ref: 81d02dbc04145e0b39e399c8ec6d2e43dc2ac98e
dir: /src/type1/t1gload.c/
/******************************************************************* * * t1gload.c 1.0 * * Type1 Glyph Loader. * * Copyright 1996-1999 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 <t1gload.h> #include <ftdebug.h> #include <ftstream.h> #ifndef T1_CONFIG_OPTION_DISABLE_HINTER #include <t1hinter.h> #endif /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ /********** *********/ /********** *********/ /********** GENERIC CHARSTRINGS PARSING *********/ /********** *********/ /********** *********/ /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ /********************************************************************* * * <Function> * T1_Init_Builder * * <Description> * Initialise a given glyph builder. * * <Input> * builder :: glyph builder to initialise * face :: current face object * size :: current size object * glyph :: current glyph object * funcs :: glyph builder functions (or "methods"). * *********************************************************************/ EXPORT_FUNC void T1_Init_Builder( T1_Builder* builder, T1_Face face, T1_Size size, T1_GlyphSlot glyph, const T1_Builder_Funcs* funcs ) { builder->funcs = *funcs; builder->path_begun = 0; builder->load_points = 1; builder->face = face; builder->size = size; builder->glyph = glyph; builder->memory = face->root.memory; if (glyph) { builder->base = glyph->root.outline; builder->max_points = glyph->max_points; builder->max_contours = glyph->max_contours; } if (size) { builder->scale_x = size->root.metrics.x_scale; builder->scale_y = size->root.metrics.y_scale; } builder->pos_x = 0; builder->pos_y = 0; builder->left_bearing.x = 0; builder->left_bearing.y = 0; builder->advance.x = 0; builder->advance.y = 0; builder->base.n_points = 0; builder->base.n_contours = 0; builder->current = builder->base; builder->pass = 0; builder->hint_point = 0; } /********************************************************************* * * <Function> * T1_Done_Builder * * <Description> * Finalise a given glyph builder. Its content can still be * used after the call, but the function saves important information * within the corresponding glyph slot. * * <Input> * builder :: glyph builder to initialise * *********************************************************************/ EXPORT_FUNC void T1_Done_Builder( T1_Builder* builder ) { T1_GlyphSlot glyph = builder->glyph; if (glyph) { glyph->root.outline = builder->base; glyph->max_points = builder->max_points; glyph->max_contours = builder->max_contours; } } /********************************************************************* * * <Function> * T1_Init_Decoder * * <Description> * Initialise a given Type 1 decoder for parsing * * <Input> * decoder :: Type 1 decoder to initialise * funcs :: hinter functions interface * *********************************************************************/ EXPORT_FUNC void T1_Init_Decoder( T1_Decoder* decoder, const T1_Hinter_Funcs* funcs ) { decoder->hinter = *funcs; /* copy hinter interface */ decoder->top = 0; decoder->zone = 0; decoder->flex_state = 0; decoder->num_flex_vectors = 0; /* Clear loader */ MEM_Set( &decoder->builder, 0, sizeof(decoder->builder) ); } /********************************************************************* * * <Function> * lookup_glyph_by_stdcharcode * * <Description> * Lookup a given glyph by its StandardEncoding charcode. Used * to implement the SEAC Type 1 operator. * * <Input> * face :: current face object * charcode :: charcode to look for * * <Return> * glyph index in font face. Returns -1 if the corresponding * glyph wasn't found. * *********************************************************************/ static T1_Int lookup_glyph_by_stdcharcode( T1_Face face, T1_Int charcode ) { T1_Int n; const T1_String* glyph_name; PSNames_Interface* psnames = (PSNames_Interface*)face->psnames; /* check range of standard char code */ if (charcode < 0 || charcode > 255) return -1; glyph_name = psnames->adobe_std_strings( psnames->adobe_std_encoding[charcode]); for ( n = 0; n < face->type1.num_glyphs; n++ ) { T1_String* name = (T1_String*)face->type1.glyph_names[n]; if ( name && strcmp(name,glyph_name) == 0 ) return n; } return -1; } /********************************************************************* * * <Function> * t1operator_seac * * <Description> * Implements the "seac" Type 1 operator for a Type 1 decoder * * <Input> * decoder :: current Type 1 decoder * asb :: accent's side bearing * adx :: horizontal position of accent * ady :: vertical position of accent * bchar :: base character's StandardEncoding charcode * achar :: accent character's StandardEncoding charcode * * <Return> * Error code. 0 means success. * *********************************************************************/ static T1_Error t1operator_seac( T1_Decoder* decoder, T1_Pos asb, T1_Pos adx, T1_Pos ady, T1_Int bchar, T1_Int achar ) { T1_Error error; T1_Face face = decoder->builder.face; T1_Int bchar_index, achar_index, n_base_points; FT_Outline* cur = &decoder->builder.current; FT_Outline* base = &decoder->builder.base; T1_Vector left_bearing, advance; T1_Font* type1 = &face->type1; bchar_index = lookup_glyph_by_stdcharcode( face, bchar ); achar_index = lookup_glyph_by_stdcharcode( face, achar ); if (bchar_index < 0 || achar_index < 0) { FT_ERROR(( "T1.Parse_Seac : invalid seac character code arguments\n" )); return T1_Err_Syntax_Error; } /* First load "bchar" in builder */ /* now load the unscaled outline */ cur->n_points = 0; cur->n_contours = 0; cur->points = base->points + base->n_points; cur->tags = base->tags + base->n_points; cur->contours = base->contours + base->n_contours; error = T1_Parse_CharStrings( decoder, type1->charstrings [bchar_index], type1->charstrings_len[bchar_index], type1->num_subrs, type1->subrs, type1->subrs_len ); if (error) return error; n_base_points = cur->n_points; if ( decoder->builder.no_recurse ) { /* if we're trying to load a composite glyph, do not load the */ /* accent character and return the array of subglyphs.. */ FT_GlyphSlot glyph = (FT_GlyphSlot)decoder->builder.glyph; FT_SubGlyph* subg; /* reallocate subglyph array if necessary */ if (glyph->max_subglyphs < 2) { FT_Memory memory = decoder->builder.face->root.memory; if ( REALLOC_ARRAY( glyph->subglyphs, glyph->max_subglyphs, 2, FT_SubGlyph ) ) return error; glyph->max_subglyphs = 2; } subg = glyph->subglyphs; /* subglyph 0 = base character */ subg->index = bchar_index; subg->flags = FT_SUBGLYPH_FLAG_ARGS_ARE_XY_VALUES | FT_SUBGLYPH_FLAG_USE_MY_METRICS; subg->arg1 = 0; subg->arg2 = 0; subg++; /* subglyph 1 = accent character */ subg->index = achar_index; subg->flags = FT_SUBGLYPH_FLAG_ARGS_ARE_XY_VALUES; subg->arg1 = adx - asb; subg->arg2 = ady; /* set up remaining glyph fields */ glyph->num_subglyphs = 2; glyph->format = ft_glyph_format_composite; } else { /* save the left bearing and width of the base character */ /* as they will be erased by the next load.. */ left_bearing = decoder->builder.left_bearing; advance = decoder->builder.advance; decoder->builder.left_bearing.x = 0; decoder->builder.left_bearing.y = 0; /* Now load "achar" on top of */ /* the base outline */ /* */ cur->n_points = 0; cur->n_contours = 0; cur->points = base->points + base->n_points; cur->tags = base->tags + base->n_points; cur->contours = base->contours + base->n_contours; error = T1_Parse_CharStrings( decoder, type1->charstrings [achar_index], type1->charstrings_len[achar_index], type1->num_subrs, type1->subrs, type1->subrs_len ); if (error) return error; /* adjust contours in accented character outline */ { T1_Int n; for ( n = 0; n < cur->n_contours; n++ ) cur->contours[n] += n_base_points; } /* restore the left side bearing and */ /* advance width of the base character */ decoder->builder.left_bearing = left_bearing; decoder->builder.advance = advance; /* Finally, move the accent */ FT_Outline_Translate( cur, adx - asb, ady ); } return T1_Err_Ok; } /********************************************************************* * * <Function> * t1operator_flex * * <Description> * Implements the "flex" Type 1 operator for a Type 1 decoder * * <Input> * decoder :: current Type 1 decoder * threshold :: threshold * end_x :: position of final flex point * end_y :: position of final flex point * * <Return> * Error code. 0 means success. * *********************************************************************/ static T1_Error t1operator_flex( T1_Decoder* decoder, T1_Pos threshold, T1_Pos end_x, T1_Pos end_y ) { T1_Vector vec; T1_Vector* flex = decoder->flex_vectors; T1_Int n; /* we don't even try to test the threshold in the non-hinting */ /* builder, even if the flex operator is said to be a path */ /* construction statement in the specification. This is better */ /* left to the hinter.. */ flex = decoder->flex_vectors; vec = *flex++; for ( n = 0; n < 6; n++ ) { flex->x += vec.x; flex->y += vec.y; vec = *flex++; } (void)threshold; (void)end_x; (void)end_y; flex = decoder->flex_vectors; return decoder->builder.funcs.rcurve_to( &decoder->builder, flex[0].x, flex[0].y, flex[1].x, flex[1].y, flex[2].x, flex[2].y ) || decoder->builder.funcs.rcurve_to( &decoder->builder, flex[3].x, flex[3].y, flex[4].x, flex[4].y, flex[5].x, flex[5].y ); } /********************************************************************* * * <Function> * T1_Parse_CharStrings * * <Description> * Parses a given Type 1 charstrings program * * <Input> * decoder :: current Type 1 decoder * charstring_base :: base of the charstring stream * charstring_len :: length in bytes of the charstring stream * num_subrs :: number of sub-routines * subrs_base :: array of sub-routines addresses * subrs_len :: array of sub-routines lengths * * <Return> * Error code. 0 means success. * *********************************************************************/ EXPORT_FUNC T1_Error T1_Parse_CharStrings( T1_Decoder* decoder, T1_Byte* charstring_base, T1_Int charstring_len, T1_Int num_subrs, T1_Byte** subrs_base, T1_Int* subrs_len ) { T1_Error error; T1_Decoder_Zone* zone; T1_Byte* ip; T1_Byte* limit; T1_Builder* builder = &decoder->builder; T1_Builder_Funcs* builds = &builder->funcs; T1_Hinter_Funcs* hints = &decoder->hinter; static const T1_Int args_count[ op_max ] = { 0, /* none */ 0, /* endchar */ 2, /* hsbw */ 5, /* seac */ 4, /* sbw */ 0, /* closepath */ 1, /* hlineto */ 1, /* hmoveto */ 4, /* hvcurveto */ 2, /* rlineto */ 2, /* rmoveto */ 6, /* rrcurveto */ 4, /* vhcurveto */ 1, /* vlineto */ 1, /* vmoveto */ 0, /* dotsection */ 2, /* hstem */ 6, /* hstem3 */ 2, /* vstem */ 6, /* vstem3 */ 2, /* div */ -1, /* callothersubr */ 1, /* callsubr */ 0, /* pop */ 0, /* return */ 2 /* setcurrentpoint */ }; /* First of all, initialise the decoder */ decoder->top = decoder->stack; decoder->zone = decoder->zones; zone = decoder->zones; builder->path_begun = 0; zone->base = charstring_base; limit = zone->limit = charstring_base + charstring_len; ip = zone->cursor = zone->base; error = T1_Err_Ok; /* now, execute loop */ while ( ip < limit ) { T1_Int* top = decoder->top; T1_Operator op = op_none; T1_Long value = 0; /* First of all, decompress operator or value */ switch (*ip++) { case 1: op = op_hstem; break; case 3: op = op_vstem; break; case 4: op = op_vmoveto; break; case 5: op = op_rlineto; break; case 6: op = op_hlineto; break; case 7: op = op_vlineto; break; case 8: op = op_rrcurveto; break; case 9: op = op_closepath; break; case 10: op = op_callsubr; break; case 11: op = op_return; break; case 13: op = op_hsbw; break; case 14: op = op_endchar; break; case 21: op = op_rmoveto; break; case 22: op = op_hmoveto; break; case 30: op = op_vhcurveto; break; case 31: op = op_hvcurveto; break; case 12: { if (ip > limit) { FT_ERROR(( "T1.Parse_CharStrings : invalid escape (12+EOF)\n" )); goto Syntax_Error; } switch (*ip++) { case 0: op = op_dotsection; break; case 1: op = op_vstem3; break; case 2: op = op_hstem3; break; case 6: op = op_seac; break; case 7: op = op_sbw; break; case 12: op = op_div; break; case 16: op = op_callothersubr; break; case 17: op = op_pop; break; case 33: op = op_setcurrentpoint; break; default: FT_ERROR(( "T1.Parse_CharStrings : invalid escape (12+%d)\n", ip[-1] )); goto Syntax_Error; } } break; case 255: /* four bytes integer */ { if (ip+4 > limit) { FT_ERROR(( "T1.Parse_CharStrings : unexpected EOF in integer\n" )); goto Syntax_Error; } value = ((long)ip[0] << 24) | ((long)ip[1] << 16) | ((long)ip[2] << 8) | ip[3]; ip += 4; } break; default: if (ip[-1] >= 32) { if (ip[-1] < 247) value = (long)ip[-1] - 139; else { if (++ip > limit) { FT_ERROR(( "T1.Parse_CharStrings : unexpected EOF in integer\n" )); goto Syntax_Error; } if (ip[-2] < 251) value = ((long)(ip[-2]-247) << 8) + ip[-1] + 108; else value = -((((long)ip[-2]-251) << 8) + ip[-1] + 108 ); } } else { FT_ERROR(( "T1.Parse_CharStrings : invalid byte (%d)\n", ip[-1] )); goto Syntax_Error; } } /* push value if needed */ if ( op == op_none ) { if ( top - decoder->stack >= T1_MAX_CHARSTRINGS_OPERANDS ) { FT_ERROR(( "T1.Parse_CharStrings : Stack overflow !!\n" )); goto Syntax_Error; } *top++ = value; decoder->top = top; } else if ( op == op_callothersubr ) /* check arguments differently */ { if ( top - decoder->stack < 2) goto Stack_Underflow; top -= 2; switch (top[1]) { case 1: /* start flex feature ----------------------------- */ { if (top[0] != 0) goto Unexpected_OtherSubr; decoder->flex_state = 1; decoder->num_flex_vectors = 0; decoder->flex_vectors[0].x = 0; decoder->flex_vectors[0].y = 0; } break; case 2: /* add flex vector ------------------------------- */ { T1_Int index; T1_Vector* flex; if (top[0] != 0) goto Unexpected_OtherSubr; top -= 2; if (top < decoder->stack) goto Stack_Underflow; index = decoder->num_flex_vectors++; if (index >= 7) { FT_ERROR(( "T1.Parse_CharStrings: too many flex vectors !\n" )); goto Syntax_Error; } flex = decoder->flex_vectors + index; flex->x += top[0]; flex->y += top[1]; } break; case 0: /* end flex feature ------------------------------ */ { if ( decoder->flex_state == 0 || decoder->num_flex_vectors != 7 ) { FT_ERROR(( "T1.Parse_CharStrings: unexpected flex end\n" )); goto Syntax_Error; } if (top[0] != 3) goto Unexpected_OtherSubr; top -= 3; if (top < decoder->stack) goto Stack_Underflow; /* now consume the remaining "pop pop setcurrentpoint" */ if ( ip+6 > limit || ip[0] != 12 || ip[1] != 17 || /* pop */ ip[2] != 12 || ip[3] != 17 || /* pop */ ip[4] != 12 || ip[5] != 33 ) /* setcurrentpoint */ { FT_ERROR(( "T1.Parse_CharStrings: invalid flex charstring\n" )); goto Syntax_Error; } decoder->flex_state = 0; decoder->top = top; error = t1operator_flex( decoder, top[0], top[1], top[2] ); } break; case 3: /* change hints ------------------------------------ */ { if (top[0] != 1) goto Unexpected_OtherSubr; /* eat the following "pop" */ if (ip+2 > limit) { FT_ERROR(( "T1.Parse_CharStrings: invalid escape (12+%d)\n", ip[-1] )); goto Syntax_Error; } if (ip[0] != 12 || ip[1] != 17) { FT_ERROR(( "T1.Parse_CharStrings: 'pop' expected, found (%d %d)\n", ip[0], ip[1] )); goto Syntax_Error; } ip += 2; error = hints->change_hints(builder); } break; default: /* invalid OtherSubrs call */ Unexpected_OtherSubr: FT_ERROR(( "T1.Parse_CharStrings: unexpected OtherSubrs [%d %d]\n", top[0], top[1] )); goto Syntax_Error; } decoder->top = top; } else { T1_Int num_args = args_count[op]; if ( top - decoder->stack < num_args ) goto Stack_Underflow; top -= num_args; switch (op) { case op_endchar: error = builds->end_char( builder ); break; case op_hsbw: error = builds->set_bearing_point( builder, top[0], 0, top[1], 0 ); break; case op_seac: /* return immediately after the processing */ return t1operator_seac( decoder, top[0], top[1], top[2], top[3], top[4] ); case op_sbw: error = builds->set_bearing_point( builder, top[0], top[1], top[2], top[3] ); break; case op_closepath: error = builds->close_path( builder ); break; case op_hlineto: error = builds->rline_to( builder, top[0], 0 ); break; case op_hmoveto: error = builds->rmove_to( builder, top[0], 0 ); break; case op_hvcurveto: error = builds->rcurve_to( builder, top[0], 0, top[1], top[2], 0, top[3] ); break; case op_rlineto: error = builds->rline_to( builder, top[0], top[1] ); break; case op_rmoveto: /* ignore operator when in flex mode */ if (decoder->flex_state == 0) error = builds->rmove_to( builder, top[0], top[1] ); else top += 2; break; case op_rrcurveto: { error = builds->rcurve_to( builder, top[0], top[1], top[2], top[3], top[4], top[5] ); } break; case op_vhcurveto: error = builds->rcurve_to( builder, 0, top[0], top[1], top[2], top[3], 0 ); break; case op_vlineto: error = builds->rline_to( builder, 0, top[0] ); break; case op_vmoveto: error = builds->rmove_to( builder, 0, top[0] ); break; case op_dotsection: error = hints->dot_section( builder ); break; case op_hstem: error = hints->stem( builder, top[0], top[1], 0 ); break; case op_hstem3: error = hints->stem3( builder, top[0], top[1], top[2], top[3], top[4], top[5], 0 ); break; case op_vstem: error = hints->stem( builder, top[0], top[1], 1 ); break; case op_vstem3: error = hints->stem3( builder, top[0], top[1], top[2], top[3], top[4], top[5], 1 ); break; case op_div: if (top[1]) *top++ = top[0] / top[1]; else { FT_ERROR(( "T1.Parse_CHarStrings : division by 0\n" )); goto Syntax_Error; } break; case op_callsubr: { T1_Int index = top[0]; if ( index < 0 || index >= num_subrs ) { FT_ERROR(( "T1.Parse_CharStrings : invalid subrs index\n" )); goto Syntax_Error; } if ( zone - decoder->zones >= T1_MAX_SUBRS_CALLS ) { FT_ERROR(( "T1.Parse_CharStrings : too many nested subrs\n" )); goto Syntax_Error; } zone->cursor = ip; /* save current instruction pointer */ zone++; zone->base = subrs_base[index]; zone->limit = zone->base + subrs_len[index]; zone->cursor = zone->base; if (!zone->base) { FT_ERROR(( "T1.Parse_CharStrings : invoking empty subrs !!\n" )); goto Syntax_Error; } decoder->zone = zone; ip = zone->base; limit = zone->limit; } break; case op_pop: FT_ERROR(( "T1.Parse_CharStrings : unexpected POP\n" )); goto Syntax_Error; case op_return: if ( zone <= decoder->zones ) { FT_ERROR(( "T1.Parse_CharStrings : unexpected return\n" )); goto Syntax_Error; } zone--; ip = zone->cursor; limit = zone->limit; decoder->zone = zone; break; case op_setcurrentpoint: FT_ERROR(( "T1.Parse_CharStrings : unexpected SETCURRENTPOINT\n" )); goto Syntax_Error; break; default: FT_ERROR(( "T1.Parse_CharStrings : unhandled opcode %d\n", op )); goto Syntax_Error; } decoder->top = top; } } return error; Syntax_Error: return T1_Err_Syntax_Error; Stack_Underflow: return T1_Err_Stack_Underflow; } /*************************************************************************/ /* */ /* <Function> T1_Add_Points */ /* */ /* <Description> */ /* Checks that there is enough room in the current load glyph outline */ /* to accept "num_points" additional outline points. If not, this */ /* function grows the load outline's arrays accordingly.. */ /* */ /* <Input> */ /* builder :: pointer to glyph builder object */ /* num_points :: number of points that will be added later */ /* */ /* <Return> */ /* Type1 error code. 0 means success */ /* */ /* <Note> */ /* This function does NOT update the points count in the glyph builder*/ /* This must be done by the caller itself, after this function is */ /* invoked.. */ /* */ LOCAL_FUNC T1_Error T1_Add_Points( T1_Builder* builder, T1_Int num_points ) { T1_Int new_points; new_points = builder->base.n_points + builder->current.n_points + num_points; if ( new_points > builder->max_points ) { FT_Memory memory = builder->memory; T1_Error error; T1_Int increment = builder->current.points - builder->base.points; T1_Int current = builder->max_points; while ( builder->max_points < new_points ) builder->max_points += 16; if ( REALLOC_ARRAY( builder->base.points, current, builder->max_points, T1_Vector ) || REALLOC_ARRAY( builder->base.tags, current, builder->max_points, T1_Byte ) ) return error; builder->current.points = builder->base.points + increment; builder->current.tags = builder->base.tags + increment; } return T1_Err_Ok; } /*************************************************************************/ /* */ /* <Function> T1_Add_Contours */ /* */ /* <Description> */ /* Checks that there is enough room in the current load glyph outline */ /* to accept "num_contours" additional contours. If not, this func */ /* the load outline's arrays accordingly.. */ /* */ /* <Input> */ /* builder :: pointer to glyph builder object */ /* num_contours :: number of contours that will be added later */ /* */ /* <Return> */ /* Type1 error code. 0 means success */ /* */ /* <Note> */ /* This function does NOT update the contours count in the load glyph */ /* This must be done by the caller itself, after this function is */ /* invoked.. */ /* */ LOCAL_FUNC T1_Error T1_Add_Contours( T1_Builder* builder, T1_Int num_contours ) { T1_Int new_contours; new_contours = builder->base.n_contours + builder->current.n_contours + num_contours; if ( new_contours > builder->max_contours && builder->load_points ) { T1_Error error; FT_Memory memory = builder->memory; T1_Int increment = builder->current.contours - builder->base.contours; T1_Int current = builder->max_contours; while ( builder->max_contours < new_contours ) builder->max_contours += 4; if ( REALLOC_ARRAY( builder->base.contours, current, builder->max_contours, T1_Short ) ) return error; builder->current.contours = builder->base.contours + increment; } return T1_Err_Ok; } /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ /********** *********/ /********** *********/ /********** COMPUTE THE MAXIMUM ADVANCE WIDTH *********/ /********** *********/ /********** The following code is in charge of computing *********/ /********** the maximum advance width of the font. It *********/ /********** quickly process each glyph charstring to *********/ /********** extract the value from either a "sbw" or "seac" *********/ /********** operator. *********/ /********** *********/ /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ static T1_Error maxadv_sbw( T1_Decoder* decoder, T1_Pos sbx, T1_Pos sby, T1_Pos wx, T1_Pos wy ) { if (wx > decoder->builder.advance.x) decoder->builder.advance.x = wx; (void)sbx; (void)sby; (void)wy; return -1; /* return an error code to exit the Type 1 parser */ /* immediately. */ } static T1_Int maxadv_error( void ) { /* we should never reach this code, unless with a buggy font */ return -2; } /* the maxadv_gbuilder_interface is used when computing the maximum */ /* advance width of all glyphs in a given font. We only process the */ /* 'sbw' operator here, and return an error for all others.. */ /* Note that "seac" is processed by the T1_Decoder */ static const T1_Builder_Funcs maxadv_builder_interface = { (T1_Builder_EndChar) maxadv_error, (T1_Builder_Sbw) maxadv_sbw, (T1_Builder_ClosePath) maxadv_error, (T1_Builder_RLineTo) maxadv_error, (T1_Builder_RMoveTo) maxadv_error, (T1_Builder_RCurveTo) maxadv_error }; /* the maxadv_interface is used when computing the maximum advance */ /* with of the set of glyphs in a given font file. We only process */ /* the "seac" operator and return immediately.. */ static const T1_Hinter_Funcs maxadv_hinter_interface = { (T1_Hinter_DotSection) maxadv_error, (T1_Hinter_ChangeHints) maxadv_error, (T1_Hinter_Stem) maxadv_error, (T1_Hinter_Stem3) maxadv_error, }; LOCAL_FUNC T1_Error T1_Compute_Max_Advance( T1_Face face, T1_Int *max_advance ) { T1_Error error; T1_Decoder decoder; T1_Int glyph_index; T1_Font* type1 = &face->type1; *max_advance = 0; /* Initialise load decoder */ T1_Init_Decoder( &decoder, &maxadv_hinter_interface ); T1_Init_Builder( &decoder.builder, face, 0, 0, &maxadv_builder_interface ); /* For each glyph, parse the glyph charstring and extract */ /* the advance width.. */ for ( glyph_index = 0; glyph_index < type1->num_glyphs; glyph_index++ ) { /* now get load the unscaled outline */ error = T1_Parse_CharStrings( &decoder, type1->charstrings [glyph_index], type1->charstrings_len[glyph_index], type1->num_subrs, type1->subrs, type1->subrs_len ); /* ignore the error if one occured - skip to next glyph */ (void)error; } *max_advance = decoder.builder.advance.x; return T1_Err_Ok; } /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ /********** *********/ /********** *********/ /********** UNHINTED GLYPH LOADER *********/ /********** *********/ /********** The following code is in charge of loading a *********/ /********** single outline. It completely ignores hinting *********/ /********** and is used when FT_LOAD_NO_HINTING is set. *********/ /********** *********/ /********** The Type 1 hinter is located in "t1hint.c" *********/ /********** *********/ /**********************************************************************/ /**********************************************************************/ /**********************************************************************/ static T1_Error close_open_path( T1_Builder* builder ) { T1_Error error; FT_Outline* cur = &builder->current; T1_Int num_points; T1_Int first_point; /* Some fonts, like Hershey, are made of "open paths" which are */ /* now managed directly by FreeType. In this case, it is necessary */ /* to close the path by duplicating its points in reverse order, */ /* which is precisely the purpose of this function */ /* first compute the number of points to duplicate.. */ if (cur->n_contours > 1) first_point = cur->contours[ cur->n_contours-2 ]+1; else first_point = 0; num_points = cur->n_points - first_point - 2; if ( num_points > 0 ) { T1_Vector* source_point; char* source_tags; T1_Vector* point; char* tags; error = T1_Add_Points( builder, num_points ); if (error) return error; point = cur->points + cur->n_points; tags = cur->tags + cur->n_points; source_point = point - 2; source_tags = tags - 2; cur->n_points += num_points; if ( builder->load_points ) do { *point++ = *source_point--; *tags++ = *source_tags--; num_points--; } while (num_points > 0); } builder->path_begun = 0; return T1_Err_Ok; } static T1_Error gload_closepath( T1_Builder* builder ) { FT_Outline* cur = &builder->current; /* save current contour, if any */ if ( cur->n_contours > 0 ) cur->contours[cur->n_contours-1] = cur->n_points-1; #ifndef T1_CONFIG_OPTION_DISABLE_HINTER /* hint latest points if needed - this is not strictly required */ /* there, but it helps for debugging, and doesn't affect performance */ if ( builder->pass == 1 ) T1_Hint_Points( builder ); #endif builder->path_begun = 0; return T1_Err_Ok; } static T1_Error gload_endchar( T1_Builder* builder ) { FT_Outline* cur = &builder->current; T1_Error error; /* close path if needed */ if (builder->path_begun) { error = close_open_path( builder ); if (error) return error; } error = gload_closepath( builder ); builder->base.n_points += cur->n_points; builder->base.n_contours += cur->n_contours; return error; } static T1_Error gload_sbw( T1_Builder* builder, T1_Pos sbx, T1_Pos sby, T1_Pos wx, T1_Pos wy ) { builder->left_bearing.x += sbx; builder->left_bearing.y += sby; builder->advance.x = wx; builder->advance.y = wy; builder->last.x = sbx; builder->last.y = sby; return 0; } static T1_Error gload_rlineto( T1_Builder* builder, T1_Pos dx, T1_Pos dy ) { T1_Error error; FT_Outline* cur = &builder->current; T1_Vector vec; /* grow buffer if necessary */ error = T1_Add_Points ( builder, 1 ); if (error) return error; if ( builder->load_points ) { /* save point */ vec.x = builder->last.x + dx; vec.y = builder->last.y + dy; cur->points[cur->n_points] = vec; cur->tags [cur->n_points] = FT_Curve_Tag_On; builder->last = vec; } cur->n_points++; builder->path_begun = 1; return T1_Err_Ok; } static T1_Error gload_rmoveto( T1_Builder* builder, T1_Pos dx, T1_Pos dy ) { T1_Error error; FT_Outline* cur = &builder->current; T1_Vector vec; /* in the case where "path_begun" is set, we have a rmoveto */ /* after some normal path definition. When the face's paint */ /* type is set to 1, this means that we have an "open path", */ /* also called a 'stroke'. The FreeType raster doesn't support */ /* opened path, so we'll close it explicitely there.. */ if ( builder->path_begun && builder->face->type1.paint_type == 1 ) { if ( builder->face->type1.paint_type == 1 ) { error = close_open_path( builder ); if (error) return error; } } /* grow buffer if necessary */ error = T1_Add_Contours( builder, 1 ) || T1_Add_Points ( builder, 1 ); if (error) return error; /* save current contour, if any */ if ( cur->n_contours > 0 ) cur->contours[cur->n_contours-1] = cur->n_points-1; if ( builder->load_points ) { /* save point */ vec.x = builder->last.x + dx; vec.y = builder->last.y + dy; cur->points[cur->n_points] = vec; cur->tags [cur->n_points] = FT_Curve_Tag_On; builder->last = vec; } cur->n_contours++; cur->n_points++; return T1_Err_Ok; } static T1_Error gload_rrcurveto( T1_Builder* builder, T1_Pos dx1, T1_Pos dy1, T1_Pos dx2, T1_Pos dy2, T1_Pos dx3, T1_Pos dy3 ) { T1_Error error; FT_Outline* cur = &builder->current; T1_Vector vec; T1_Vector* points; char* tags; /* grow buffer if necessary */ error = T1_Add_Points ( builder, 3 ); if (error) return error; if ( builder->load_points ) { /* save point */ points = cur->points + cur->n_points; tags = cur->tags + cur->n_points; vec.x = builder->last.x + dx1; vec.y = builder->last.y + dy1; points[0] = vec; tags[0] = FT_Curve_Tag_Cubic; vec.x += dx2; vec.y += dy2; points[1] = vec; tags[1] = FT_Curve_Tag_Cubic; vec.x += dx3; vec.y += dy3; points[2] = vec; tags[2] = FT_Curve_Tag_On; builder->last = vec; } cur->n_points += 3; builder->path_begun = 1; return T1_Err_Ok; } static T1_Error gload_ignore( void ) { return 0; } static const T1_Builder_Funcs gload_builder_interface = { gload_endchar, gload_sbw, gload_closepath, gload_rlineto, gload_rmoveto, gload_rrcurveto }; static const T1_Builder_Funcs gload_builder_interface_null = { (T1_Builder_EndChar) gload_ignore, (T1_Builder_Sbw) gload_sbw, /* record left bearing */ (T1_Builder_ClosePath) gload_ignore, (T1_Builder_RLineTo) gload_ignore, (T1_Builder_RMoveTo) gload_ignore, (T1_Builder_RCurveTo) gload_ignore }; static const T1_Hinter_Funcs gload_hinter_interface = { (T1_Hinter_DotSection) gload_ignore, /* dotsection */ (T1_Hinter_ChangeHints) gload_ignore, /* changehints */ (T1_Hinter_Stem) gload_ignore, /* hstem & vstem */ (T1_Hinter_Stem3) gload_ignore, /* hstem3 & vestem3 */ }; LOCAL_FUNC T1_Error T1_Load_Glyph( T1_GlyphSlot glyph, T1_Size size, T1_Int glyph_index, T1_Int load_flags ) { T1_Error error; T1_Decoder decoder; T1_Face face = (T1_Face)glyph->root.face; T1_Bool hinting; T1_Font* type1 = &face->type1; if (load_flags & FT_LOAD_NO_RECURSE) load_flags |= FT_LOAD_NO_SCALE | FT_LOAD_NO_HINTING; glyph->x_scale = size->root.metrics.x_scale; glyph->y_scale = size->root.metrics.y_scale; glyph->root.outline.n_points = 0; glyph->root.outline.n_contours = 0; glyph->root.format = ft_glyph_format_none; hinting = 0; #ifndef T1_CONFIG_OPTION_DISABLE_HINTER /*****************************************************************/ /* */ /* Hinter overview : */ /* */ /* This is a two-pass hinter. On the first pass, the hints */ /* are all recorded by the hinter, and no point is loaded */ /* in the outline. */ /* */ /* When the first pass is finished, all stems hints are */ /* grid-fitted at once. */ /* */ /* Then, a second pass is performed to load the outline */ /* points as well as hint/scale them correctly. */ /* */ hinting = (load_flags & (FT_LOAD_NO_SCALE|FT_LOAD_NO_HINTING)) == 0; if ( hinting ) { /* Pass 1 - don't record points, simply stem hints */ T1_Init_Decoder( &decoder, &t1_hinter_funcs ); T1_Init_Builder( &decoder.builder, face, size, glyph, &gload_builder_interface_null ); glyph->hints->hori_stems.num_stems = 0; glyph->hints->vert_stems.num_stems = 0; error = T1_Parse_CharStrings( &decoder, type1->charstrings [glyph_index], type1->charstrings_len[glyph_index], type1->num_subrs, type1->subrs, type1->subrs_len ); /* All right, pass 1 is finished, now grid-fit all stem hints */ T1_Hint_Stems( &decoder.builder ); /* Pass 2 - record and scale/hint the points */ T1_Init_Decoder( &decoder, &t1_hinter_funcs ); T1_Init_Builder( &decoder.builder, face, size, glyph, &gload_builder_interface ); decoder.builder.pass = 1; decoder.builder.no_recurse = 0; error = T1_Parse_CharStrings( &decoder, type1->charstrings [glyph_index], type1->charstrings_len[glyph_index], type1->num_subrs, type1->subrs, type1->subrs_len ); /* save new glyph tables */ T1_Done_Builder( &decoder.builder ); } else #endif { T1_Init_Decoder( &decoder, &gload_hinter_interface ); T1_Init_Builder( &decoder.builder, face, size, glyph, &gload_builder_interface ); decoder.builder.no_recurse = !!(load_flags & FT_LOAD_NO_RECURSE); /* now load the unscaled outline */ error = T1_Parse_CharStrings( &decoder, type1->charstrings [glyph_index], type1->charstrings_len[glyph_index], type1->num_subrs, type1->subrs, type1->subrs_len ); /* save new glyph tables */ T1_Done_Builder( &decoder.builder ); } /* Now, set the metrics.. - this is rather simple, as : */ /* the left side bearing is the xMin, and the top side */ /* bearing the yMax.. */ if (!error) { /* for composite glyphs, return only the left side bearing and the */ /* advance width.. */ if ( load_flags & FT_LOAD_NO_RECURSE ) { glyph->root.metrics.horiBearingX = decoder.builder.left_bearing.x; glyph->root.metrics.horiAdvance = decoder.builder.advance.x; } else { FT_BBox cbox; FT_Glyph_Metrics* metrics = &glyph->root.metrics; FT_Outline_Get_CBox( &glyph->root.outline, &cbox ); /* grid fit the bounding box if necessary */ if (hinting) { cbox.xMin &= -64; cbox.yMin &= -64; cbox.xMax = ( cbox.xMax+63 ) & -64; cbox.yMax = ( cbox.yMax+63 ) & -64; } metrics->width = cbox.xMax - cbox.xMin; metrics->height = cbox.yMax - cbox.yMin; metrics->horiBearingX = cbox.xMin; metrics->horiBearingY = cbox.yMax; /* copy the _unscaled_ advance width */ metrics->horiAdvance = decoder.builder.advance.x; /* make up vertical metrics */ metrics->vertBearingX = 0; metrics->vertBearingY = 0; metrics->vertAdvance = 0; glyph->root.format = ft_glyph_format_outline; glyph->root.outline.flags &= ft_outline_owner; if ( size->root.metrics.y_ppem < 24 ) glyph->root.outline.flags |= ft_outline_high_precision; glyph->root.outline.flags |= ft_outline_reverse_fill; /* glyph->root.outline.second_pass = TRUE; glyph->root.outline.high_precision = ( size->root.metrics.y_ppem < 24 ); glyph->root.outline.dropout_mode = 2; */ if ( hinting ) { /* adjust the advance width */ /* XXX : TODO : consider stem hints grid-fit */ metrics->horiAdvance = FT_MulFix( metrics->horiAdvance, glyph->x_scale ); } else if ( (load_flags & FT_LOAD_NO_SCALE) == 0 ) { /* scale the outline and the metrics */ T1_Int n; FT_Outline* cur = &decoder.builder.base; T1_Vector* vec = cur->points; T1_Fixed x_scale = glyph->x_scale; T1_Fixed y_scale = glyph->y_scale; /* First of all, scale the points */ for ( n = cur->n_points; n > 0; n--, vec++ ) { vec->x = FT_MulFix( vec->x, x_scale ); vec->y = FT_MulFix( vec->y, y_scale ); } /* Then scale the metrics */ metrics->width = FT_MulFix( metrics->width, x_scale ); metrics->height = FT_MulFix( metrics->height, y_scale ); metrics->horiBearingX = FT_MulFix( metrics->horiBearingX, x_scale ); metrics->horiBearingY = FT_MulFix( metrics->horiBearingY, y_scale ); metrics->horiAdvance = FT_MulFix( metrics->horiAdvance, x_scale ); metrics->vertBearingX = FT_MulFix( metrics->vertBearingX, x_scale ); metrics->vertBearingY = FT_MulFix( metrics->vertBearingY, y_scale ); metrics->vertAdvance = FT_MulFix( metrics->vertAdvance, x_scale ); } } } return error; }