/**************************************************************************//** * Contains various Struct class methods. * * Copyright © 2002 - 2009 by Timothy P. Hunter * * Changes since Nov. 2009 copyright © by Benjamin Thomas and Omer Bar-or * * @file rmstruct.c * @version $Id: rmstruct.c,v 1.5 2009/12/20 02:33:34 baror Exp $ * @author Tim Hunter ******************************************************************************/ #include "rmagick.h" /** * Given a C AffineMatrix, create the equivalent AffineMatrix object. * * No Ruby usage (internal function) * * Notes: * - am = Magick::AffineMatrix.new(sx, rx, ry, sy, tx, ty) * * @param affine the C AffineMatrix * @return a Ruby AffineMatrix object */ VALUE Import_AffineMatrix(AffineMatrix *affine) { VALUE argv[6]; argv[0] = rb_float_new(affine->sx); argv[1] = rb_float_new(affine->rx); argv[2] = rb_float_new(affine->ry); argv[3] = rb_float_new(affine->sy); argv[4] = rb_float_new(affine->tx); argv[5] = rb_float_new(affine->ty); return rb_class_new_instance(6, argv, Class_AffineMatrix); } /** * Convert a Magick::AffineMatrix object to a AffineMatrix structure. * * No Ruby usage (internal function) * * Notes: * - If not initialized, the defaults are [sx,rx,ry,sy,tx,ty] = [1,0,0,1,0,0] * * @param am The C AffineMatrix to modify * @param st the Ruby AffineMatrix object */ void Export_AffineMatrix(AffineMatrix *am, VALUE st) { VALUE values, v; if (CLASS_OF(st) != Class_AffineMatrix) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(st))); } values = rb_funcall(st, rm_ID_values, 0); v = rb_ary_entry(values, 0); am->sx = v == Qnil ? 1.0 : NUM2DBL(v); v = rb_ary_entry(values, 1); am->rx = v == Qnil ? 0.0 : NUM2DBL(v); v = rb_ary_entry(values, 2); am->ry = v == Qnil ? 0.0 : NUM2DBL(v); v = rb_ary_entry(values, 3); am->sy = v == Qnil ? 1.0 : NUM2DBL(v); v = rb_ary_entry(values, 4); am->tx = v == Qnil ? 0.0 : NUM2DBL(v); v = rb_ary_entry(values, 5); am->ty = v == Qnil ? 0.0 : NUM2DBL(v); RB_GC_GUARD(values); RB_GC_GUARD(v); } /** * Create a Magick::ChromaticityInfo object from a ChromaticityInfo structure. * * No Ruby usage (internal function) * * @param ci the C ChromaticityInfo * @return a Ruby Magick::ChromaticityInfo object */ VALUE ChromaticityInfo_new(ChromaticityInfo *ci) { VALUE red_primary; VALUE green_primary; VALUE blue_primary; VALUE white_point; red_primary = Import_PrimaryInfo(&ci->red_primary); green_primary = Import_PrimaryInfo(&ci->green_primary); blue_primary = Import_PrimaryInfo(&ci->blue_primary); white_point = Import_PrimaryInfo(&ci->white_point); RB_GC_GUARD(red_primary); RB_GC_GUARD(green_primary); RB_GC_GUARD(blue_primary); RB_GC_GUARD(white_point); return rb_funcall(Class_Chromaticity, rm_ID_new, 4 , red_primary, green_primary, blue_primary, white_point); } /** * Extract the elements from a Magick::ChromaticityInfo and store in a * ChromaticityInfo structure. * * No Ruby usage (internal function) * * @param ci the C ChromaticityInfo structure to modify * @param chrom the Ruby Magick::ChromaticityInfo object */ void Export_ChromaticityInfo(ChromaticityInfo *ci, VALUE chrom) { VALUE chrom_members; VALUE red_primary, green_primary, blue_primary, white_point; VALUE entry_members, x, y; ID values_id; if (CLASS_OF(chrom) != Class_Chromaticity) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(chrom))); } values_id = rm_ID_values; // Get the struct members in an array chrom_members = rb_funcall(chrom, values_id, 0); red_primary = rb_ary_entry(chrom_members, 0); green_primary = rb_ary_entry(chrom_members, 1); blue_primary = rb_ary_entry(chrom_members, 2); white_point = rb_ary_entry(chrom_members, 3); // Get the red_primary PrimaryInfo members in an array entry_members = rb_funcall(red_primary, values_id, 0); x = rb_ary_entry(entry_members, 0); // red_primary.x ci->red_primary.x = x == Qnil ? 0.0 : NUM2DBL(x); y = rb_ary_entry(entry_members, 1); // red_primary.y ci->red_primary.y = y == Qnil ? 0.0 : NUM2DBL(y); ci->red_primary.z = 0.0; // Get the green_primary PrimaryInfo members in an array entry_members = rb_funcall(green_primary, values_id, 0); x = rb_ary_entry(entry_members, 0); // green_primary.x ci->green_primary.x = x == Qnil ? 0.0 : NUM2DBL(x); y = rb_ary_entry(entry_members, 1); // green_primary.y ci->green_primary.y = y == Qnil ? 0.0 : NUM2DBL(y); ci->green_primary.z = 0.0; // Get the blue_primary PrimaryInfo members in an array entry_members = rb_funcall(blue_primary, values_id, 0); x = rb_ary_entry(entry_members, 0); // blue_primary.x ci->blue_primary.x = x == Qnil ? 0.0 : NUM2DBL(x); y = rb_ary_entry(entry_members, 1); // blue_primary.y ci->blue_primary.y = y == Qnil ? 0.0 : NUM2DBL(y); ci->blue_primary.z = 0.0; // Get the white_point PrimaryInfo members in an array entry_members = rb_funcall(white_point, values_id, 0); x = rb_ary_entry(entry_members, 0); // white_point.x ci->white_point.x = x == Qnil ? 0.0 : NUM2DBL(x); y = rb_ary_entry(entry_members, 1); // white_point.y ci->white_point.y = y == Qnil ? 0.0 : NUM2DBL(y); ci->white_point.z = 0.0; RB_GC_GUARD(chrom_members); RB_GC_GUARD(red_primary); RB_GC_GUARD(green_primary); RB_GC_GUARD(blue_primary); RB_GC_GUARD(white_point); RB_GC_GUARD(entry_members); RB_GC_GUARD(x); RB_GC_GUARD(y); } /** * Create a string representation of a Magick::Chromaticity. * * Ruby usage: * - @verbatim Magick::Chromaticity#to_s @endverbatim * * @param self this object * @return the string */ VALUE ChromaticityInfo_to_s(VALUE self) { ChromaticityInfo ci; char buff[200]; Export_ChromaticityInfo(&ci, self); sprintf(buff, "red_primary=(x=%g,y=%g) " "green_primary=(x=%g,y=%g) " "blue_primary=(x=%g,y=%g) " "white_point=(x=%g,y=%g) ", ci.red_primary.x, ci.red_primary.y, ci.green_primary.x, ci.green_primary.y, ci.blue_primary.x, ci.blue_primary.y, ci.white_point.x, ci.white_point.y); return rb_str_new2(buff); } /** * Convert a ColorInfo structure to a Magick::Color. * * No Ruby usage (internal function) * * @param ci the C ColorInfo structure * @return a Ruby Magick::Color object */ VALUE Import_ColorInfo(const ColorInfo *ci) { ComplianceType compliance_type; VALUE name; VALUE compliance; VALUE color; name = rb_str_new2(ci->name); compliance_type = ci->compliance; compliance = ComplianceType_new(compliance_type); color = Pixel_from_MagickPixel(&(ci->color)); RB_GC_GUARD(name); RB_GC_GUARD(compliance); RB_GC_GUARD(color); return rb_funcall(Class_Color, rm_ID_new, 3 , name, compliance, color); } /** * Convert a Magick::Color to a ColorInfo structure. * * No Ruby usage (internal function) * * @param ci the C ColorInfo structure to modify * @param st the Ruby Magick::Color object */ void Export_ColorInfo(ColorInfo *ci, VALUE st) { PixelColor pixel; VALUE members, m; if (CLASS_OF(st) != Class_Color) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(st))); } memset(ci, '\0', sizeof(ColorInfo)); members = rb_funcall(st, rm_ID_values, 0); m = rb_ary_entry(members, 0); if (m != Qnil) { (void) CloneString((char **)&(ci->name), StringValuePtr(m)); } m = rb_ary_entry(members, 1); if (m != Qnil) { VALUE_TO_ENUM(m, ci->compliance, ComplianceType); } m = rb_ary_entry(members, 2); if (m != Qnil) { Color_to_PixelColor(&pixel, m); // For >= 6.3.0, ColorInfo.color is a MagickPixelPacket so we have to // convert the PixelPacket. rm_init_magickpixel(NULL, &ci->color); ci->color.red = (MagickRealType) pixel.red; ci->color.green = (MagickRealType) pixel.green; ci->color.blue = (MagickRealType) pixel.blue; ci->color.opacity = (MagickRealType) OpaqueOpacity; ci->color.index = (MagickRealType) 0; } RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Convert either a String color name or a Magick::Pixel to a MagickPixel. * * No Ruby usage (internal function) * * Notes: * - The channel values in a MagickPixel are doubles. * * @param image the Image * @param mpp The MagickPixel to modify * @param color the name of the color */ void Color_to_MagickPixel(Image *image, MagickPixel *mpp, VALUE color) { PixelColor pp; // image can be NULL rm_init_magickpixel(image, mpp); Color_to_PixelColor(&pp, color); mpp->red = (MagickRealType) pp.red; mpp->green = (MagickRealType) pp.green; mpp->blue = (MagickRealType) pp.blue; mpp->opacity = (MagickRealType) pp.opacity; } /** * Free the storage allocated by Export_ColorInfo. * * No Ruby usage (internal function) * * @param ci the ColorInfo object * @see Export_ColorInfo */ static void destroy_ColorInfo(ColorInfo *ci) { magick_free((void*)ci->name); ci->name = NULL; } /** * Return a string representation of a Magick::Color object. * * Ruby usage: * - @verbatim Color#to_s @endverbatim * * @param self this object * @return the string */ VALUE Color_to_s(VALUE self) { ColorInfo ci; char buff[1024]; Export_ColorInfo(&ci, self); sprintf(buff, "name=%s, compliance=%s, " #if (MAGICKCORE_QUANTUM_DEPTH == 32 || MAGICKCORE_QUANTUM_DEPTH == 64) && defined(HAVE_TYPE_LONG_DOUBLE) "color.red=%Lg, color.green=%Lg, color.blue=%Lg, color.opacity=%Lg ", #else "color.red=%g, color.green=%g, color.blue=%g, color.opacity=%g ", #endif ci.name, ComplianceType_name(&ci.compliance), ci.color.red, ci.color.green, ci.color.blue, ci.color.opacity); destroy_ColorInfo(&ci); return rb_str_new2(buff); } /** * Convert a TypeInfo structure to a Magick::Font. * * No Ruby usage (internal function) * * @param ti the C TypeInfo structure * @return a Ruby Magick::Font object */ VALUE Import_TypeInfo(const TypeInfo *ti) { VALUE name, description, family; VALUE style, stretch, weight; VALUE encoding, foundry, format; name = rb_str_new2(ti->name); family = rb_str_new2(ti->family); style = StyleType_new(ti->style); stretch = StretchType_new(ti->stretch); weight = ULONG2NUM(ti->weight); description = ti->description ? rb_str_new2(ti->description) : Qnil; encoding = ti->encoding ? rb_str_new2(ti->encoding) : Qnil; foundry = ti->foundry ? rb_str_new2(ti->foundry) : Qnil; format = ti->format ? rb_str_new2(ti->format) : Qnil; RB_GC_GUARD(name); RB_GC_GUARD(description); RB_GC_GUARD(family); RB_GC_GUARD(style); RB_GC_GUARD(stretch); RB_GC_GUARD(weight); RB_GC_GUARD(encoding); RB_GC_GUARD(foundry); RB_GC_GUARD(format); return rb_funcall(Class_Font, rm_ID_new, 9 , name, description, family, style , stretch, weight, encoding, foundry, format); } /** * Convert a Magick::Font to a TypeInfo structure. * * No Ruby usage (internal function) * * @param ti the C TypeInfo structure to modify * @param st the Ruby Magick::Font object */ void Export_TypeInfo(TypeInfo *ti, VALUE st) { VALUE members, m; if (CLASS_OF(st) != Class_Font) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(st))); } memset(ti, '\0', sizeof(TypeInfo)); members = rb_funcall(st, rm_ID_values, 0); m = rb_ary_entry(members, 0); if (m != Qnil) { (void) CloneString((char **)&(ti->name), StringValuePtr(m)); } m = rb_ary_entry(members, 1); if (m != Qnil) { (void) CloneString((char **)&(ti->description), StringValuePtr(m)); } m = rb_ary_entry(members, 2); if (m != Qnil) { (void) CloneString((char **)&(ti->family), StringValuePtr(m)); } m = rb_ary_entry(members, 3); ti->style = m == Qnil ? 0 : FIX2INT(m); m = rb_ary_entry(members, 4); ti->stretch = m == Qnil ? 0 : FIX2INT(m); m = rb_ary_entry(members, 5); ti->weight = m == Qnil ? 0 : FIX2INT(m); m = rb_ary_entry(members, 6); if (m != Qnil) (void) CloneString((char **)&(ti->encoding), StringValuePtr(m)); m = rb_ary_entry(members, 7); if (m != Qnil) (void) CloneString((char **)&(ti->foundry), StringValuePtr(m)); m = rb_ary_entry(members, 8); if (m != Qnil) (void) CloneString((char **)&(ti->format), StringValuePtr(m)); RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Free the storage allocated by Export_TypeInfo. * * No Ruby usage (internal function) * * @param ti the TypeInfo object * @see Export_TypeInfo */ static void destroy_TypeInfo(TypeInfo *ti) { magick_free((void*)ti->name); ti->name = NULL; magick_free((void*)ti->description); ti->description = NULL; magick_free((void*)ti->family); ti->family = NULL; magick_free((void*)ti->encoding); ti->encoding = NULL; magick_free((void*)ti->foundry); ti->foundry = NULL; magick_free((void*)ti->format); ti->format = NULL; } /** * Implement the Font#to_s method. * * No Ruby usage (internal function) * * @param self this object * @return the string */ VALUE Font_to_s(VALUE self) { TypeInfo ti; char weight[20]; char buff[1024]; Export_TypeInfo(&ti, self); switch (ti.weight) { case 400: strcpy(weight, "NormalWeight"); break; case 700: strcpy(weight, "BoldWeight"); break; default: sprintf(weight, "%lu", ti.weight); break; } sprintf(buff, "name=%s, description=%s, " "family=%s, style=%s, stretch=%s, weight=%s, " "encoding=%s, foundry=%s, format=%s", ti.name, ti.description, ti.family, StyleType_name(ti.style), StretchType_name(ti.stretch), weight, ti.encoding ? ti.encoding : "", ti.foundry ? ti.foundry : "", ti.format ? ti.format : ""); destroy_TypeInfo(&ti); return rb_str_new2(buff); } /** * Create a Magick::Point object from a PointInfo structure. * * No Ruby usage (internal function) * * @param p the C PointInfo structure * @return a Ruby Magick::Point object */ VALUE Import_PointInfo(PointInfo *p) { return rb_funcall(Class_Point, rm_ID_new, 2 , INT2FIX(p->x), INT2FIX(p->y)); } /** * Convert a Magick::Point object to a PointInfo structure. * * No Ruby usage (internal function) * * @param pi the C PointInfo structure to modify * @param sp the Ruby Magick::Point object */ void Export_PointInfo(PointInfo *pi, VALUE sp) { VALUE members, m; if (CLASS_OF(sp) != Class_Point) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(sp))); } members = rb_funcall(sp, rm_ID_values, 0); m = rb_ary_entry(members, 0); pi->x = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 1); pi->y = m == Qnil ? 0.0 : NUM2DBL(m); RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Create a Magick::PrimaryInfo object from a PrimaryInfo structure. * * No Ruby usage (internal function) * * @param p the C PrimaryInfo structure * @return a Ruby Magick::PrimaryInfo object */ VALUE Import_PrimaryInfo(PrimaryInfo *p) { return rb_funcall(Class_Primary, rm_ID_new, 3 , INT2FIX(p->x), INT2FIX(p->y), INT2FIX(p->z)); } /** * Convert a Magick::PrimaryInfo object to a PrimaryInfo structure. * * No Ruby usage (internal function) * * @param pi the C PrimaryInfo structure to modify * @param sp the Ruby Magick::PrimaryInfo object */ void Export_PrimaryInfo(PrimaryInfo *pi, VALUE sp) { VALUE members, m; if (CLASS_OF(sp) != Class_Primary) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(sp))); } members = rb_funcall(sp, rm_ID_values, 0); m = rb_ary_entry(members, 0); pi->x = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 1); pi->y = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 2); pi->z = m == Qnil ? 0.0 : NUM2DBL(m); RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Create a string representation of a Magick::PrimaryInfo. * * Ruby usage: * - @verbatim Magick::PrimaryInfo#to_s @endverbatim * * @param self this object * @return the string */ VALUE PrimaryInfo_to_s(VALUE self) { PrimaryInfo pi; char buff[100]; Export_PrimaryInfo(&pi, self); sprintf(buff, "x=%g, y=%g, z=%g", pi.x, pi.y, pi.z); return rb_str_new2(buff); } /** * Convert a RectangleInfo structure to a Magick::Rectangle. * * No Ruby usage (internal function) * * @param rect the C RectangleInfo structure * @return a Ruby Magick::Rectangle object */ VALUE Import_RectangleInfo(RectangleInfo *rect) { VALUE width; VALUE height; VALUE x, y; width = UINT2NUM(rect->width); height = UINT2NUM(rect->height); x = INT2NUM(rect->x); y = INT2NUM(rect->y); RB_GC_GUARD(width); RB_GC_GUARD(height); RB_GC_GUARD(x); RB_GC_GUARD(y); return rb_funcall(Class_Rectangle, rm_ID_new, 4 , width, height, x, y); } /** * Convert a Magick::Rectangle to a RectangleInfo structure. * * No Ruby usage (internal function) * * @param rect the C RectangleInfo structure to modify * @param sr the Ruby Magick::Rectangle object */ void Export_RectangleInfo(RectangleInfo *rect, VALUE sr) { VALUE members, m; if (CLASS_OF(sr) != Class_Rectangle) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(sr))); } members = rb_funcall(sr, rm_ID_values, 0); m = rb_ary_entry(members, 0); rect->width = m == Qnil ? 0 : NUM2ULONG(m); m = rb_ary_entry(members, 1); rect->height = m == Qnil ? 0 : NUM2ULONG(m); m = rb_ary_entry(members, 2); rect->x = m == Qnil ? 0 : NUM2LONG (m); m = rb_ary_entry(members, 3); rect->y = m == Qnil ? 0 : NUM2LONG (m); RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Create a string representation of a Magick::Rectangle. * * Ruby usage: * - @verbatim Magick::Rectangle#to_s @endverbatim * * @param self this object * @return the string */ VALUE RectangleInfo_to_s(VALUE self) { RectangleInfo rect; char buff[100]; Export_RectangleInfo(&rect, self); sprintf(buff, "width=%lu, height=%lu, x=%ld, y=%ld" , rect.width, rect.height, rect.x, rect.y); return rb_str_new2(buff); } /** * Convert a SegmentInfo structure to a Magick::Segment. * * No Ruby usage (internal function) * * @param segment the C SegmentInfo structure * @return a Ruby Magick::Segment object */ VALUE Import_SegmentInfo(SegmentInfo *segment) { VALUE x1, y1, x2, y2; x1 = rb_float_new(segment->x1); y1 = rb_float_new(segment->y1); x2 = rb_float_new(segment->x2); y2 = rb_float_new(segment->y2); RB_GC_GUARD(x1); RB_GC_GUARD(y1); RB_GC_GUARD(x2); RB_GC_GUARD(y2); return rb_funcall(Class_Segment, rm_ID_new, 4, x1, y1, x2, y2); } /** * Convert a Magick::Segment to a SegmentInfo structure. * * No Ruby usage (internal function) * * @param segment the C SegmentInfo structure to modify * @param s the Ruby Magick::Segment object */ void Export_SegmentInfo(SegmentInfo *segment, VALUE s) { VALUE members, m; if (CLASS_OF(s) != Class_Segment) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(s))); } members = rb_funcall(s, rm_ID_values, 0); m = rb_ary_entry(members, 0); segment->x1 = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 1); segment->y1 = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 2); segment->x2 = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 3); segment->y2 = m == Qnil ? 0.0 : NUM2DBL(m); RB_GC_GUARD(members); RB_GC_GUARD(m); } /** * Create a string representation of a Magick::Segment. * * Ruby usage: * - @verbatim Magick::SegmentInfo#to_s @endverbatim * * @param self this object * @return the string */ VALUE SegmentInfo_to_s(VALUE self) { SegmentInfo segment; char buff[100]; Export_SegmentInfo(&segment, self); sprintf(buff, "x1=%g, y1=%g, x2=%g, y2=%g" , segment.x1, segment.y1, segment.x2, segment.y2); return rb_str_new2(buff); } /** * Convert a TypeMetric structure to a Magick::TypeMetric. * * No Ruby usage (internal function) * * @param tm the C TypeMetric structure * @return a Ruby Magick::TypeMetric object */ VALUE Import_TypeMetric(TypeMetric *tm) { VALUE pixels_per_em; VALUE ascent, descent; VALUE width, height, max_advance; VALUE bounds, underline_position, underline_thickness; pixels_per_em = Import_PointInfo(&tm->pixels_per_em); ascent = rb_float_new(tm->ascent); descent = rb_float_new(tm->descent); width = rb_float_new(tm->width); height = rb_float_new(tm->height); max_advance = rb_float_new(tm->max_advance); bounds = Import_SegmentInfo(&tm->bounds); underline_position = rb_float_new(tm->underline_position); underline_thickness = rb_float_new(tm->underline_position); RB_GC_GUARD(pixels_per_em); RB_GC_GUARD(ascent); RB_GC_GUARD(descent); RB_GC_GUARD(width); RB_GC_GUARD(height); RB_GC_GUARD(max_advance); RB_GC_GUARD(bounds); RB_GC_GUARD(underline_position); RB_GC_GUARD(underline_thickness); return rb_funcall(Class_TypeMetric, rm_ID_new, 9 , pixels_per_em, ascent, descent, width , height, max_advance, bounds , underline_position, underline_thickness); } /** * Convert a Magick::TypeMetric to a TypeMetric structure. * * No Ruby usage (internal function) * * @param tm the C TypeMetric structure to modify * @param st the Ruby Magick::TypeMetric object */ void Export_TypeMetric(TypeMetric *tm, VALUE st) { VALUE members, m; VALUE pixels_per_em; if (CLASS_OF(st) != Class_TypeMetric) { rb_raise(rb_eTypeError, "type mismatch: %s given", rb_class2name(CLASS_OF(st))); } members = rb_funcall(st, rm_ID_values, 0); pixels_per_em = rb_ary_entry(members, 0); Export_PointInfo(&tm->pixels_per_em, pixels_per_em); m = rb_ary_entry(members, 1); tm->ascent = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 2); tm->descent = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 3); tm->width = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 4); tm->height = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 5); tm->max_advance = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 6); Export_SegmentInfo(&tm->bounds, m); m = rb_ary_entry(members, 7); tm->underline_position = m == Qnil ? 0.0 : NUM2DBL(m); m = rb_ary_entry(members, 8); tm->underline_thickness = m == Qnil ? 0.0 : NUM2DBL(m); RB_GC_GUARD(members); RB_GC_GUARD(m); RB_GC_GUARD(pixels_per_em); } /** * Create a string representation of a Magick::TypeMetric. * * Ruby usage: * - @verbatim Magick::TypeMetric#to_s @endverbatim * * @param self this object * @return the string */ VALUE TypeMetric_to_s(VALUE self) { VALUE str; TypeMetric tm; char temp[200]; int len; Export_TypeMetric(&tm, self); len = sprintf(temp, "pixels_per_em=(x=%g,y=%g) ", tm.pixels_per_em.x, tm.pixels_per_em.y); str = rb_str_new(temp, len); len = sprintf(temp, "ascent=%g descent=%g ",tm.ascent, tm.descent); rb_str_cat(str, temp, len); len = sprintf(temp, "width=%g height=%g max_advance=%g ", tm.width, tm.height, tm.max_advance); rb_str_cat(str, temp, len); len = sprintf(temp, "bounds.x1=%g bounds.y1=%g ", tm.bounds.x1, tm.bounds.y1); rb_str_cat(str, temp, len); len = sprintf(temp, "bounds.x2=%g bounds.y2=%g ", tm.bounds.x2, tm.bounds.y2); rb_str_cat(str, temp, len); len = sprintf(temp, "underline_position=%g underline_thickness=%g", tm.underline_position, tm.underline_thickness); rb_str_cat(str, temp, len); RB_GC_GUARD(str); return str; }