKern = 0; FT_FREE( fi->KernPairs ); fi->NumKernPair = 0; fi->IsCIDFont = 0; return error; } #else /* T1_CONFIG_OPTION_NO_AFM */ /* ANSI C doesn't like empty source files */ typedef int _afm_parse_dummy; #endif /* T1_CONFIG_OPTION_NO_AFM */ /* END */