ref: 3574643bc0d1b04f4a6da2ffa3f6a6fc9818bc0a
dir: /src/type1/t1load.c/
/***************************************************************************/ /* */ /* t1load.c */ /* */ /* Type 1 font loader (body). */ /* */ /* 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. */ /* */ /***************************************************************************/ /*************************************************************************/ /* */ /* This is the new and improved Type 1 data loader for FreeType 2. The */ /* old loader has several problems: it is slow, complex, difficult to */ /* maintain, and contains incredible hacks to make it accept some */ /* ill-formed Type 1 fonts without hiccup-ing. Moreover, about 5% of */ /* the Type 1 fonts on my machine still aren't loaded correctly by it. */ /* */ /* This version is much simpler, much faster and also easier to read and */ /* maintain by a great order of magnitude. The idea behind it is to */ /* _not_ try to read the Type 1 token stream with a state machine (i.e. */ /* a Postscript-like interpreter) but rather to perform simple pattern */ /* matching. */ /* */ /* Indeed, nearly all data definitions follow a simple pattern like */ /* */ /* ... /Field <data> ... */ /* */ /* where <data> can be a number, a boolean, a string, or an array of */ /* numbers. There are a few exceptions, namely the encoding, font name, */ /* charstrings, and subrs; they are handled with a special pattern */ /* matching routine. */ /* */ /* All other common cases are handled very simply. The matching rules */ /* are defined in the file `t1tokens.h' through the use of several */ /* macros calls PARSE_XXX. */ /* */ /* This file is included twice here; the first time to generate parsing */ /* callback functions, the second to generate a table of keywords (with */ /* pointers to the associated callback). */ /* */ /* The function `parse_dict' simply scans *linearly* a given dictionary */ /* (either the top-level or private one) and calls the appropriate */ /* callback when it encounters an immediate keyword. */ /* */ /* This is by far the fastest way one can find to parse and read all */ /* data. */ /* */ /* This led to tremendous code size reduction. Note that later, the */ /* glyph loader will also be _greatly_ simplified, and the automatic */ /* hinter will replace the clumsy `t1hinter'. */ /* */ /*************************************************************************/ #include <freetype/internal/ftdebug.h> #include <freetype/config/ftconfig.h> #include <freetype/ftmm.h> #include <freetype/internal/t1types.h> #include <freetype/internal/t1errors.h> #ifdef FT_FLAT_COMPILE #include "t1load.h" #else #include <type1/t1load.h> #endif #include <string.h> /* for strncmp(), strcmp() */ #include <ctype.h> /* for isalnum() */ /*************************************************************************/ /* */ /* The macro FT_COMPONENT is used in trace mode. It is an implicit */ /* parameter of the FT_TRACE() and FT_ERROR() macros, used to print/log */ /* messages during execution. */ /* */ #undef FT_COMPONENT #define FT_COMPONENT trace_t1load #ifndef T1_CONFIG_OPTION_NO_MM_SUPPORT /*************************************************************************/ /*************************************************************************/ /***** *****/ /***** MULTIPLE MASTERS SUPPORT *****/ /***** *****/ /*************************************************************************/ /*************************************************************************/ static FT_Error t1_allocate_blend( T1_Face face, FT_UInt num_designs, FT_UInt num_axis ) { T1_Blend* blend; FT_Memory memory = face->root.memory; FT_Error error = 0; blend = face->blend; if ( !blend ) { if ( ALLOC( blend, sizeof ( *blend ) ) ) goto Exit; face->blend = blend; } /* allocate design data if needed */ if ( num_designs > 0 ) { if ( blend->num_designs == 0 ) { FT_UInt nn; /* allocate the blend `private' and `font_info' dictionaries */ if ( ALLOC_ARRAY( blend->font_infos[1], num_designs, T1_FontInfo ) || ALLOC_ARRAY( blend->privates[1], num_designs, T1_Private ) || ALLOC_ARRAY( blend->weight_vector, num_designs * 2, FT_Fixed ) ) goto Exit; blend->default_weight_vector = blend->weight_vector + num_designs; blend->font_infos[0] = &face->type1.font_info; blend->privates [0] = &face->type1.private_dict; for ( nn = 2; nn <= num_designs; nn++ ) { blend->privates[nn] = blend->privates [nn - 1] + 1; blend->font_infos[nn] = blend->font_infos[nn - 1] + 1; } blend->num_designs = num_designs; } else if ( blend->num_designs != num_designs ) goto Fail; } /* allocate axis data if needed */ if ( num_axis > 0 ) { if ( blend->num_axis != 0 && blend->num_axis != num_axis ) goto Fail; blend->num_axis = num_axis; } /* allocate the blend design pos table if needed */ num_designs = blend->num_designs; num_axis = blend->num_axis; if ( num_designs && num_axis && blend->design_pos[0] == 0 ) { FT_UInt n; if ( ALLOC_ARRAY( blend->design_pos[0], num_designs * num_axis, FT_Fixed ) ) goto Exit; for ( n = 1; n < num_designs; n++ ) blend->design_pos[n] = blend->design_pos[0] + num_axis * n; } Exit: return error; Fail: error = -1; goto Exit; } FT_LOCAL_DEF FT_Error T1_Get_Multi_Master( T1_Face face, FT_Multi_Master* master ) { T1_Blend* blend = face->blend; FT_UInt n; FT_Error error; error = T1_Err_Invalid_Argument; if ( blend ) { master->num_axis = blend->num_axis; master->num_designs = blend->num_designs; for ( n = 0; n < blend->num_axis; n++ ) { FT_MM_Axis* axis = master->axis + n; T1_DesignMap* map = blend->design_map + n; axis->name = blend->axis_names[n]; axis->minimum = map->design_points[0]; axis->maximum = map->design_points[map->num_points - 1]; } error = 0; } return error; } FT_LOCAL_DEF FT_Error T1_Set_MM_Blend( T1_Face face, FT_UInt num_coords, FT_Fixed* coords ) { T1_Blend* blend = face->blend; FT_Error error; FT_UInt n, m; error = T1_Err_Invalid_Argument; if ( blend && blend->num_axis == num_coords ) { /* recompute the weight vector from the blend coordinates */ error = FT_Err_Ok; for ( n = 0; n < blend->num_designs; n++ ) { FT_Fixed result = 0x10000L; /* 1.0 fixed */ for ( m = 0; m < blend->num_axis; m++ ) { FT_Fixed factor; /* get current blend axis position */ factor = coords[m]; if ( factor < 0 ) factor = 0; if ( factor > 0x10000L ) factor = 0x10000L; if ( ( n & ( 1 << m ) ) == 0 ) factor = 0x10000L - factor; result = FT_MulFix( result, factor ); } blend->weight_vector[n] = result; } error = FT_Err_Ok; } return error; } FT_LOCAL_DEF FT_Error T1_Set_MM_Design( T1_Face face, FT_UInt num_coords, FT_Long* coords ) { T1_Blend* blend = face->blend; FT_Error error; FT_UInt n, p; error = T1_Err_Invalid_Argument; if ( blend && blend->num_axis == num_coords ) { /* compute the blend coordinates through the blend design map */ FT_Fixed final_blends[T1_MAX_MM_DESIGNS]; for ( n = 0; n < blend->num_axis; n++ ) { FT_Long design = coords[n]; FT_Fixed the_blend; T1_DesignMap* map = blend->design_map + n; FT_Fixed* designs = map->design_points; FT_Fixed* blends = map->blend_points; FT_Int before = -1, after = -1; for ( p = 0; p < map->num_points; p++ ) { FT_Fixed p_design = designs[p]; /* exact match ? */ if ( design == p_design ) { the_blend = blends[p]; goto Found; } if ( design < p_design ) { after = p; break; } before = p; } /* now, interpolate if needed */ if ( before < 0 ) the_blend = blends[0]; else if ( after < 0 ) the_blend = blends[map->num_points - 1]; else the_blend = FT_MulDiv( design - designs[before], blends [after] - blends [before], designs[after] - designs[before] ); Found: final_blends[n] = the_blend; } error = T1_Set_MM_Blend( face, num_coords, final_blends ); } return error; } FT_LOCAL_DEF void T1_Done_Blend( T1_Face face ) { FT_Memory memory = face->root.memory; T1_Blend* blend = face->blend; if ( blend ) { FT_UInt num_designs = blend->num_designs; FT_UInt num_axis = blend->num_axis; FT_UInt n; /* release design pos table */ FREE( blend->design_pos[0] ); for ( n = 1; n < num_designs; n++ ) blend->design_pos[n] = 0; /* release blend `private' and `font info' dictionaries */ FREE( blend->privates[1] ); FREE( blend->font_infos[1] ); for ( n = 0; n < num_designs; n++ ) { blend->privates [n] = 0; blend->font_infos[n] = 0; } /* release weight vectors */ FREE( blend->weight_vector ); blend->default_weight_vector = 0; /* release axis names */ for ( n = 0; n < num_axis; n++ ) FREE( blend->axis_names[n] ); /* release design map */ for ( n = 0; n < num_axis; n++ ) { T1_DesignMap* dmap = blend->design_map + n; FREE( dmap->design_points ); dmap->num_points = 0; } FREE( face->blend ); } } static void parse_blend_axis_types( T1_Face face, T1_Loader* loader ) { T1_Token axis_tokens[ T1_MAX_MM_AXIS ]; FT_Int n, num_axis; FT_Error error = 0; T1_Blend* blend; FT_Memory memory; /* take an array of objects */ T1_ToTokenArray( &loader->parser, axis_tokens, T1_MAX_MM_AXIS, &num_axis ); if ( num_axis <= 0 || num_axis > T1_MAX_MM_AXIS ) { FT_ERROR(( "parse_blend_axis_types: incorrect number of axes: %d\n", num_axis )); error = T1_Err_Invalid_File_Format; goto Exit; } /* allocate blend if necessary */ error = t1_allocate_blend( face, 0, (FT_UInt)num_axis ); if ( error ) goto Exit; blend = face->blend; memory = face->root.memory; /* each token is an immediate containing the name of the axis */ for ( n = 0; n < num_axis; n++ ) { T1_Token* token = axis_tokens + n; FT_Byte* name; FT_Int len; /* skip first slash, if any */ if (token->start[0] == '/') token->start++; len = token->limit - token->start; if ( len <= 0 ) { error = T1_Err_Invalid_File_Format; goto Exit; } if ( ALLOC( blend->axis_names[n], len + 1 ) ) goto Exit; name = (FT_Byte*)blend->axis_names[n]; MEM_Copy( name, token->start, len ); name[len] = 0; } Exit: loader->parser.root.error = error; } static void parse_blend_design_positions( T1_Face face, T1_Loader* loader ) { T1_Token design_tokens[ T1_MAX_MM_DESIGNS ]; FT_Int num_designs; FT_Int num_axis; T1_ParserRec* parser = &loader->parser; FT_Error error = 0; T1_Blend* blend; /* get the array of design tokens - compute number of designs */ T1_ToTokenArray( parser, design_tokens, T1_MAX_MM_DESIGNS, &num_designs ); if ( num_designs <= 0 || num_designs > T1_MAX_MM_DESIGNS ) { FT_ERROR(( "parse_blend_design_positions:" )); FT_ERROR(( " incorrect number of designs: %d\n", num_designs )); error = T1_Err_Invalid_File_Format; goto Exit; } { FT_Byte* old_cursor = parser->root.cursor; FT_Byte* old_limit = parser->root.limit; FT_UInt n; blend = face->blend; num_axis = 0; /* make compiler happy */ for ( n = 0; n < (FT_UInt)num_designs; n++ ) { T1_Token axis_tokens[ T1_MAX_MM_DESIGNS ]; T1_Token* token; FT_Int axis, n_axis; /* read axis/coordinates tokens */ token = design_tokens + n; parser->root.cursor = token->start - 1; parser->root.limit = token->limit + 1; T1_ToTokenArray( parser, axis_tokens, T1_MAX_MM_AXIS, &n_axis ); if ( n == 0 ) { num_axis = n_axis; error = t1_allocate_blend( face, num_designs, num_axis ); if ( error ) goto Exit; blend = face->blend; } else if ( n_axis != num_axis ) { FT_ERROR(( "parse_blend_design_positions: incorrect table\n" )); error = T1_Err_Invalid_File_Format; goto Exit; } /* now, read each axis token into the design position */ for ( axis = 0; axis < n_axis; axis++ ) { T1_Token* token2 = axis_tokens + axis; parser->root.cursor = token2->start; parser->root.limit = token2->limit; blend->design_pos[n][axis] = T1_ToFixed( parser, 0 ); } } loader->parser.root.cursor = old_cursor; loader->parser.root.limit = old_limit; } Exit: loader->parser.root.error = error; } static void parse_blend_design_map( T1_Face face, T1_Loader* loader ) { FT_Error error = 0; T1_ParserRec* parser = &loader->parser; T1_Blend* blend; T1_Token axis_tokens[ T1_MAX_MM_AXIS ]; FT_Int n, num_axis; FT_Byte* old_cursor; FT_Byte* old_limit; FT_Memory memory = face->root.memory; T1_ToTokenArray( parser, axis_tokens, T1_MAX_MM_AXIS, &num_axis ); if ( num_axis <= 0 || num_axis > T1_MAX_MM_AXIS ) { FT_ERROR(( "parse_blend_design_map: incorrect number of axes: %d\n", num_axis )); error = T1_Err_Invalid_File_Format; goto Exit; } old_cursor = parser->root.cursor; old_limit = parser->root.limit; error = t1_allocate_blend( face, 0, num_axis ); if ( error ) goto Exit; blend = face->blend; /* now, read each axis design map */ for ( n = 0; n < num_axis; n++ ) { T1_DesignMap* map = blend->design_map + n; T1_Token* token; FT_Int p, num_points; token = axis_tokens + n; parser->root.cursor = token->start; parser->root.limit = token->limit; /* count the number of map points */ { FT_Byte* ptr = token->start; FT_Byte* limit = token->limit; num_points = 0; for ( ; ptr < limit; ptr++ ) if ( ptr[0] == '[' ) num_points++; } if ( num_points <= 0 || num_points > T1_MAX_MM_MAP_POINTS ) { FT_ERROR(( "parse_blend_design_map: incorrect table\n" )); error = T1_Err_Invalid_File_Format; goto Exit; } /* allocate design map data */ if ( ALLOC_ARRAY( map->design_points, num_points * 2, FT_Fixed ) ) goto Exit; map->blend_points = map->design_points + num_points; map->num_points = (FT_Byte)num_points; for ( p = 0; p < num_points; p++ ) { map->design_points[p] = T1_ToInt( parser ); map->blend_points [p] = T1_ToFixed( parser, 0 ); } } parser->root.cursor = old_cursor; parser->root.limit = old_limit; Exit: parser->root.error = error; } static void parse_weight_vector( T1_Face face, T1_Loader* loader ) { FT_Error error = 0; T1_ParserRec* parser = &loader->parser; T1_Blend* blend = face->blend; T1_Token master; FT_UInt n; FT_Byte* old_cursor; FT_Byte* old_limit; if ( !blend || blend->num_designs == 0 ) { FT_ERROR(( "parse_weight_vector: too early!\n" )); error = T1_Err_Invalid_File_Format; goto Exit; } T1_ToToken( parser, &master ); if ( master.type != t1_token_array ) { FT_ERROR(( "parse_weight_vector: incorrect format!\n" )); error = T1_Err_Invalid_File_Format; goto Exit; } old_cursor = parser->root.cursor; old_limit = parser->root.limit; parser->root.cursor = master.start; parser->root.limit = master.limit; for ( n = 0; n < blend->num_designs; n++ ) { blend->default_weight_vector[n] = blend->weight_vector[n] = T1_ToFixed( parser, 0 ); } parser->root.cursor = old_cursor; parser->root.limit = old_limit; Exit: parser->root.error = error; } /* the keyword `/shareddict' appears in some multiple master fonts */ /* with a lot of Postscript garbage behind it (that's completely out */ /* of spec!); we detect it and terminate the parsing */ /* */ static void parse_shared_dict( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; FT_UNUSED( face ); parser->root.cursor = parser->root.limit; parser->root.error = 0; } #endif /* T1_CONFIG_OPTION_NO_MM_SUPPORT */ /*************************************************************************/ /*************************************************************************/ /***** *****/ /***** TYPE 1 SYMBOL PARSING *****/ /***** *****/ /*************************************************************************/ /*************************************************************************/ /*************************************************************************/ /* */ /* First of all, define the token field static variables. This is a set */ /* of T1_Field variables used later. */ /* */ /*************************************************************************/ static FT_Error t1_load_keyword( T1_Face face, T1_Loader* loader, T1_Field* field ) { FT_Error error; void* dummy_object; void** objects; FT_UInt max_objects; T1_Blend* blend = face->blend; /* if the keyword has a dedicated callback, call it */ if ( field->type == t1_field_callback ) { field->reader( (FT_Face)face, loader ); error = loader->parser.root.error; goto Exit; } /* now, the keyword is either a simple field, or a table of fields; */ /* we are now going to take care of it */ switch ( field->location ) { case t1_field_font_info: dummy_object = &face->type1.font_info; objects = &dummy_object; max_objects = 0; if ( blend ) { objects = (void**)blend->font_infos; max_objects = blend->num_designs; } break; case t1_field_private: dummy_object = &face->type1.private_dict; objects = &dummy_object; max_objects = 0; if ( blend ) { objects = (void**)blend->privates; max_objects = blend->num_designs; } break; default: dummy_object = &face->type1; objects = &dummy_object; max_objects = 0; } if ( field->type == t1_field_integer_array || field->type == t1_field_fixed_array ) error = T1_Load_Field_Table( &loader->parser, field, objects, max_objects, 0 ); else error = T1_Load_Field( &loader->parser, field, objects, max_objects, 0 ); Exit: return error; } static int is_space( FT_Byte c ) { return ( c == ' ' || c == '\t' || c == '\r' || c == '\n' ); } static int is_alpha( FT_Byte c ) { return ( isalnum( c ) || c == '.' || c == '_' ); } static int read_binary_data( T1_ParserRec* parser, FT_Int* size, FT_Byte** base ) { FT_Byte* cur; FT_Byte* limit = parser->root.limit; /* the binary data has the following format */ /* */ /* `size' [white*] RD white ....... ND */ /* */ T1_Skip_Spaces( parser ); cur = parser->root.cursor; if ( cur < limit && (FT_Byte)( *cur - '0' ) < 10 ) { *size = T1_ToInt( parser ); T1_Skip_Spaces( parser ); T1_Skip_Alpha ( parser ); /* `RD' or `-|' or something else */ /* there is only one whitespace char after the */ /* `RD' or `-|' token */ *base = parser->root.cursor + 1; parser->root.cursor += *size + 1; return 1; } FT_ERROR(( "read_binary_data: invalid size field\n" )); parser->root.error = T1_Err_Invalid_File_Format; return 0; } /* we will now define the routines used to handle */ /* the `/Encoding', `/Subrs', and `/CharStrings' */ /* dictionaries */ static void parse_font_name( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; FT_Error error; FT_Memory memory = parser->root.memory; FT_Int len; FT_Byte* cur; FT_Byte* cur2; FT_Byte* limit; T1_Skip_Spaces( parser ); cur = parser->root.cursor; limit = parser->root.limit; if ( cur >= limit - 1 || *cur != '/' ) return; cur++; cur2 = cur; while ( cur2 < limit && is_alpha( *cur2 ) ) cur2++; len = cur2 - cur; if ( len > 0 ) { if ( ALLOC( face->type1.font_name, len + 1 ) ) { parser->root.error = error; return; } MEM_Copy( face->type1.font_name, cur, len ); face->type1.font_name[len] = '\0'; } parser->root.cursor = cur2; } static void parse_font_bbox( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; FT_Short temp[4]; FT_BBox* bbox = &face->type1.font_bbox; (void)T1_ToCoordArray( parser, 4, temp ); bbox->xMin = temp[0]; bbox->yMin = temp[1]; bbox->xMax = temp[2]; bbox->yMax = temp[3]; } static void parse_font_matrix( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; FT_Matrix* matrix = &face->type1.font_matrix; FT_Vector* offset = &face->type1.font_offset; FT_Fixed temp[6]; if ( matrix->xx || matrix->yx ) /* with synthetic fonts, it's possible we get here twice */ return; (void)T1_ToFixedArray( parser, 6, temp, 3 ); /* we need to scale the values by 1.0/temp[3] */ if ( temp[3] != 0x10000L ) { temp[0] = FT_DivFix( temp[0], temp[3] ); temp[1] = FT_DivFix( temp[1], temp[3] ); temp[2] = FT_DivFix( temp[2], temp[3] ); temp[4] = FT_DivFix( temp[4], temp[3] ); temp[5] = FT_DivFix( temp[5], temp[3] ); temp[3] = 0x10000L; } matrix->xx = temp[0]; matrix->yx = temp[1]; matrix->xy = temp[2]; matrix->yy = temp[3]; /* note that the offsets must be expressed in integer font units */ offset->x = temp[4] >> 16; offset->y = temp[5] >> 16; } static void parse_encoding( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; FT_Byte* cur = parser->root.cursor; FT_Byte* limit = parser->root.limit; PSAux_Interface* psaux = (PSAux_Interface*)face->psaux; /* skip whitespace */ while ( is_space( *cur ) ) { cur++; if ( cur >= limit ) { FT_ERROR(( "parse_encoding: out of bounds!\n" )); parser->root.error = T1_Err_Invalid_File_Format; return; } } /* if we have a number, then the encoding is an array, */ /* and we must load it now */ if ( (FT_Byte)( *cur - '0' ) < 10 ) { T1_Encoding* encode = &face->type1.encoding; FT_Int count, n; PS_Table* char_table = &loader->encoding_table; FT_Memory memory = parser->root.memory; FT_Error error; /* read the number of entries in the encoding, should be 256 */ count = T1_ToInt( parser ); if ( parser->root.error ) return; /* we use a T1_Table to store our charnames */ encode->num_chars = count; if ( ALLOC_ARRAY( encode->char_index, count, FT_Short ) || ALLOC_ARRAY( encode->char_name, count, FT_String* ) || ( error = psaux->ps_table_funcs->init( char_table, count, memory ) ) != 0 ) { parser->root.error = error; return; } /* We need to `zero' out encoding_table.elements */ for ( n = 0; n < count; n++ ) { char* notdef = (char *)".notdef"; T1_Add_Table( char_table, n, notdef, 8 ); } /* Now, we will need to read a record of the form */ /* ... charcode /charname ... for each entry in our table */ /* */ /* We simply look for a number followed by an immediate */ /* name. Note that this ignores correctly the sequence */ /* that is often seen in type1 fonts: */ /* */ /* 0 1 255 { 1 index exch /.notdef put } for dup */ /* */ /* used to clean the encoding array before anything else. */ /* */ /* We stop when we encounter a `def'. */ cur = parser->root.cursor; limit = parser->root.limit; n = 0; for ( ; cur < limit; ) { FT_Byte c; c = *cur; /* we stop when we encounter a `def' */ if ( c == 'd' && cur + 3 < limit ) { if ( cur[1] == 'e' && cur[2] == 'f' && is_space(cur[-1]) && is_space(cur[3]) ) { FT_TRACE6(( "encoding end\n" )); break; } } /* otherwise, we must find a number before anything else */ if ( (FT_Byte)( c - '0' ) < 10 ) { FT_Int charcode; parser->root.cursor = cur; charcode = T1_ToInt( parser ); cur = parser->root.cursor; /* skip whitespace */ while ( cur < limit && is_space( *cur ) ) cur++; if ( cur < limit && *cur == '/' ) { /* bingo, we have an immediate name -- it must be a */ /* character name */ FT_Byte* cur2 = cur + 1; FT_Int len; while ( cur2 < limit && is_alpha( *cur2 ) ) cur2++; len = cur2 - cur - 1; parser->root.error = T1_Add_Table( char_table, charcode, cur + 1, len + 1 ); char_table->elements[charcode][len] = '\0'; if ( parser->root.error ) return; cur = cur2; } } else cur++; } face->type1.encoding_type = t1_encoding_array; parser->root.cursor = cur; } /* Otherwise, we should have either `StandardEncoding' or */ /* `ExpertEncoding' */ else { if ( cur + 17 < limit && strncmp( (const char*)cur, "StandardEncoding", 16 ) == 0 ) face->type1.encoding_type = t1_encoding_standard; else if ( cur + 15 < limit && strncmp( (const char*)cur, "ExpertEncoding", 14 ) == 0 ) face->type1.encoding_type = t1_encoding_expert; else { FT_ERROR(( "parse_encoding: invalid token!\n" )); parser->root.error = T1_Err_Invalid_File_Format; } } } static void parse_subrs( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; PS_Table* table = &loader->subrs; FT_Memory memory = parser->root.memory; FT_Error error; FT_Int n; PSAux_Interface* psaux = (PSAux_Interface*)face->psaux; loader->num_subrs = T1_ToInt( parser ); if ( parser->root.error ) return; /* position the parser right before the `dup' of the first subr */ T1_Skip_Spaces( parser ); T1_Skip_Alpha( parser ); /* `array' */ T1_Skip_Spaces( parser ); /* initialize subrs array */ error = psaux->ps_table_funcs->init( table, loader->num_subrs, memory ); if ( error ) goto Fail; /* the format is simple: */ /* */ /* `index' + binary data */ /* */ for ( n = 0; n < loader->num_subrs; n++ ) { FT_Int index, size; FT_Byte* base; /* If the next token isn't `dup', we are also done. This */ /* happens when there are `holes' in the Subrs array. */ if ( strncmp( (char*)parser->root.cursor, "dup", 3 ) != 0 ) break; index = T1_ToInt( parser ); if ( !read_binary_data( parser, &size, &base ) ) return; /* The binary string is followed by one token, e.g. `NP' */ /* (bound to `noaccess put') or by two separate tokens: */ /* `noaccess' & `put'. We position the parser right */ /* before the next `dup', if any. */ T1_Skip_Spaces( parser ); T1_Skip_Alpha( parser ); /* `NP' or `I' or `noaccess' */ T1_Skip_Spaces( parser ); if ( strncmp( (char*)parser->root.cursor, "put", 3 ) == 0 ) { T1_Skip_Alpha( parser ); /* skip `put' */ T1_Skip_Spaces( parser ); } /* some fonts use a value of -1 for lenIV to indicate that */ /* the charstrings are unencoded */ /* */ /* thanks to Tom Kacvinsky for pointing this out */ /* */ if ( face->type1.private_dict.lenIV >= 0 ) { T1_Decrypt( base, size, 4330 ); size -= face->type1.private_dict.lenIV; base += face->type1.private_dict.lenIV; } error = T1_Add_Table( table, index, base, size ); if ( error ) goto Fail; } return; Fail: parser->root.error = error; } static void parse_charstrings( T1_Face face, T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; PS_Table* code_table = &loader->charstrings; PS_Table* name_table = &loader->glyph_names; FT_Memory memory = parser->root.memory; FT_Error error; PSAux_Interface* psaux = (PSAux_Interface*)face->psaux; FT_Byte* cur; FT_Byte* limit = parser->root.limit; FT_Int n; FT_UInt notdef_index = 0; FT_Byte notdef_found = 0; if ( loader->num_glyphs ) /* with synthetic fonts, it's possible we get here twice */ return; loader->num_glyphs = T1_ToInt( parser ); if ( parser->root.error ) return; /* initialize tables, adding space for `swap' at table end */ error = psaux->ps_table_funcs->init( code_table, loader->num_glyphs + 1, memory ); if ( error ) goto Fail; error = psaux->ps_table_funcs->init( name_table, loader->num_glyphs + 1, memory ); if ( error ) goto Fail; n = 0; for (;;) { FT_Int size; FT_Byte* base; /* the format is simple: */ /* `/glyphname' + binary data */ /* */ /* note that we stop when we find a `def' */ /* */ T1_Skip_Spaces( parser ); cur = parser->root.cursor; if ( cur >= limit ) break; /* we stop when we find a `def' or `end' keyword */ if ( *cur == 'd' && cur + 3 < limit && cur[1] == 'e' && cur[2] == 'f' ) break; if ( *cur == 'e' && cur + 3 < limit && cur[1] == 'n' && cur[2] == 'd' ) break; if ( *cur != '/' ) T1_Skip_Alpha( parser ); else { FT_Byte* cur2 = cur + 1; FT_Int len; while ( cur2 < limit && is_alpha( *cur2 ) ) cur2++; len = cur2 - cur - 1; error = T1_Add_Table( name_table, n, cur + 1, len + 1 ); if ( error ) goto Fail; /* add a trailing zero to the name table */ name_table->elements[n][len] = '\0'; /* record index of /.notdef */ if ( strcmp( (const char*)".notdef", (const char*)(name_table->elements[n]) ) == 0 ) { notdef_index = n; notdef_found = 1; } parser->root.cursor = cur2; if ( !read_binary_data( parser, &size, &base ) ) return; if ( face->type1.private_dict.lenIV >= 0 ) { T1_Decrypt( base, size, 4330 ); size -= face->type1.private_dict.lenIV; base += face->type1.private_dict.lenIV; } error = T1_Add_Table( code_table, n, base, size ); if ( error ) goto Fail; n++; if ( n >= loader->num_glyphs ) break; } } loader->num_glyphs = n; /* if /.notdef is found but does not occupy index 0, do our magic. */ if ( strcmp( (const char*)".notdef", (const char*)name_table->elements[0] ) && notdef_found ) { /* Swap glyph in index 0 with /.notdef glyph. First, add index 0 */ /* name/code to end of table. Then place notdef_index name/code into */ /* index 0. Then take end of table name/code and place it into index */ /* notdef_index. */ error = T1_Add_Table( name_table, n, name_table->elements[0], name_table->lengths [0] ); if ( error ) goto Fail; error = T1_Add_Table( code_table, n, code_table->elements[0], code_table->lengths [0] ); if ( error ) goto Fail; error = T1_Add_Table( name_table, 0, name_table->elements[notdef_index], name_table->lengths [notdef_index] ); if ( error ) goto Fail; error = T1_Add_Table( code_table, 0, code_table->elements[notdef_index], code_table->lengths [notdef_index] ); if ( error ) goto Fail; error = T1_Add_Table( name_table, notdef_index, name_table->elements[n], name_table->lengths [n] ); if ( error ) goto Fail; error = T1_Add_Table( code_table, notdef_index, code_table->elements[n], code_table->lengths [n] ); if ( error ) goto Fail; } else if ( !notdef_found ) { /* notdef_index is already 0, or /.notdef is undefined in */ /* charstrings dictionary. Worry about /.notdef undefined. */ /* we take index 0 and add it to the end of the table(s) */ /* and add our own /.notdef glyph to index 0. */ /* 0 333 hsbw endchar */ FT_Byte notdef_glyph[] = {0x8B, 0xF7, 0xE1, 0x0D, 0x0E}; char* notdef_name = (char *)".notdef"; error = T1_Add_Table( name_table, n, name_table->elements[0], name_table->lengths [0] ); if ( error ) goto Fail; error = T1_Add_Table( code_table, n, code_table->elements[0], code_table->lengths [0] ); if ( error ) goto Fail; error = T1_Add_Table( name_table, 0, notdef_name, 8 ); if ( error ) goto Fail; error = T1_Add_Table( code_table, 0, notdef_glyph, 5 ); if ( error ) goto Fail; /* we added a glyph. */ loader->num_glyphs = n + 1; } return; Fail: parser->root.error = error; } static const T1_Field t1_keywords[] = { #ifdef FT_FLAT_COMPILE #include "t1tokens.h" #else #include <type1/t1tokens.h> #endif /* now add the special functions... */ T1_FIELD_CALLBACK( "FontName", parse_font_name ) T1_FIELD_CALLBACK( "FontBBox", parse_font_bbox ) T1_FIELD_CALLBACK( "FontMatrix", parse_font_matrix ) T1_FIELD_CALLBACK( "Encoding", parse_encoding ) T1_FIELD_CALLBACK( "Subrs", parse_subrs ) T1_FIELD_CALLBACK( "CharStrings", parse_charstrings ) #ifndef T1_CONFIG_OPTION_NO_MM_SUPPORT T1_FIELD_CALLBACK( "BlendDesignPositions", parse_blend_design_positions ) T1_FIELD_CALLBACK( "BlendDesignMap", parse_blend_design_map ) T1_FIELD_CALLBACK( "BlendAxisTypes", parse_blend_axis_types ) T1_FIELD_CALLBACK( "WeightVector", parse_weight_vector ) T1_FIELD_CALLBACK( "shareddict", parse_shared_dict ) #endif { 0, t1_field_cid_info, t1_field_none, 0, 0, 0, 0, 0 } }; static FT_Error parse_dict( T1_Face face, T1_Loader* loader, FT_Byte* base, FT_Long size ) { T1_ParserRec* parser = &loader->parser; parser->root.cursor = base; parser->root.limit = base + size; parser->root.error = 0; { FT_Byte* cur = base; FT_Byte* limit = cur + size; for ( ; cur < limit; cur++ ) { /* look for `FontDirectory', which causes problems on some fonts */ if ( *cur == 'F' && cur + 25 < limit && strncmp( (char*)cur, "FontDirectory", 13 ) == 0 ) { FT_Byte* cur2; /* skip the `FontDirectory' keyword */ cur += 13; cur2 = cur; /* lookup the `known' keyword */ while ( cur < limit && *cur != 'k' && strncmp( (char*)cur, "known", 5 ) ) cur++; if ( cur < limit ) { T1_Token token; /* skip the `known' keyword and the token following it */ cur += 5; loader->parser.root.cursor = cur; T1_ToToken( &loader->parser, &token ); /* if the last token was an array, skip it! */ if ( token.type == t1_token_array ) cur2 = parser->root.cursor; } cur = cur2; } /* look for immediates */ else if ( *cur == '/' && cur + 2 < limit ) { FT_Byte* cur2; FT_Int len; cur++; cur2 = cur; while ( cur2 < limit && is_alpha( *cur2 ) ) cur2++; len = cur2 - cur; if ( len > 0 && len < 22 ) { if ( !loader->fontdata ) { if ( strncmp( (char*)cur, "FontInfo", 8 ) == 0 ) loader->fontdata = 1; } else { /* now, compare the immediate name to the keyword table */ T1_Field* keyword = (T1_Field*)t1_keywords; for (;;) { FT_Byte* name; name = (FT_Byte*)keyword->ident; if ( !name ) break; if ( cur[0] == name[0] && len == (FT_Int)strlen( (const char*)name ) ) { FT_Int n; for ( n = 1; n < len; n++ ) if ( cur[n] != name[n] ) break; if ( n >= len ) { /* we found it -- run the parsing callback! */ parser->root.cursor = cur2; T1_Skip_Spaces( parser ); parser->root.error = t1_load_keyword( face, loader, keyword ); if ( parser->root.error ) return parser->root.error; cur = parser->root.cursor; break; } } keyword++; } } } } } } return parser->root.error; } static void t1_init_loader( T1_Loader* loader, T1_Face face ) { FT_UNUSED( face ); MEM_Set( loader, 0, sizeof ( *loader ) ); loader->num_glyphs = 0; loader->num_chars = 0; /* initialize the tables -- simply set their `init' field to 0 */ loader->encoding_table.init = 0; loader->charstrings.init = 0; loader->glyph_names.init = 0; loader->subrs.init = 0; loader->fontdata = 0; } static void t1_done_loader( T1_Loader* loader ) { T1_ParserRec* parser = &loader->parser; /* finalize tables */ T1_Release_Table( &loader->encoding_table ); T1_Release_Table( &loader->charstrings ); T1_Release_Table( &loader->glyph_names ); T1_Release_Table( &loader->subrs ); /* finalize parser */ T1_Done_Parser( parser ); } FT_LOCAL_DEF FT_Error T1_Open_Face( T1_Face face ) { T1_Loader loader; T1_ParserRec* parser; T1_Font* type1 = &face->type1; FT_Error error; PSAux_Interface* psaux = (PSAux_Interface*)face->psaux; t1_init_loader( &loader, face ); /* default lenIV */ type1->private_dict.lenIV = 4; parser = &loader.parser; error = T1_New_Parser( parser, face->root.stream, face->root.memory, psaux ); if ( error ) goto Exit; error = parse_dict( face, &loader, parser->base_dict, parser->base_len ); if ( error ) goto Exit; error = T1_Get_Private_Dict( parser ); if ( error ) goto Exit; error = parse_dict( face, &loader, parser->private_dict, parser->private_len ); if ( error ) goto Exit; /* now, propagate the subrs, charstrings, and glyphnames tables */ /* to the Type1 data */ type1->num_glyphs = loader.num_glyphs; if ( !loader.subrs.init ) { FT_ERROR(( "T1_Open_Face: no subrs array in face!\n" )); error = T1_Err_Invalid_File_Format; } if ( !loader.charstrings.init ) { FT_ERROR(( "T1_Open_Face: no charstrings array in face!\n" )); error = T1_Err_Invalid_File_Format; } loader.subrs.init = 0; type1->num_subrs = loader.num_subrs; type1->subrs_block = loader.subrs.block; type1->subrs = loader.subrs.elements; type1->subrs_len = loader.subrs.lengths; loader.charstrings.init = 0; type1->charstrings_block = loader.charstrings.block; type1->charstrings = loader.charstrings.elements; type1->charstrings_len = loader.charstrings.lengths; /* we copy the glyph names `block' and `elements' fields; */ /* the `lengths' field must be released later */ type1->glyph_names_block = loader.glyph_names.block; type1->glyph_names = (FT_String**)loader.glyph_names.elements; loader.glyph_names.block = 0; loader.glyph_names.elements = 0; /* we must now build type1.encoding when we have a custom */ /* array.. */ if ( type1->encoding_type == t1_encoding_array ) { FT_Int charcode, index, min_char, max_char; FT_Byte* char_name; FT_Byte* glyph_name; /* OK, we do the following: for each element in the encoding */ /* table, look up the index of the glyph having the same name */ /* the index is then stored in type1.encoding.char_index, and */ /* a the name to type1.encoding.char_name */ min_char = +32000; max_char = -32000; charcode = 0; for ( ; charcode < loader.encoding_table.max_elems; charcode++ ) { type1->encoding.char_index[charcode] = 0; type1->encoding.char_name [charcode] = (char *)".notdef"; char_name = loader.encoding_table.elements[charcode]; if ( char_name ) for ( index = 0; index < type1->num_glyphs; index++ ) { glyph_name = (FT_Byte*)type1->glyph_names[index]; if ( strcmp( (const char*)char_name, (const char*)glyph_name ) == 0 ) { type1->encoding.char_index[charcode] = index; type1->encoding.char_name [charcode] = (char*)glyph_name; /* Change min/max encoded char only if glyph name is */ /* not /.notdef */ if ( strcmp( (const char*)".notdef", (const char*)glyph_name ) != 0 ) { if (charcode < min_char) min_char = charcode; if (charcode > max_char) max_char = charcode; } break; } } } type1->encoding.code_first = min_char; type1->encoding.code_last = max_char; type1->encoding.num_chars = loader.num_chars; } Exit: t1_done_loader( &loader ); return error; } /* END */