📄 ftsynth.c
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/***************************************************************************//* *//* ftsynth.c *//* *//* FreeType synthesizing code for emboldening and slanting (body). *//* *//* Copyright 2000-2001, 2002 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 <ft2build.h>#include FT_INTERNAL_OBJECTS_H#include FT_INTERNAL_CALC_H#include FT_OUTLINE_H#include FT_TRIGONOMETRY_H#include FT_SYNTHESIS_H#define FT_BOLD_THRESHOLD 0x0100 /*************************************************************************/ /*************************************************************************/ /**** ****/ /**** EXPERIMENTAL OBLIQUING SUPPORT ****/ /**** ****/ /*************************************************************************/ /*************************************************************************/ FT_EXPORT_DEF( void ) FT_GlyphSlot_Oblique( FT_GlyphSlot slot ) { FT_Matrix transform; FT_Outline* outline = &slot->outline; /* only oblique outline glyphs */ if ( slot->format != FT_GLYPH_FORMAT_OUTLINE ) return; /* we don't touch the advance width */ /* For italic, simply apply a shear transform, with an angle */ /* of about 12 degrees. */ transform.xx = 0x10000L; transform.yx = 0x00000L; transform.xy = 0x06000L; transform.yy = 0x10000L; FT_Outline_Transform( outline, &transform ); } /*************************************************************************/ /*************************************************************************/ /**** ****/ /**** EXPERIMENTAL EMBOLDENING/OUTLINING SUPPORT ****/ /**** ****/ /*************************************************************************/ /*************************************************************************/ static int ft_test_extrema( FT_Outline* outline, int n ) { FT_Vector *prev, *cur, *next; FT_Pos product; FT_Int c, first, last; /* we need to compute the `previous' and `next' point */ /* for these extrema. */ cur = outline->points + n; prev = cur - 1; next = cur + 1; first = 0; for ( c = 0; c < outline->n_contours; c++ ) { last = outline->contours[c]; if ( n == first ) prev = outline->points + last; if ( n == last ) next = outline->points + first; first = last + 1; } product = FT_MulDiv( cur->x - prev->x, /* in.x */ next->y - cur->y, /* out.y */ 0x40 ) - FT_MulDiv( cur->y - prev->y, /* in.y */ next->x - cur->x, /* out.x */ 0x40 ); if ( product ) product = product > 0 ? 1 : -1; return product; } /* Compute the orientation of path filling. It differs between TrueType */ /* and Type1 formats. We could use the `FT_OUTLINE_REVERSE_FILL' flag, */ /* but it is better to re-compute it directly (it seems that this flag */ /* isn't correctly set for some weird composite glyphs currently). */ /* */ /* We do this by computing bounding box points, and computing their */ /* curvature. */ /* */ /* The function returns either 1 or -1. */ /* */ static int ft_get_orientation( FT_Outline* outline ) { FT_BBox box; FT_BBox indices; int n, last; indices.xMin = -1; indices.yMin = -1; indices.xMax = -1; indices.yMax = -1; box.xMin = box.yMin = 32767; box.xMax = box.yMax = -32768; /* is it empty ? */ if ( outline->n_contours < 1 ) return 1; last = outline->contours[outline->n_contours - 1]; for ( n = 0; n <= last; n++ ) { FT_Pos x, y; x = outline->points[n].x; if ( x < box.xMin ) { box.xMin = x; indices.xMin = n; } if ( x > box.xMax ) { box.xMax = x; indices.xMax = n; } y = outline->points[n].y; if ( y < box.yMin ) { box.yMin = y; indices.yMin = n; } if ( y > box.yMax ) { box.yMax = y; indices.yMax = n; } } /* test orientation of the xmin */ n = ft_test_extrema( outline, indices.xMin ); if ( n ) goto Exit; n = ft_test_extrema( outline, indices.yMin ); if ( n ) goto Exit; n = ft_test_extrema( outline, indices.xMax ); if ( n ) goto Exit; n = ft_test_extrema( outline, indices.yMax ); if ( !n ) n = 1; Exit: return n; } FT_EXPORT_DEF( void ) FT_GlyphSlot_Embolden( FT_GlyphSlot slot ) { FT_Vector* points; FT_Vector v_prev, v_first, v_next, v_cur; FT_Pos distance; FT_Outline* outline = &slot->outline; FT_Face face = FT_SLOT_FACE( slot ); FT_Angle rotate, angle_in, angle_out; FT_Int c, n, first, orientation; /* only embolden outline glyph images */ if ( slot->format != FT_GLYPH_FORMAT_OUTLINE ) return; /* compute control distance */ distance = FT_MulFix( face->units_per_EM / 60, face->size->metrics.y_scale ); orientation = ft_get_orientation( outline ); rotate = FT_ANGLE_PI2*orientation; points = outline->points; first = 0; for ( c = 0; c < outline->n_contours; c++ ) { int last = outline->contours[c]; v_first = points[first]; v_prev = points[last]; v_cur = v_first; for ( n = first; n <= last; n++ ) { FT_Pos d; FT_Vector in, out; FT_Fixed scale; FT_Angle angle_diff; if ( n < last ) v_next = points[n + 1]; else v_next = v_first; /* compute the in and out vectors */ in.x = v_cur.x - v_prev.x; in.y = v_cur.y - v_prev.y; out.x = v_next.x - v_cur.x; out.y = v_next.y - v_cur.y; angle_in = FT_Atan2( in.x, in.y ); angle_out = FT_Atan2( out.x, out.y ); angle_diff = FT_Angle_Diff( angle_in, angle_out ); scale = FT_Cos( angle_diff/2 ); if ( scale < 0x400L && scale > -0x400L ) { if ( scale >= 0 ) scale = 0x400L; else scale = -0x400L; } d = FT_DivFix( distance, scale ); FT_Vector_From_Polar( &in, d, angle_in + angle_diff/2 - rotate ); outline->points[n].x = v_cur.x + distance + in.x; outline->points[n].y = v_cur.y + distance + in.y; v_prev = v_cur; v_cur = v_next; } first = last + 1; } slot->metrics.horiAdvance = ( slot->metrics.horiAdvance + distance*4 ) & -64; }/* END */⌨️ 快捷键说明
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