/* Copyright (C) 1989, 1995, 1996, 1997, 1999 Aladdin Enterprises. All rights reserved. This software is provided AS-IS with no warranty, either express or implied. This software is distributed under license and may not be copied, modified or distributed except as expressly authorized under the terms of the license contained in the file LICENSE in this distribution. For more information about licensing, please refer to http://www.ghostscript.com/licensing/. For information on commercial licensing, go to http://www.artifex.com/licensing/ or contact Artifex Software, Inc., 101 Lucas Valley Road #110, San Rafael, CA 94903, U.S.A., +1(415)492-9861. */ /* $Id: gsline.c,v 1.4 2002/02/21 22:24:52 giles Exp $ */ /* Line parameter operators for Ghostscript library */ #include "math_.h" #include "memory_.h" #include "gx.h" #include "gserrors.h" #include "gxfixed.h" /* ditto */ #include "gxmatrix.h" /* for gzstate */ #include "gzstate.h" #include "gscoord.h" /* for currentmatrix, setmatrix */ #include "gsline.h" /* for prototypes */ #include "gzline.h" /* ------ Device-independent parameters ------ */ #define pgs_lp gs_currentlineparams_inline(pgs) /* setlinewidth */ int gs_setlinewidth(gs_state * pgs, floatp width) { gx_set_line_width(pgs_lp, width); return 0; } /* currentlinewidth */ float gs_currentlinewidth(const gs_state * pgs) { return gx_current_line_width(pgs_lp); } /* setlinecap */ int gs_setlinecap(gs_state * pgs, gs_line_cap cap) { if ((uint) cap > gs_line_cap_max) return_error(gs_error_rangecheck); pgs_lp->cap = cap; return 0; } /* currentlinecap */ gs_line_cap gs_currentlinecap(const gs_state * pgs) { return pgs_lp->cap; } /* setlinejoin */ int gs_setlinejoin(gs_state * pgs, gs_line_join join) { if ((uint) join > gs_line_join_max) return_error(gs_error_rangecheck); pgs_lp->join = join; return 0; } /* currentlinejoin */ gs_line_join gs_currentlinejoin(const gs_state * pgs) { return pgs_lp->join; } /* setmiterlimit */ int gx_set_miter_limit(gx_line_params * plp, floatp limit) { if (limit < 1.0) return_error(gs_error_rangecheck); plp->miter_limit = limit; /* * Compute the miter check value. The supplied miter limit is an * upper bound on 1/sin(phi/2); we convert this to a lower bound on * tan(phi). Note that if phi > pi/2, this is negative. We use the * half-angle and angle-sum formulas here to avoid the trig functions. * We also need a special check for phi/2 close to pi/4. * Some C compilers can't handle this as a conditional expression.... */ { double limit_squared = limit * limit; if (limit_squared < 2.0001 && limit_squared > 1.9999) plp->miter_check = 1.0e6; else plp->miter_check = sqrt(limit_squared - 1) * 2 / (limit_squared - 2); } return 0; } int gs_setmiterlimit(gs_state * pgs, floatp limit) { return gx_set_miter_limit(pgs_lp, limit); } /* currentmiterlimit */ float gs_currentmiterlimit(const gs_state * pgs) { return pgs_lp->miter_limit; } /* setdash */ int gx_set_dash(gx_dash_params * dash, const float *pattern, uint length, floatp offset, gs_memory_t * mem) { uint n = length; const float *dfrom = pattern; bool ink = true; int index = 0; float pattern_length = 0.0; float dist_left; float *ppat = dash->pattern; /* Check the dash pattern. */ while (n--) { float elt = *dfrom++; if (elt < 0) return_error(gs_error_rangecheck); pattern_length += elt; } if (length == 0) { /* empty pattern */ dist_left = 0.0; if (mem && ppat) { gs_free_object(mem, ppat, "gx_set_dash(old pattern)"); ppat = 0; } } else { uint size = length * sizeof(float); if (pattern_length == 0) return_error(gs_error_rangecheck); /* Compute the initial index, ink_on, and distance left */ /* in the pattern, according to the offset. */ #define f_mod(a, b) ((a) - floor((a) / (b)) * (b)) if (length & 1) { /* Odd and even repetitions of the pattern */ /* have opposite ink values! */ float length2 = pattern_length * 2; dist_left = f_mod(offset, length2); if (dist_left >= pattern_length) dist_left -= pattern_length, ink = !ink; } else dist_left = f_mod(offset, pattern_length); while ((dist_left -= pattern[index]) >= 0 && (dist_left > 0 || pattern[index] != 0) ) ink = !ink, index++; if (mem) { if (ppat == 0) ppat = (float *)gs_alloc_bytes(mem, size, "gx_set_dash(pattern)"); else if (length != dash->pattern_size) ppat = gs_resize_object(mem, ppat, size, "gx_set_dash(pattern)"); if (ppat == 0) return_error(gs_error_VMerror); } memcpy(ppat, pattern, length * sizeof(float)); } dash->pattern = ppat; dash->pattern_size = length; dash->offset = offset; dash->pattern_length = pattern_length; dash->init_ink_on = ink; dash->init_index = index; dash->init_dist_left = -dist_left; return 0; } int gs_setdash(gs_state * pgs, const float *pattern, uint length, floatp offset) { return gx_set_dash(&pgs_lp->dash, pattern, length, offset, pgs->memory); } /* currentdash */ uint gs_currentdash_length(const gs_state * pgs) { return pgs_lp->dash.pattern_size; } const float * gs_currentdash_pattern(const gs_state * pgs) { return pgs_lp->dash.pattern; } float gs_currentdash_offset(const gs_state * pgs) { return pgs_lp->dash.offset; } /* Internal accessor for line parameters */ const gx_line_params * gs_currentlineparams(const gs_imager_state * pis) { return gs_currentlineparams_inline(pis); } /* ------ Device-dependent parameters ------ */ /* setflat */ int gs_imager_setflat(gs_imager_state * pis, floatp flat) { if (flat <= 0.2) flat = 0.2; else if (flat > 100) flat = 100; pis->flatness = flat; return 0; } int gs_setflat(gs_state * pgs, floatp flat) { return gs_imager_setflat((gs_imager_state *) pgs, flat); } /* currentflat */ float gs_currentflat(const gs_state * pgs) { return pgs->flatness; } /* setstrokeadjust */ int gs_setstrokeadjust(gs_state * pgs, bool stroke_adjust) { pgs->stroke_adjust = stroke_adjust; return 0; } /* currentstrokeadjust */ bool gs_currentstrokeadjust(const gs_state * pgs) { return pgs->stroke_adjust; } /* ------ Extensions ------ */ /* Device-independent */ /* setdashadapt */ void gs_setdashadapt(gs_state * pgs, bool adapt) { pgs_lp->dash.adapt = adapt; } /* currentdashadapt */ bool gs_imager_currentdashadapt(const gs_imager_state * pis) { return gs_currentlineparams_inline(pis)->dash.adapt; } bool gs_currentdashadapt(const gs_state * pgs) { return gs_imager_currentdashadapt((const gs_imager_state *)pgs); } /* setcurvejoin */ int gs_setcurvejoin(gs_state * pgs, int join) { if (join < -1 || join > gs_line_join_max) return_error(gs_error_rangecheck); pgs_lp->curve_join = join; return 0; } /* currentcurvejoin */ int gs_currentcurvejoin(const gs_state * pgs) { return pgs_lp->curve_join; } /* Device-dependent */ /* setaccuratecurves */ void gs_setaccuratecurves(gs_state * pgs, bool accurate) { pgs->accurate_curves = accurate; } /* currentaccuratecurves */ bool gs_imager_currentaccuratecurves(const gs_imager_state * pis) { return pis->accurate_curves; } bool gs_currentaccuratecurves(const gs_state * pgs) { return gs_imager_currentaccuratecurves((const gs_imager_state *)pgs); } /* setdotlength */ int gx_set_dot_length(gx_line_params * plp, floatp length, bool absolute) { if (length < 0) return_error(gs_error_rangecheck); plp->dot_length = length; plp->dot_length_absolute = absolute; return 0; } int gs_setdotlength(gs_state * pgs, floatp length, bool absolute) { return gx_set_dot_length(pgs_lp, length, absolute); } /* currentdotlength */ float gs_currentdotlength(const gs_state * pgs) { return pgs_lp->dot_length; } bool gs_currentdotlength_absolute(const gs_state * pgs) { return pgs_lp->dot_length_absolute; } /* setdotorientation */ int gs_setdotorientation(gs_state *pgs) { if (is_xxyy(&pgs->ctm) || is_xyyx(&pgs->ctm)) return gs_currentmatrix(pgs, &pgs_lp->dot_orientation); return_error(gs_error_rangecheck); } /* dotorientation */ int gs_dotorientation(gs_state *pgs) { return gs_setmatrix(pgs, &pgs_lp->dot_orientation); }