// SPDX-License-Identifier: GPL-2.0-or-later /** @file * @brief Enhanced Metafile printing *//* * Authors: * Ulf Erikson * Jon A. Cruz * Abhishek Sharma * David Mathog * * Copyright (C) 2006-2009 Authors * * Released under GNU GPL v2+, read the file 'COPYING' for more information. * * References: * - How to Create & Play Enhanced Metafiles in Win32 * http://support.microsoft.com/kb/q145999/ * - INFO: Windows Metafile Functions & Aldus Placeable Metafiles * http://support.microsoft.com/kb/q66949/ * - Metafile Functions * http://msdn.microsoft.com/library/en-us/gdi/metafile_0whf.asp * - Metafile Structures * http://msdn.microsoft.com/library/en-us/gdi/metafile_5hkj.asp */ #include "emf-print.h" #include #include #include <3rdparty/libuemf/symbol_convert.h> #include <2geom/sbasis-to-bezier.h> #include <2geom/path.h> #include <2geom/pathvector.h> #include <2geom/rect.h> #include <2geom/curves.h> #include <2geom/svg-path-parser.h> // to get from SVG text to Geom::Path #include "inkscape-version.h" #include "document.h" #include "path-prefix.h" #include "style.h" #include "style-enums.h" // Fill rules #include "display/cairo-utils.h" // for Inkscape::Pixbuf::PF_CAIRO #include "display/curve.h" #include "extension/system.h" #include "extension/print.h" #include "helper/geom.h" #include "helper/geom-curves.h" #include "object/sp-pattern.h" #include "object/sp-image.h" #include "object/sp-gradient.h" #include "object/sp-radial-gradient.h" #include "object/sp-linear-gradient.h" #include "object/sp-item.h" #include "object/sp-root.h" #include "object/sp-shape.h" #include "object/sp-clippath.h" #include "path/path-boolop.h" #include "util/units.h" namespace Inkscape { namespace Extension { namespace Internal { #define PXPERMETER 2835 /* globals */ static double PX2WORLD; static bool FixPPTCharPos, FixPPTDashLine, FixPPTGrad2Polys, FixPPTLinGrad, FixPPTPatternAsHatch, FixImageRot; static EMFTRACK *et = nullptr; static EMFHANDLES *eht = nullptr; void PrintEmf::smuggle_adxkyrtl_out(const char *string, uint32_t **adx, double *ky, int *rtl, int *ndx, float scale) { float fdx; int i; uint32_t *ladx; const char *cptr = &string[strlen(string) + 1]; // this works because of the first fake terminator *adx = nullptr; *ky = 0.0; // set a default value sscanf(cptr, "%7d", ndx); if (!*ndx) { return; // this could happen with an empty string } cptr += 7; ladx = (uint32_t *) malloc(*ndx * sizeof(uint32_t)); if (!ladx) { g_message("Out of memory"); } *adx = ladx; for (i = 0; i < *ndx; i++, cptr += 7, ladx++) { sscanf(cptr, "%7f", &fdx); *ladx = (uint32_t) round(fdx * scale); } cptr++; // skip 2nd fake terminator sscanf(cptr, "%7f", &fdx); *ky = fdx; cptr += 7; // advance over ky and its space sscanf(cptr, "%07d", rtl); } PrintEmf::PrintEmf() { // all of the class variables are initialized elsewhere, many in PrintEmf::Begin, } unsigned int PrintEmf::setup(Inkscape::Extension::Print * /*mod*/) { return TRUE; } unsigned int PrintEmf::begin(Inkscape::Extension::Print *mod, SPDocument *doc) { U_SIZEL szlDev, szlMm; U_RECTL rclBounds, rclFrame; char *rec; gchar const *utf8_fn = mod->get_param_string("destination"); // Typically PX2WORLD is 1200/90, using inkscape's default dpi PX2WORLD = 1200.0 / Inkscape::Util::Quantity::convert(1.0, "in", "px"); FixPPTCharPos = mod->get_param_bool("FixPPTCharPos"); FixPPTDashLine = mod->get_param_bool("FixPPTDashLine"); FixPPTGrad2Polys = mod->get_param_bool("FixPPTGrad2Polys"); FixPPTLinGrad = mod->get_param_bool("FixPPTLinGrad"); FixPPTPatternAsHatch = mod->get_param_bool("FixPPTPatternAsHatch"); FixImageRot = mod->get_param_bool("FixImageRot"); (void) emf_start(utf8_fn, 1000000, 250000, &et); // Initialize the et structure (void) htable_create(128, 128, &eht); // Initialize the eht structure char *ansi_uri = (char *) utf8_fn; // width and height in px _width = doc->getWidth().value("px"); _height = doc->getHeight().value("px"); _doc_unit_scale = doc->getDocumentScale()[Geom::X]; // initialize a few global variables hbrush = hbrushOld = hpen = 0; htextalignment = U_TA_BASELINE | U_TA_LEFT; use_stroke = use_fill = simple_shape = usebk = false; Inkscape::XML::Node *nv = doc->getReprNamedView(); if (nv) { const char *p1 = nv->attribute("pagecolor"); char *p2; uint32_t lc = strtoul(&p1[1], &p2, 16); // it looks like "#ABC123" if (*p2) { lc = 0; } gv.bgc = _gethexcolor(lc); gv.rgb[0] = (float) U_RGBAGetR(gv.bgc) / 255.0; gv.rgb[1] = (float) U_RGBAGetG(gv.bgc) / 255.0; gv.rgb[2] = (float) U_RGBAGetB(gv.bgc) / 255.0; } bool pageBoundingBox; pageBoundingBox = mod->get_param_bool("pageBoundingBox"); Geom::Rect d; if (pageBoundingBox) { d = Geom::Rect::from_xywh(0, 0, _width, _height); } else { SPItem *doc_item = doc->getRoot(); Geom::OptRect bbox = doc_item->desktopVisualBounds(); if (bbox) { d = *bbox; } } d *= Geom::Scale(Inkscape::Util::Quantity::convert(1, "px", "in")); float dwInchesX = d.width(); float dwInchesY = d.height(); // dwInchesX x dwInchesY in micrometer units, 1200 dpi/25.4 -> dpmm (void) drawing_size((int) ceil(dwInchesX * 25.4), (int) ceil(dwInchesY * 25.4),1200.0/25.4, &rclBounds, &rclFrame); // set up the reference device as 100 X A4 horizontal, (1200 dpi/25.4 -> dpmm). Extra digits maintain dpi better in EMF int MMX = 216; int MMY = 279; (void) device_size(MMX, MMY, 1200.0 / 25.4, &szlDev, &szlMm); int PixelsX = szlDev.cx; int PixelsY = szlDev.cy; // set up the description: (version string)0(file)00 char buff[1024]; memset(buff, 0, sizeof(buff)); char *p1 = strrchr(ansi_uri, '\\'); char *p2 = strrchr(ansi_uri, '/'); char *p = MAX(p1, p2); if (p) { p++; } else { p = ansi_uri; } snprintf(buff, sizeof(buff) - 1, "Inkscape %s \1%s\1", Inkscape::version_string, p); uint16_t *Description = U_Utf8ToUtf16le(buff, 0, nullptr); int cbDesc = 2 + wchar16len(Description); // also count the final terminator (void) U_Utf16leEdit(Description, '\1', '\0'); // swap the temporary \1 characters for nulls // construct the EMRHEADER record and append it to the EMF in memory rec = U_EMRHEADER_set(rclBounds, rclFrame, nullptr, cbDesc, Description, szlDev, szlMm, 0); free(Description); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at EMRHEADER"); } // Simplest mapping mode, supply all coordinates in pixels rec = U_EMRSETMAPMODE_set(U_MM_TEXT); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at EMRSETMAPMODE"); } // In earlier versions this was used to scale from inkscape's dpi of 90 to // the files 1200 dpi, taking into account PX2WORLD which was 20. Now PX2WORLD // is set so that this matrix is unitary. The usual value of PX2WORLD is 1200/90, // but might be different if the internal dpi is changed. U_XFORM worldTransform; worldTransform.eM11 = 1.0; worldTransform.eM12 = 0.0; worldTransform.eM21 = 0.0; worldTransform.eM22 = 1.0; worldTransform.eDx = 0; worldTransform.eDy = 0; rec = U_EMRMODIFYWORLDTRANSFORM_set(worldTransform, U_MWT_LEFTMULTIPLY); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at EMRMODIFYWORLDTRANSFORM"); } if (true) { snprintf(buff, sizeof(buff) - 1, "Screen=%dx%dpx, %dx%dmm", PixelsX, PixelsY, MMX, MMY); rec = textcomment_set(buff); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at textcomment_set 1"); } snprintf(buff, sizeof(buff) - 1, "Drawing=%.1fx%.1fpx, %.1fx%.1fmm", _width, _height, Inkscape::Util::Quantity::convert(dwInchesX, "in", "mm"), Inkscape::Util::Quantity::convert(dwInchesY, "in", "mm")); rec = textcomment_set(buff); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at textcomment_set 1"); } } /* set some parameters, else the program that reads the EMF may default to other values */ rec = U_EMRSETBKMODE_set(U_TRANSPARENT); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at U_EMRSETBKMODE_set"); } hpolyfillmode = U_WINDING; rec = U_EMRSETPOLYFILLMODE_set(U_WINDING); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at U_EMRSETPOLYFILLMODE_set"); } // Text alignment: (only changed if RTL text is encountered ) // - (x,y) coordinates received by this filter are those of the point where the text // actually starts, and already takes into account the text object's alignment; // - for this reason, the EMF text alignment must always be TA_BASELINE|TA_LEFT. htextalignment = U_TA_BASELINE | U_TA_LEFT; rec = U_EMRSETTEXTALIGN_set(U_TA_BASELINE | U_TA_LEFT); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at U_EMRSETTEXTALIGN_set"); } htextcolor_rgb[0] = htextcolor_rgb[1] = htextcolor_rgb[2] = 0.0; rec = U_EMRSETTEXTCOLOR_set(U_RGB(0, 0, 0)); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at U_EMRSETTEXTCOLOR_set"); } rec = U_EMRSETROP2_set(U_R2_COPYPEN); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::begin at U_EMRSETROP2_set"); } /* miterlimit is set with eah pen, so no need to check for it changes as in WMF */ return 0; } unsigned int PrintEmf::finish(Inkscape::Extension::Print * /*mod*/) { do_clip_if_present(nullptr); // Terminate any open clip. char *rec; if (!et) { return 0; } // earlier versions had flush of fill here, but it never executed and was removed rec = U_EMREOF_set(0, nullptr, et); // generate the EOF record if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::finish"); } (void) emf_finish(et, eht); // Finalize and write out the EMF emf_free(&et); // clean up htable_free(&eht); // clean up return 0; } // fcolor is defined when gradients are being expanded, it is the color of one stripe or ring. int PrintEmf::create_brush(SPStyle const *style, PU_COLORREF fcolor) { float rgb[3]; char *rec; U_LOGBRUSH lb; uint32_t brush, fmode; MFDrawMode fill_mode; Inkscape::Pixbuf *pixbuf; uint32_t brushStyle; int hatchType; U_COLORREF hatchColor; U_COLORREF bkColor; uint32_t width = 0; // quiets a harmless compiler warning, initialization not otherwise required. uint32_t height = 0; if (!et) { return 0; } // set a default fill in case we can't figure out a better way to do it fmode = U_ALTERNATE; fill_mode = DRAW_PAINT; brushStyle = U_BS_SOLID; hatchType = U_HS_SOLIDCLR; bkColor = U_RGB(0, 0, 0); if (fcolor) { hatchColor = *fcolor; } else { hatchColor = U_RGB(0, 0, 0); } if (!fcolor && style) { if (style->fill.isColor()) { fill_mode = DRAW_PAINT; #if 0 // opacity not supported by EMF float opacity = SP_SCALE24_TO_FLOAT(style->fill_opacity.value); if (opacity <= 0.0) { opacity = 0.0; // basically the same as no fill } #endif style->fill.value.color.get_rgb_floatv(rgb); hatchColor = U_RGB(255 * rgb[0], 255 * rgb[1], 255 * rgb[2]); fmode = style->fill_rule.computed == 0 ? U_WINDING : (style->fill_rule.computed == 2 ? U_ALTERNATE : U_ALTERNATE); } else if (SP_IS_PATTERN(SP_STYLE_FILL_SERVER(style))) { // must be paint-server SPPaintServer *paintserver = style->fill.value.href->getObject(); SPPattern *pat = SP_PATTERN(paintserver); double dwidth = pat->width(); double dheight = pat->height(); width = dwidth; height = dheight; brush_classify(pat, 0, &pixbuf, &hatchType, &hatchColor, &bkColor); if (pixbuf) { fill_mode = DRAW_IMAGE; } else { // pattern fill_mode = DRAW_PATTERN; if (hatchType == -1) { // Not a standard hatch, so force it to something hatchType = U_HS_CROSS; hatchColor = U_RGB(0xFF, 0xC3, 0xC3); } } if (FixPPTPatternAsHatch) { if (hatchType == -1) { // image or unclassified fill_mode = DRAW_PATTERN; hatchType = U_HS_DIAGCROSS; hatchColor = U_RGB(0xFF, 0xC3, 0xC3); } } brushStyle = U_BS_HATCHED; } else if (SP_IS_GRADIENT(SP_STYLE_FILL_SERVER(style))) { // must be a gradient // currently we do not do anything with gradients, the code below just sets the color to the average of the stops SPPaintServer *paintserver = style->fill.value.href->getObject(); SPLinearGradient *lg = nullptr; SPRadialGradient *rg = nullptr; if (SP_IS_LINEARGRADIENT(paintserver)) { lg = SP_LINEARGRADIENT(paintserver); lg->ensureVector(); // when exporting from commandline, vector is not built fill_mode = DRAW_LINEAR_GRADIENT; } else if (SP_IS_RADIALGRADIENT(paintserver)) { rg = SP_RADIALGRADIENT(paintserver); rg->ensureVector(); // when exporting from commandline, vector is not built fill_mode = DRAW_RADIAL_GRADIENT; } else { // default fill } if (rg) { if (FixPPTGrad2Polys) { return hold_gradient(rg, fill_mode); } else { hatchColor = avg_stop_color(rg); } } else if (lg) { if (FixPPTGrad2Polys || FixPPTLinGrad) { return hold_gradient(lg, fill_mode); } else { hatchColor = avg_stop_color(lg); } } } } else { // if (!style) // default fill } lb = logbrush_set(brushStyle, hatchColor, hatchType); switch (fill_mode) { case DRAW_LINEAR_GRADIENT: // fill with average color unless gradients are converted to slices case DRAW_RADIAL_GRADIENT: // ditto case DRAW_PAINT: case DRAW_PATTERN: // SVG text has no background attribute, so OPAQUE mode ALWAYS cancels after the next draw, otherwise it would mess up future text output. if (usebk) { rec = U_EMRSETBKCOLOR_set(bkColor); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at U_EMRSETBKCOLOR_set"); } rec = U_EMRSETBKMODE_set(U_OPAQUE); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at U_EMRSETBKMODE_set"); } } rec = createbrushindirect_set(&brush, eht, lb); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at createbrushindirect_set"); } break; case DRAW_IMAGE: char *px; char *rgba_px; uint32_t cbPx; uint32_t colortype; PU_RGBQUAD ct; int numCt; U_BITMAPINFOHEADER Bmih; PU_BITMAPINFO Bmi; rgba_px = (char *) pixbuf->pixels(); // Do NOT free this!!! colortype = U_BCBM_COLOR32; (void) RGBA_to_DIB(&px, &cbPx, &ct, &numCt, rgba_px, width, height, width * 4, colortype, 0, 1); // pixbuf can be either PF_CAIRO or PF_GDK, and these have R and B bytes swapped if (pixbuf->pixelFormat() == Inkscape::Pixbuf::PF_CAIRO) { swapRBinRGBA(px, width * height); } Bmih = bitmapinfoheader_set(width, height, 1, colortype, U_BI_RGB, 0, PXPERMETER, PXPERMETER, numCt, 0); Bmi = bitmapinfo_set(Bmih, ct); rec = createdibpatternbrushpt_set(&brush, eht, U_DIB_RGB_COLORS, Bmi, cbPx, px); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at createdibpatternbrushpt_set"); } free(px); free(Bmi); // ct will be NULL because of colortype break; } hbrush = brush; // need this later for destroy_brush rec = selectobject_set(brush, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at selectobject_set"); } if (fmode != hpolyfillmode) { hpolyfillmode = fmode; rec = U_EMRSETPOLYFILLMODE_set(fmode); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_brush at U_EMRSETPOLYdrawmode_set"); } } return 0; } void PrintEmf::destroy_brush() { char *rec; // before an object may be safely deleted it must no longer be selected // select in a stock object to deselect this one, the stock object should // never be used because we always select in a new one before drawing anythingrestore previous brush, necessary??? Would using a default stock object not work? rec = selectobject_set(U_NULL_BRUSH, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::destroy_brush at selectobject_set"); } if (hbrush) { rec = deleteobject_set(&hbrush, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::destroy_brush"); } hbrush = 0; } } int PrintEmf::create_pen(SPStyle const *style, const Geom::Affine &transform) { U_EXTLOGPEN *elp; U_NUM_STYLEENTRY n_dash = 0; U_STYLEENTRY *dash = nullptr; char *rec = nullptr; int linestyle = U_PS_SOLID; int linecap = 0; int linejoin = 0; uint32_t pen; uint32_t brushStyle; Inkscape::Pixbuf *pixbuf; int hatchType; U_COLORREF hatchColor; U_COLORREF bkColor; uint32_t width, height; char *px = nullptr; char *rgba_px; uint32_t cbPx = 0; uint32_t colortype; PU_RGBQUAD ct = nullptr; int numCt = 0; U_BITMAPINFOHEADER Bmih; PU_BITMAPINFO Bmi = nullptr; if (!et) { return 0; } // set a default stroke in case we can't figure out a better way to do it brushStyle = U_BS_SOLID; hatchColor = U_RGB(0, 0, 0); hatchType = U_HS_HORIZONTAL; bkColor = U_RGB(0, 0, 0); if (style) { float rgb[3]; if (SP_IS_PATTERN(SP_STYLE_STROKE_SERVER(style))) { // must be paint-server SPPaintServer *paintserver = style->stroke.value.href->getObject(); SPPattern *pat = SP_PATTERN(paintserver); double dwidth = pat->width(); double dheight = pat->height(); width = dwidth; height = dheight; brush_classify(pat, 0, &pixbuf, &hatchType, &hatchColor, &bkColor); if (pixbuf) { brushStyle = U_BS_DIBPATTERN; rgba_px = (char *) pixbuf->pixels(); // Do NOT free this!!! colortype = U_BCBM_COLOR32; (void) RGBA_to_DIB(&px, &cbPx, &ct, &numCt, rgba_px, width, height, width * 4, colortype, 0, 1); // pixbuf can be either PF_CAIRO or PF_GDK, and these have R and B bytes swapped if (pixbuf->pixelFormat() == Inkscape::Pixbuf::PF_CAIRO) { swapRBinRGBA(px, width * height); } Bmih = bitmapinfoheader_set(width, height, 1, colortype, U_BI_RGB, 0, PXPERMETER, PXPERMETER, numCt, 0); Bmi = bitmapinfo_set(Bmih, ct); } else { // pattern brushStyle = U_BS_HATCHED; if (usebk) { // OPAQUE mode ALWAYS cancels after the next draw, otherwise it would mess up future text output. rec = U_EMRSETBKCOLOR_set(bkColor); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_pen at U_EMRSETBKCOLOR_set"); } rec = U_EMRSETBKMODE_set(U_OPAQUE); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_pen at U_EMRSETBKMODE_set"); } } if (hatchType == -1) { // Not a standard hatch, so force it to something hatchType = U_HS_CROSS; hatchColor = U_RGB(0xFF, 0xC3, 0xC3); } } if (FixPPTPatternAsHatch) { if (hatchType == -1) { // image or unclassified brushStyle = U_BS_HATCHED; hatchType = U_HS_DIAGCROSS; hatchColor = U_RGB(0xFF, 0xC3, 0xC3); } } } else if (SP_IS_GRADIENT(SP_STYLE_STROKE_SERVER(style))) { // must be a gradient // currently we do not do anything with gradients, the code below has no net effect. SPPaintServer *paintserver = style->stroke.value.href->getObject(); if (SP_IS_LINEARGRADIENT(paintserver)) { SPLinearGradient *lg = SP_LINEARGRADIENT(paintserver); lg->ensureVector(); // when exporting from commandline, vector is not built Geom::Point p1(lg->x1.computed, lg->y1.computed); Geom::Point p2(lg->x2.computed, lg->y2.computed); if (lg->gradientTransform_set) { p1 = p1 * lg->gradientTransform; p2 = p2 * lg->gradientTransform; } hatchColor = avg_stop_color(lg); } else if (SP_IS_RADIALGRADIENT(paintserver)) { SPRadialGradient *rg = SP_RADIALGRADIENT(paintserver); rg->ensureVector(); // when exporting from commandline, vector is not built double r = rg->r.computed; Geom::Point c(rg->cx.computed, rg->cy.computed); Geom::Point xhandle_point(r, 0); Geom::Point yhandle_point(0, -r); yhandle_point += c; xhandle_point += c; if (rg->gradientTransform_set) { c = c * rg->gradientTransform; yhandle_point = yhandle_point * rg->gradientTransform; xhandle_point = xhandle_point * rg->gradientTransform; } hatchColor = avg_stop_color(rg); } else { // default fill } } else if (style->stroke.isColor()) { // test last, always seems to be set, even for other types above style->stroke.value.color.get_rgb_floatv(rgb); brushStyle = U_BS_SOLID; hatchColor = U_RGB(255 * rgb[0], 255 * rgb[1], 255 * rgb[2]); hatchType = U_HS_SOLIDCLR; } else { // default fill } using Geom::X; using Geom::Y; Geom::Point zero(0, 0); Geom::Point one(1, 1); Geom::Point p0(zero * transform); Geom::Point p1(one * transform); Geom::Point p(p1 - p0); double scale = sqrt((p[X] * p[X]) + (p[Y] * p[Y])) / sqrt(2); if (!style->stroke_width.computed) { return 0; //if width is 0 do not (reset) the pen, it should already be NULL_PEN } uint32_t linewidth = MAX(1, (uint32_t) round(scale * style->stroke_width.computed * PX2WORLD)); if (style->stroke_linecap.computed == 0) { linecap = U_PS_ENDCAP_FLAT; } else if (style->stroke_linecap.computed == 1) { linecap = U_PS_ENDCAP_ROUND; } else if (style->stroke_linecap.computed == 2) { linecap = U_PS_ENDCAP_SQUARE; } if (style->stroke_linejoin.computed == 0) { linejoin = U_PS_JOIN_MITER; } else if (style->stroke_linejoin.computed == 1) { linejoin = U_PS_JOIN_ROUND; } else if (style->stroke_linejoin.computed == 2) { linejoin = U_PS_JOIN_BEVEL; } if (!style->stroke_dasharray.values.empty()) { if (FixPPTDashLine) { // will break up line into many smaller lines. Override gradient if that was set, cannot do both. brushStyle = U_BS_SOLID; hatchType = U_HS_HORIZONTAL; } else { unsigned i = 0; while ((linestyle != U_PS_USERSTYLE) && (i < style->stroke_dasharray.values.size())) { if (style->stroke_dasharray.values[i].value > 0.00000001) { linestyle = U_PS_USERSTYLE; } i++; } if (linestyle == U_PS_USERSTYLE) { n_dash = style->stroke_dasharray.values.size(); dash = new uint32_t[n_dash]; for (i = 0; i < n_dash; i++) { dash[i] = MAX(1, (uint32_t)round(scale * style->stroke_dasharray.values[i].value * PX2WORLD)); } } } } elp = extlogpen_set( U_PS_GEOMETRIC | linestyle | linecap | linejoin, linewidth, brushStyle, hatchColor, hatchType, n_dash, dash); } else { // if (!style) linejoin = 0; elp = extlogpen_set( linestyle, 1, U_BS_SOLID, U_RGB(0, 0, 0), U_HS_HORIZONTAL, 0, nullptr); } rec = extcreatepen_set(&pen, eht, Bmi, cbPx, px, elp); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_pen at extcreatepen_set"); } free(elp); if (Bmi) { free(Bmi); } if (px) { free(px); // ct will always be NULL } rec = selectobject_set(pen, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_pen at selectobject_set"); } hpen = pen; // need this later for destroy_pen if (linejoin == U_PS_JOIN_MITER) { float miterlimit = style->stroke_miterlimit.value; // This is a ratio. if (miterlimit < 1) { miterlimit = 1; } rec = U_EMRSETMITERLIMIT_set((uint32_t) miterlimit); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::create_pen at U_EMRSETMITERLIMIT_set"); } } if (n_dash) { delete[] dash; } return 0; } // set the current pen to the stock object NULL_PEN and then delete the defined pen object, if there is one. void PrintEmf::destroy_pen() { char *rec = nullptr; // before an object may be safely deleted it must no longer be selected // select in a stock object to deselect this one, the stock object should // never be used because we always select in a new one before drawing anythingrestore previous brush, necessary??? Would using a default stock object not work? rec = selectobject_set(U_NULL_PEN, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::destroy_pen at selectobject_set"); } if (hpen) { rec = deleteobject_set(&hpen, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::destroy_pen"); } hpen = 0; } } /* Return a Path consisting of just the corner points of the single path in a PathVector. If the PathVector has more than one path, or that one path is open, or any of its segments are curved, then the returned PathVector is an empty path. If the input path is already just straight lines and vertices the output will be the same as the sole path in the input. */ Geom::Path PrintEmf::pathv_to_simple_polygon(Geom::PathVector const &pathv, int *vertices) { Geom::Point P1_trail; Geom::Point P1; Geom::Point P1_lead; Geom::Point v1,v2; Geom::Path output; Geom::Path bad; Geom::PathVector pv = pathv_to_linear_and_cubic_beziers(pathv); Geom::PathVector::const_iterator pit = pv.begin(); Geom::PathVector::const_iterator pit2 = pv.begin(); int first_seg=1; ++pit2; *vertices = 0; if(pit->end_closed() != pit->end_default())return(bad); // path must be closed if(pit2 != pv.end())return(bad); // there may only be one path P1_trail = pit->finalPoint(); Geom::Path::const_iterator cit = pit->begin(); P1 = cit->initialPoint(); for(;cit != pit->end_closed();++cit) { if (!is_straight_curve(*cit)) { *vertices = 0; return(bad); } P1_lead = cit->finalPoint(); if(Geom::are_near(P1_lead, P1, 1e-5))continue; // duplicate points at the same coordinate v1 = unit_vector(P1 - P1_trail); v2 = unit_vector(P1_lead - P1 ); if(Geom::are_near(dot(v1,v2), 1.0, 1e-5)){ // P1 is within a straight line P1 = P1_lead; continue; } // P1 is the center point of a turn of some angle if(!*vertices){ output.start( P1 ); output.close( pit->closed() ); } if(!Geom::are_near(P1, P1_trail, 1e-5)){ // possible for P1 to start on the end point Geom::LineSegment ls(P1_trail, P1); output.append(ls); if(first_seg){ *vertices += 2; first_seg=0; } else { *vertices += 1; } } P1_trail = P1; P1 = P1_lead; } return(output); } /* Returns the simplified PathVector (no matter what). Sets is_rect if it is a rectangle. Sets angle that will rotate side closest to horizontal onto horizontal. */ Geom::Path PrintEmf::pathv_to_rect(Geom::PathVector const &pathv, bool *is_rect, double *angle) { Geom::Point P1_trail; Geom::Point P1; Geom::Point v1,v2; int vertices; Geom::Path pR = pathv_to_simple_polygon(pathv, &vertices); *is_rect = false; if(vertices==4){ // or else it cannot be a rectangle int vertex_count=0; /* Get the ends of the LAST line segment. Find minimum rotation to align rectangle with X,Y axes. (Very degenerate if it is rotated 45 degrees.) */ *angle = 10.0; /* must be > than the actual angle in radians. */ for(Geom::Path::iterator cit = pR.begin();; ++cit){ P1_trail = cit->initialPoint(); P1 = cit->finalPoint(); v1 = unit_vector(P1 - P1_trail); if(v1[Geom::X] > 0){ // only check the 1 or 2 points on vectors aimed the same direction as unit X double ang = asin(v1[Geom::Y]); // because component is rotation by ang of {1,0| vector if(fabs(ang) < fabs(*angle))*angle = -ang; // y increases down, flips sign on angle } if(cit == pR.end_open())break; } /* For increased numerical stability, snap the angle to the nearest 1/100th of a degree. */ double convert = 36000.0/ (2.0 * M_PI); *angle = round(*angle * convert)/convert; // at this stage v1 holds the last vector in the path, whichever direction it points. for(Geom::Path::iterator cit = pR.begin(); ;++cit) { v2 = v1; P1_trail = cit->initialPoint(); P1 = cit->finalPoint(); v1 = unit_vector(P1 - P1_trail); // P1 is center of a turn that is not 90 degrees. Limit comes from cos(89.9) = .001745 if(!Geom::are_near(dot(v1,v2), 0.0, 2e-3))break; vertex_count++; if(cit == pR.end_open())break; } if(vertex_count == 4){ *is_rect=true; } } return(pR); } /* Compare a vector with a rectangle's orientation (angle needed to rotate side(s) closest to horizontal to exactly horizontal) and return: 0 none of the following 1 parallel to horizontal 2 parallel to vertical 3 antiparallel to horizontal 4 antiparallel to vertical */ int PrintEmf::vector_rect_alignment(double angle, Geom::Point vtest){ int stat = 0; Geom::Point v1 = Geom::unit_vector(vtest); // unit vector to test alignment Geom::Point v2 = Geom::Point(1,0) * Geom::Rotate(-angle); // unit horizontal side (sign change because Y increases DOWN) Geom::Point v3 = Geom::Point(0,1) * Geom::Rotate(-angle); // unit horizontal side (sign change because Y increases DOWN) if( Geom::are_near(dot(v1,v2), 1.0, 1e-5)){ stat = 1; } else if(Geom::are_near(dot(v1,v2),-1.0, 1e-5)){ stat = 2; } else if(Geom::are_near(dot(v1,v3), 1.0, 1e-5)){ stat = 3; } else if(Geom::are_near(dot(v1,v3),-1.0, 1e-5)){ stat = 4; } return(stat); } /* retrieve the point at the indicated corner: 0 UL (and default) 1 UR 2 LR 3 LL Needed because the start can be any point, and the direction could run either clockwise or counterclockwise. This should work even if the corners of the rectangle are slightly displaced. */ Geom::Point PrintEmf::get_pathrect_corner(Geom::Path pathRect, double angle, int corner){ Geom::Point center(0,0); for(Geom::Path::iterator cit = pathRect.begin(); ; ++cit) { center += cit->initialPoint()/4.0; if(cit == pathRect.end_open())break; } int LR; // 1 if Left, 0 if Right int UL; // 1 if Lower, 0 if Upper (as viewed on screen, y coordinates increase downwards) switch(corner){ case 1: //UR LR = 0; UL = 0; break; case 2: //LR LR = 0; UL = 1; break; case 3: //LL LR = 1; UL = 1; break; default: //UL LR = 1; UL = 0; break; } Geom::Point v1 = Geom::Point(1,0) * Geom::Rotate(-angle); // unit horizontal side (sign change because Y increases DOWN) Geom::Point v2 = Geom::Point(0,1) * Geom::Rotate(-angle); // unit vertical side (sign change because Y increases DOWN) Geom::Point P1; for(Geom::Path::iterator cit = pathRect.begin(); ; ++cit) { P1 = cit->initialPoint(); if ( ( LR == (dot(P1 - center,v1) > 0 ? 0 : 1) ) && ( UL == (dot(P1 - center,v2) > 0 ? 1 : 0) ) ) break; if(cit == pathRect.end_open())break; } return(P1); } U_TRIVERTEX PrintEmf::make_trivertex(Geom::Point Pt, U_COLORREF uc){ U_TRIVERTEX tv; using Geom::X; using Geom::Y; tv.x = (int32_t) round(Pt[X]); tv.y = (int32_t) round(Pt[Y]); tv.Red = uc.Red << 8; tv.Green = uc.Green << 8; tv.Blue = uc.Blue << 8; tv.Alpha = uc.Reserved << 8; // EMF will ignore this return(tv); } /* Examine clip. If there is a (new) one then apply it. If there is one and it is the same as the preceding one, leave the preceding one active. If style is NULL terminate the current clip, if any, and return. */ void PrintEmf::do_clip_if_present(SPStyle const *style){ char *rec; static SPClipPath *scpActive = nullptr; if(!style){ if(scpActive){ // clear the existing clip rec = U_EMRRESTOREDC_set(-1); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::fill at U_EMRRESTOREDC_set"); } scpActive=nullptr; } } else { /* The current implementation converts only one level of clipping. If there were more clips further up the stack they should be combined with the pathvector using "and". Since this comes up rarely, and would involve a lot of searching (all the way up the stack for every draw operation), it has not yet been implemented. Note, to debug this section of code use print statements on sp_svg_write_path(combined_pathvector). */ /* find the first clip_ref at object or up the stack. There may not be one. */ SPClipPath *scp = nullptr; SPItem *item = SP_ITEM(style->object); while(true) { scp = item->getClipObject(); if(scp)break; item = SP_ITEM(item->parent); if(!item || SP_IS_ROOT(item))break; // this will never be a clipping path } if(scp != scpActive){ // change or remove the clipping if(scpActive){ // clear the existing clip rec = U_EMRRESTOREDC_set(-1); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::fill at U_EMRRESTOREDC_set"); } scpActive = nullptr; } if (scp) { // set the new clip /* because of units and who knows what other transforms that might be applied above we need the full transform all the way to the root. */ Geom::Affine tf = item->transform; SPItem *scan_item = item; while(true) { scan_item = SP_ITEM(scan_item->parent); if(!scan_item)break; tf *= scan_item->transform; } tf *= Geom::Scale(_doc_unit_scale);; // Transform must be in PIXELS, no matter what the document unit is. /* find the clipping path */ Geom::PathVector combined_pathvector; Geom::Affine tfc; // clipping transform, generally not the same as item transform for (auto& child: scp->children) { item = SP_ITEM(&child); if (!item) { break; } if (SP_IS_GROUP(item)) { // not implemented // return sp_group_render(item); combined_pathvector = merge_PathVector_with_group(combined_pathvector, item, tfc); } else if (SP_IS_SHAPE(item)) { combined_pathvector = merge_PathVector_with_shape(combined_pathvector, item, tfc); } else { // not implemented } } if (!combined_pathvector.empty()) { // if clipping path isn't empty, define EMF clipping record scpActive = scp; // remember for next time // the sole purpose of this SAVEDC is to let us clear the clipping region later. rec = U_EMRSAVEDC_set(); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at U_EMRSAVEDC_set"); } (void) draw_pathv_to_EMF(combined_pathvector, tf); rec = U_EMRSELECTCLIPPATH_set(U_RGN_COPY); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::do_clip_if_present at U_EMRSELECTCLIPPATH_set"); } } else { scpActive = nullptr; // no valid path available to draw, so no DC was saved, so no signal to restore } } // change or remove clipping } // scp exists } // style exists } Geom::PathVector PrintEmf::merge_PathVector_with_group(Geom::PathVector const &combined_pathvector, SPItem const *item, const Geom::Affine &transform) { // sanity test, only a group should be passed in, return empty if something else happens auto group = dynamic_cast(item); if (!group) return {}; Geom::PathVector new_combined_pathvector = combined_pathvector; Geom::Affine tfc = item->transform * transform; for (auto& child: group->children) { item = SP_ITEM(&child); if (!item) { break; } if (SP_IS_GROUP(item)) { new_combined_pathvector = merge_PathVector_with_group(new_combined_pathvector, item, tfc); // could be endlessly recursive on a badly formed SVG } else if (SP_IS_SHAPE(item)) { new_combined_pathvector = merge_PathVector_with_shape(new_combined_pathvector, item, tfc); } else { // not implemented } } return new_combined_pathvector; } Geom::PathVector PrintEmf::merge_PathVector_with_shape(Geom::PathVector const &combined_pathvector, SPItem const *item, const Geom::Affine &transform) { Geom::PathVector new_combined_pathvector; auto shape = dynamic_cast(item); // sanity test, only a shape should be passed in, return empty if something else happens if (!shape) return new_combined_pathvector; Geom::Affine tfc = item->transform * transform; if (shape->curve()) { Geom::PathVector const &new_vect = shape->curve()->get_pathvector(); if(combined_pathvector.empty()){ new_combined_pathvector = new_vect * tfc; } else { new_combined_pathvector = sp_pathvector_boolop(new_vect * tfc, combined_pathvector, bool_op_union , (FillRule) fill_oddEven, (FillRule) fill_oddEven); } } return new_combined_pathvector; } unsigned int PrintEmf::fill( Inkscape::Extension::Print * /*mod*/, Geom::PathVector const &pathv, Geom::Affine const & /*transform*/, SPStyle const *style, Geom::OptRect const &/*pbox*/, Geom::OptRect const &/*dbox*/, Geom::OptRect const &/*bbox*/) { char *rec; using Geom::X; using Geom::Y; Geom::Affine tf = m_tr_stack.top(); do_clip_if_present(style); // If clipping is needed set it up use_fill = true; use_stroke = false; fill_transform = tf; int brush_stat = create_brush(style, nullptr); /* native linear gradients are only used if the object is a rectangle AND the gradient is parallel to the sides of the object */ bool is_Rect = false; double angle; int rectDir=0; Geom::Path pathRect; if(FixPPTLinGrad && brush_stat && gv.mode == DRAW_LINEAR_GRADIENT){ Geom::PathVector pvr = pathv * fill_transform; pathRect = pathv_to_rect(pvr, &is_Rect, &angle); if(is_Rect){ /* Gradientfill records can only be used if the gradient is parallel to the sides of the rectangle. That must be checked here so that we can fall back to another form of gradient fill if it is not the case. */ rectDir = vector_rect_alignment(angle, (gv.p2 - gv.p1) * fill_transform); if(!rectDir)is_Rect = false; } if(!is_Rect && !FixPPTGrad2Polys)brush_stat=0; // fall all the way back to a solid fill } if (brush_stat) { // only happens if the style is a gradient /* Handle gradients. Uses modified livarot as 2geom boolops is currently broken. Can handle gradients with multiple stops. The overlap is needed to avoid antialiasing artifacts when edges are not strictly aligned on pixel boundaries. There is an inevitable loss of accuracy saving through an EMF file because of the integer coordinate system. Keep the overlap quite large so that loss of accuracy does not remove an overlap. */ destroy_pen(); //this sets the NULL_PEN, otherwise gradient slices may display with boundaries, see longer explanation below Geom::Path cutter; float rgb[3]; U_COLORREF wc, c1, c2; FillRule frb = SPWR_to_LVFR((SPWindRule) style->fill_rule.computed); double doff, doff_base, doff_range; double divisions = 128.0; int nstops; int istop = 1; float opa; // opacity at stop SPRadialGradient *tg = (SPRadialGradient *)(gv.grad); // linear/radial are the same here nstops = tg->vector.stops.size(); tg->vector.stops[0].color.get_rgb_floatv(rgb); opa = tg->vector.stops[0].opacity; // first stop c1 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); tg->vector.stops[nstops - 1].color.get_rgb_floatv(rgb); opa = tg->vector.stops[nstops - 1].opacity; // last stop c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); doff = 0.0; doff_base = 0.0; doff_range = tg->vector.stops[1].offset; // next or last stop if (gv.mode == DRAW_RADIAL_GRADIENT) { Geom::Point xv = gv.p2 - gv.p1; // X' vector Geom::Point yv = gv.p3 - gv.p1; // Y' vector Geom::Point xuv = Geom::unit_vector(xv); // X' unit vector double rx = hypot(xv[X], xv[Y]); double ry = hypot(yv[X], yv[Y]); double range = fmax(rx, ry); // length along the gradient double step = range / divisions; // adequate approximation for gradient double overlap = step / 4.0; // overlap slices slightly double start; double stop; Geom::PathVector pathvc, pathvr; /* radial gradient might stop part way through the shape, fill with outer color from there to "infinity". Do this first so that outer colored ring will overlay it. */ pathvc = center_elliptical_hole_as_SVG_PathV(gv.p1, rx * (1.0 - overlap / range), ry * (1.0 - overlap / range), asin(xuv[Y])); pathvr = sp_pathvector_boolop(pathvc, pathv, bool_op_inters, (FillRule) fill_oddEven, frb); wc = weight_opacity(c2); (void) create_brush(style, &wc); print_pathv(pathvr, fill_transform); tg->vector.stops[istop].color.get_rgb_floatv(rgb); opa = tg->vector.stops[istop].opacity; c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); for (start = 0.0; start < range; start += step, doff += 1. / divisions) { stop = start + step + overlap; if (stop > range) { stop = range; } wc = weight_colors(c1, c2, (doff - doff_base) / (doff_range - doff_base)); (void) create_brush(style, &wc); pathvc = center_elliptical_ring_as_SVG_PathV(gv.p1, rx * start / range, ry * start / range, rx * stop / range, ry * stop / range, asin(xuv[Y])); pathvr = sp_pathvector_boolop(pathvc, pathv, bool_op_inters, (FillRule) fill_nonZero, frb); print_pathv(pathvr, fill_transform); // show the intersection if (doff >= doff_range) { istop++; if (istop >= nstops) { istop = nstops - 1; continue; // could happen on a rounding error } doff_base = doff_range; doff_range = tg->vector.stops[istop].offset; // next or last stop c1 = c2; tg->vector.stops[istop].color.get_rgb_floatv(rgb); opa = tg->vector.stops[istop].opacity; c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); } } } else if (gv.mode == DRAW_LINEAR_GRADIENT) { if(is_Rect){ int gMode; Geom::Point ul, ur, lr; Geom::Point outUL, outLR; // UL,LR corners of a stop rectangle, in OUTPUT coordinates U_TRIVERTEX ut[2]; U_GRADIENT4 ug4; U_RECTL rcb; U_XFORM tmpTransform; double wRect, hRect; /* coordinates: upper left, upper right, and lower right corners of the rectangle. inkscape transform already applied, but needs to be scaled to EMF coordinates. */ ul = get_pathrect_corner(pathRect, angle, 0) * PX2WORLD; ur = get_pathrect_corner(pathRect, angle, 1) * PX2WORLD; lr = get_pathrect_corner(pathRect, angle, 2) * PX2WORLD; wRect = Geom::distance(ul,ur); hRect = Geom::distance(ur,lr); /* The basic rectangle for all of these is placed with its UL corner at 0,0 with a size wRect,hRect. Apply a world transform to place/scale it into the appropriate position on the drawing. Actual gradientfill records are either this entire rectangle or slices of it as defined by the stops. This rectangle has already been transformed by tf (whatever rotation/scale) Inkscape had applied to it. */ Geom::Affine tf2 = Geom::Rotate(-angle); // the rectangle may be drawn skewed to the coordinate system tmpTransform.eM11 = tf2[0]; tmpTransform.eM12 = tf2[1]; tmpTransform.eM21 = tf2[2]; tmpTransform.eM22 = tf2[3]; tmpTransform.eDx = round((ul)[Geom::X]); // use explicit round for better stability tmpTransform.eDy = round((ul)[Geom::Y]); rec = U_EMRSAVEDC_set(); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at U_EMRSAVEDC_set"); } rec = U_EMRMODIFYWORLDTRANSFORM_set(tmpTransform, U_MWT_LEFTMULTIPLY); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at EMRMODIFYWORLDTRANSFORM"); } for(;istopvector.stops[istop].offset; // next or last stop if(rectDir == 1 || rectDir == 2){ outUL = Geom::Point(doff_base *wRect, 0 ); outLR = Geom::Point(doff_range*wRect, hRect); gMode = U_GRADIENT_FILL_RECT_H; } else { outUL = Geom::Point(0, doff_base *hRect); outLR = Geom::Point(wRect,doff_range*hRect); gMode = U_GRADIENT_FILL_RECT_V; } doff_base = doff_range; rcb.left = round(outUL[X]); // use explicit round for better stability rcb.top = round(outUL[Y]); rcb.right = round(outLR[X]); rcb.bottom = round(outLR[Y]); tg->vector.stops[istop].color.get_rgb_floatv(rgb); opa = tg->vector.stops[istop].opacity; c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); if(rectDir == 2 || rectDir == 4){ // gradient is reversed, so swap colors ut[0] = make_trivertex(outUL, c2); ut[1] = make_trivertex(outLR, c1); } else { ut[0] = make_trivertex(outUL, c1); ut[1] = make_trivertex(outLR, c2); } c1 = c2; // for next stop ug4.UpperLeft = 0; ug4.LowerRight= 1; rec = U_EMRGRADIENTFILL_set(rcb, 2, 1, gMode, ut, (uint32_t *) &ug4 ); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::fill at U_EMRGRADIENTFILL_set"); } } rec = U_EMRRESTOREDC_set(-1); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::fill at U_EMRRESTOREDC_set"); } } else { Geom::Point uv = Geom::unit_vector(gv.p2 - gv.p1); // unit vector Geom::Point puv = uv.cw(); // perp. to unit vector double range = Geom::distance(gv.p1, gv.p2); // length along the gradient double step = range / divisions; // adequate approximation for gradient double overlap = step / 4.0; // overlap slices slightly double start; double stop; Geom::PathVector pathvc, pathvr; /* before lower end of gradient, overlap first slice position */ wc = weight_opacity(c1); (void) create_brush(style, &wc); pathvc = rect_cutter(gv.p1, uv * (overlap), uv * (-50000.0), puv * 50000.0); pathvr = sp_pathvector_boolop(pathvc, pathv, bool_op_inters, (FillRule) fill_nonZero, frb); print_pathv(pathvr, fill_transform); /* after high end of gradient, overlap last slice position */ wc = weight_opacity(c2); (void) create_brush(style, &wc); pathvc = rect_cutter(gv.p2, uv * (-overlap), uv * (50000.0), puv * 50000.0); pathvr = sp_pathvector_boolop(pathvc, pathv, bool_op_inters, (FillRule) fill_nonZero, frb); print_pathv(pathvr, fill_transform); tg->vector.stops[istop].color.get_rgb_floatv(rgb); opa = tg->vector.stops[istop].opacity; c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); for (start = 0.0; start < range; start += step, doff += 1. / divisions) { stop = start + step + overlap; if (stop > range) { stop = range; } pathvc = rect_cutter(gv.p1, uv * start, uv * stop, puv * 50000.0); wc = weight_colors(c1, c2, (doff - doff_base) / (doff_range - doff_base)); (void) create_brush(style, &wc); Geom::PathVector pathvr = sp_pathvector_boolop(pathvc, pathv, bool_op_inters, (FillRule) fill_nonZero, frb); print_pathv(pathvr, fill_transform); // show the intersection if (doff >= doff_range) { istop++; if (istop >= nstops) { istop = nstops - 1; continue; // could happen on a rounding error } doff_base = doff_range; doff_range = tg->vector.stops[istop].offset; // next or last stop c1 = c2; tg->vector.stops[istop].color.get_rgb_floatv(rgb); opa = tg->vector.stops[istop].opacity; c2 = U_RGBA(255 * rgb[0], 255 * rgb[1], 255 * rgb[2], 255 * opa); } } } } else { g_error("Fatal programming error in PrintEmf::fill, invalid gradient type detected"); } use_fill = false; // gradients handled, be sure stroke does not use stroke and fill } else { /* Inkscape was not calling create_pen for objects with no border. This was because it never called stroke() (next method). PPT, and presumably others, pick whatever they want for the border if it is not specified, so no border can become a visible border. To avoid this force the pen to NULL_PEN if we can determine that no pen will be needed after the fill. */ if (style->stroke.noneSet || style->stroke_width.computed == 0.0) { destroy_pen(); //this sets the NULL_PEN } /* postpone fill in case stroke also required AND all stroke paths closed Dashes converted to line segments will "open" a closed path. */ bool all_closed = true; for (const auto & pit : pathv) { for (Geom::Path::const_iterator cit = pit.begin(); cit != pit.end_open(); ++cit) { if (pit.end_default() != pit.end_closed()) { all_closed = false; } } } if ( (style->stroke.isNone() || style->stroke.noneSet || style->stroke_width.computed == 0.0) || (!style->stroke_dasharray.values.empty() && FixPPTDashLine) || !all_closed ) { print_pathv(pathv, fill_transform); // do any fills. side effect: clears fill_pathv use_fill = false; } } return 0; } unsigned int PrintEmf::stroke( Inkscape::Extension::Print * /*mod*/, Geom::PathVector const &pathv, const Geom::Affine &/*transform*/, const SPStyle *style, Geom::OptRect const &/*pbox*/, Geom::OptRect const &/*dbox*/, Geom::OptRect const &/*bbox*/) { char *rec = nullptr; Geom::Affine tf = m_tr_stack.top(); do_clip_if_present(style); // If clipping is needed set it up use_stroke = true; // use_fill was set in ::fill, if it is needed if (create_pen(style, tf)) { return 0; } if (!style->stroke_dasharray.values.empty() && FixPPTDashLine) { // convert the path, gets its complete length, and then make a new path with parameter length instead of t Geom::Piecewise > tmp_pathpw; // pathv-> sbasis Geom::Piecewise > tmp_pathpw2; // sbasis using arc length parameter Geom::Piecewise > tmp_pathpw3; // new (discontinuous) path, composed of dots/dashes Geom::Piecewise > first_frag; // first fragment, will be appended at end int n_dash = style->stroke_dasharray.values.size(); int i = 0; //dash index double tlength; // length of tmp_pathpw double slength = 0.0; // start of gragment double elength; // end of gragment for (const auto & i : pathv) { tmp_pathpw.concat(i.toPwSb()); } tlength = length(tmp_pathpw, 0.1); tmp_pathpw2 = arc_length_parametrization(tmp_pathpw); // go around the dash array repeatedly until the entire path is consumed (but not beyond). while (slength < tlength) { elength = slength + style->stroke_dasharray.values[i++].value; if (elength > tlength) { elength = tlength; } Geom::Piecewise > fragment(portion(tmp_pathpw2, slength, elength)); if (slength) { tmp_pathpw3.concat(fragment); } else { first_frag = fragment; } slength = elength; slength += style->stroke_dasharray.values[i++].value; // the gap if (i >= n_dash) { i = 0; } } tmp_pathpw3.concat(first_frag); // may merge line around start point Geom::PathVector out_pathv = Geom::path_from_piecewise(tmp_pathpw3, 0.01); print_pathv(out_pathv, tf); } else { print_pathv(pathv, tf); } use_stroke = false; use_fill = false; if (usebk) { // OPAQUE was set, revert to TRANSPARENT usebk = false; rec = U_EMRSETBKMODE_set(U_TRANSPARENT); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::stroke at U_EMRSETBKMODE_set"); } } return 0; } // Draws simple_shapes, those with closed EMR_* primitives, like polygons, rectangles and ellipses. // These use whatever the current pen/brush are and need not be followed by a FILLPATH or STROKEPATH. // For other paths it sets a few flags and returns. bool PrintEmf::print_simple_shape(Geom::PathVector const &pathv, const Geom::Affine &transform) { Geom::PathVector pv = pathv_to_linear_and_cubic_beziers(pathv * transform); int nodes = 0; int moves = 0; int lines = 0; int curves = 0; char *rec = nullptr; for (auto & pit : pv) { moves++; nodes++; for (Geom::Path::iterator cit = pit.begin(); cit != pit.end_open(); ++cit) { nodes++; if (is_straight_curve(*cit)) { lines++; } else if (dynamic_cast(&*cit)) { curves++; } } } if (!nodes) { return false; } U_POINT *lpPoints = new U_POINT[moves + lines + curves * 3]; int i = 0; /** * For all Subpaths in the */ for (auto & pit : pv) { using Geom::X; using Geom::Y; Geom::Point p0 = pit.initialPoint(); p0[X] = (p0[X] * PX2WORLD); p0[Y] = (p0[Y] * PX2WORLD); int32_t const x0 = (int32_t) round(p0[X]); int32_t const y0 = (int32_t) round(p0[Y]); lpPoints[i].x = x0; lpPoints[i].y = y0; i = i + 1; /** * For all segments in the subpath */ for (Geom::Path::iterator cit = pit.begin(); cit != pit.end_open(); ++cit) { if (is_straight_curve(*cit)) { //Geom::Point p0 = cit->initialPoint(); Geom::Point p1 = cit->finalPoint(); //p0[X] = (p0[X] * PX2WORLD); p1[X] = (p1[X] * PX2WORLD); //p0[Y] = (p0[Y] * PX2WORLD); p1[Y] = (p1[Y] * PX2WORLD); //int32_t const x0 = (int32_t) round(p0[X]); //int32_t const y0 = (int32_t) round(p0[Y]); int32_t const x1 = (int32_t) round(p1[X]); int32_t const y1 = (int32_t) round(p1[Y]); lpPoints[i].x = x1; lpPoints[i].y = y1; i = i + 1; } else if (Geom::CubicBezier const *cubic = dynamic_cast(&*cit)) { std::vector points = cubic->controlPoints(); //Geom::Point p0 = points[0]; Geom::Point p1 = points[1]; Geom::Point p2 = points[2]; Geom::Point p3 = points[3]; //p0[X] = (p0[X] * PX2WORLD); p1[X] = (p1[X] * PX2WORLD); p2[X] = (p2[X] * PX2WORLD); p3[X] = (p3[X] * PX2WORLD); //p0[Y] = (p0[Y] * PX2WORLD); p1[Y] = (p1[Y] * PX2WORLD); p2[Y] = (p2[Y] * PX2WORLD); p3[Y] = (p3[Y] * PX2WORLD); //int32_t const x0 = (int32_t) round(p0[X]); //int32_t const y0 = (int32_t) round(p0[Y]); int32_t const x1 = (int32_t) round(p1[X]); int32_t const y1 = (int32_t) round(p1[Y]); int32_t const x2 = (int32_t) round(p2[X]); int32_t const y2 = (int32_t) round(p2[Y]); int32_t const x3 = (int32_t) round(p3[X]); int32_t const y3 = (int32_t) round(p3[Y]); lpPoints[i].x = x1; lpPoints[i].y = y1; lpPoints[i + 1].x = x2; lpPoints[i + 1].y = y2; lpPoints[i + 2].x = x3; lpPoints[i + 2].y = y3; i = i + 3; } } } bool done = false; bool closed = (lpPoints[0].x == lpPoints[i - 1].x) && (lpPoints[0].y == lpPoints[i - 1].y); bool polygon = false; bool rectangle = false; bool ellipse = false; if (moves == 1 && moves + lines == nodes && closed) { polygon = true; // if (nodes==5) { // disable due to LP Bug 407394 // if (lpPoints[0].x == lpPoints[3].x && lpPoints[1].x == lpPoints[2].x && // lpPoints[0].y == lpPoints[1].y && lpPoints[2].y == lpPoints[3].y) // { // rectangle = true; // } // } } else if (moves == 1 && nodes == 5 && moves + curves == nodes && closed) { // if (lpPoints[0].x == lpPoints[1].x && lpPoints[1].x == lpPoints[11].x && // lpPoints[5].x == lpPoints[6].x && lpPoints[6].x == lpPoints[7].x && // lpPoints[2].x == lpPoints[10].x && lpPoints[3].x == lpPoints[9].x && lpPoints[4].x == lpPoints[8].x && // lpPoints[2].y == lpPoints[3].y && lpPoints[3].y == lpPoints[4].y && // lpPoints[8].y == lpPoints[9].y && lpPoints[9].y == lpPoints[10].y && // lpPoints[5].y == lpPoints[1].y && lpPoints[6].y == lpPoints[0].y && lpPoints[7].y == lpPoints[11].y) // { // disable due to LP Bug 407394 // ellipse = true; // } } if (polygon || ellipse) { if (use_fill && !use_stroke) { // only fill rec = selectobject_set(U_NULL_PEN, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_simple_shape at selectobject_set pen"); } } else if (!use_fill && use_stroke) { // only stroke rec = selectobject_set(U_NULL_BRUSH, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_simple_shape at selectobject_set brush"); } } if (polygon) { if (rectangle) { U_RECTL rcl = rectl_set((U_POINTL) { lpPoints[0].x, lpPoints[0].y }, (U_POINTL) { lpPoints[2].x, lpPoints[2].y }); rec = U_EMRRECTANGLE_set(rcl); } else { rec = U_EMRPOLYGON_set(U_RCL_DEF, nodes, lpPoints); } } else if (ellipse) { U_RECTL rcl = rectl_set((U_POINTL) { lpPoints[6].x, lpPoints[3].y }, (U_POINTL) { lpPoints[0].x, lpPoints[9].y }); rec = U_EMRELLIPSE_set(rcl); } if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_simple_shape at retangle/ellipse/polygon"); } done = true; // replace the handle we moved above, assuming there was something set already if (use_fill && !use_stroke && hpen) { // only fill rec = selectobject_set(hpen, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_simple_shape at selectobject_set pen"); } } else if (!use_fill && use_stroke && hbrush) { // only stroke rec = selectobject_set(hbrush, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_simple_shape at selectobject_set brush"); } } } delete[] lpPoints; return done; } /** Some parts based on win32.cpp by Lauris Kaplinski . Was a part of Inkscape in the past (or will be in the future?) Not in current trunk. (4/19/2012) Limitations of this code: 1. Transparency is lost on export. (Apparently a limitation of the EMF format.) 2. Probably messes up if row stride != w*4 3. There is still a small memory leak somewhere, possibly in a pixbuf created in a routine that calls this one and passes px, but never removes the rest of the pixbuf. The first time this is called it leaked 5M (in one test) and each subsequent call leaked around 200K more. If this routine is reduced to if(1)return(0); and called for a single 1280 x 1024 image then the program leaks 11M per call, or roughly the size of two bitmaps. */ unsigned int PrintEmf::image( Inkscape::Extension::Print * /* module */, /** not used */ unsigned char *rgba_px, /** array of pixel values, Gdk::Pixbuf bitmap format */ unsigned int w, /** width of bitmap */ unsigned int h, /** height of bitmap */ unsigned int rs, /** row stride (normally w*4) */ Geom::Affine const &tf_rect, /** affine transform only used for defining location and size of rect, for all other transforms, use the one from m_tr_stack */ SPStyle const *style) /** provides indirect link to image object */ { double x1, y1, dw, dh; char *rec = nullptr; Geom::Affine tf = m_tr_stack.top(); do_clip_if_present(style); // If clipping is needed set it up rec = U_EMRSETSTRETCHBLTMODE_set(U_COLORONCOLOR); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at EMRHEADER"); } x1 = tf_rect[4]; y1 = tf_rect[5]; dw = ((double) w) * tf_rect[0]; dh = ((double) h) * tf_rect[3]; Geom::Point pLL(x1, y1); Geom::Point pLL2 = pLL * tf; //location of LL corner in Inkscape coordinates char *px; uint32_t cbPx; uint32_t colortype; PU_RGBQUAD ct; int numCt; U_BITMAPINFOHEADER Bmih; PU_BITMAPINFO Bmi; colortype = U_BCBM_COLOR32; (void) RGBA_to_DIB(&px, &cbPx, &ct, &numCt, (char *) rgba_px, w, h, w * 4, colortype, 0, 1); Bmih = bitmapinfoheader_set(w, h, 1, colortype, U_BI_RGB, 0, PXPERMETER, PXPERMETER, numCt, 0); Bmi = bitmapinfo_set(Bmih, ct); U_POINTL Dest = pointl_set(round(pLL2[Geom::X] * PX2WORLD), round(pLL2[Geom::Y] * PX2WORLD)); U_POINTL cDest = pointl_set(round(dw * PX2WORLD), round(dh * PX2WORLD)); U_POINTL Src = pointl_set(0, 0); U_POINTL cSrc = pointl_set(w, h); /* map the integer Dest coordinates back into pLL2, so that the rounded part does not destabilize the transform offset below */ pLL2[Geom::X] = Dest.x; pLL2[Geom::Y] = Dest.y; pLL2 /= PX2WORLD; if (!FixImageRot) { /* Rotate images - some programs cannot read them in correctly if they are rotated */ tf[4] = tf[5] = 0.0; // get rid of the offset in the transform Geom::Point pLL2prime = pLL2 * tf; U_XFORM tmpTransform; tmpTransform.eM11 = tf[0]; tmpTransform.eM12 = tf[1]; tmpTransform.eM21 = tf[2]; tmpTransform.eM22 = tf[3]; tmpTransform.eDx = (pLL2[Geom::X] - pLL2prime[Geom::X]) * PX2WORLD; tmpTransform.eDy = (pLL2[Geom::Y] - pLL2prime[Geom::Y]) * PX2WORLD; rec = U_EMRSAVEDC_set(); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at U_EMRSAVEDC_set"); } rec = U_EMRMODIFYWORLDTRANSFORM_set(tmpTransform, U_MWT_LEFTMULTIPLY); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at EMRMODIFYWORLDTRANSFORM"); } } rec = U_EMRSTRETCHDIBITS_set( U_RCL_DEF, //! Bounding rectangle in device units Dest, //! Destination UL corner in logical units cDest, //! Destination W & H in logical units Src, //! Source UL corner in logical units cSrc, //! Source W & H in logical units U_DIB_RGB_COLORS, //! DIBColors Enumeration U_SRCCOPY, //! RasterOPeration Enumeration Bmi, //! (Optional) bitmapbuffer (U_BITMAPINFO section) h * rs, //! size in bytes of px px //! (Optional) bitmapbuffer (U_BITMAPINFO section) ); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at U_EMRSTRETCHDIBITS_set"); } free(px); free(Bmi); if (numCt) { free(ct); } if (!FixImageRot) { rec = U_EMRRESTOREDC_set(-1); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::image at U_EMRRESTOREDC_set"); } } return 0; } unsigned int PrintEmf::draw_pathv_to_EMF(Geom::PathVector const &pathv, const Geom::Affine &transform) { char *rec; /* inkscape to EMF scaling is done below, but NOT the rotation/translation transform, that is handled by the EMF MODIFYWORLDTRANSFORM record */ Geom::PathVector pv = pathv_to_linear_and_cubic_beziers(pathv * transform); rec = U_EMRBEGINPATH_set(); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRBEGINPATH_set"); } /** * For all Subpaths in the */ for (const auto & pit : pv) { using Geom::X; using Geom::Y; Geom::Point p0 = pit.initialPoint(); p0[X] = (p0[X] * PX2WORLD); p0[Y] = (p0[Y] * PX2WORLD); U_POINTL ptl = pointl_set((int32_t) round(p0[X]), (int32_t) round(p0[Y])); rec = U_EMRMOVETOEX_set(ptl); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRMOVETOEX_set"); } /** * For all segments in the subpath */ for (Geom::Path::const_iterator cit = pit.begin(); cit != pit.end_open(); ++cit) { if (is_straight_curve(*cit)) { //Geom::Point p0 = cit->initialPoint(); Geom::Point p1 = cit->finalPoint(); //p0[X] = (p0[X] * PX2WORLD); p1[X] = (p1[X] * PX2WORLD); //p0[Y] = (p0[Y] * PX2WORLD); p1[Y] = (p1[Y] * PX2WORLD); //int32_t const x0 = (int32_t) round(p0[X]); //int32_t const y0 = (int32_t) round(p0[Y]); ptl = pointl_set((int32_t) round(p1[X]), (int32_t) round(p1[Y])); rec = U_EMRLINETO_set(ptl); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRLINETO_set"); } } else if (Geom::CubicBezier const *cubic = dynamic_cast(&*cit)) { std::vector points = cubic->controlPoints(); //Geom::Point p0 = points[0]; Geom::Point p1 = points[1]; Geom::Point p2 = points[2]; Geom::Point p3 = points[3]; //p0[X] = (p0[X] * PX2WORLD); p1[X] = (p1[X] * PX2WORLD); p2[X] = (p2[X] * PX2WORLD); p3[X] = (p3[X] * PX2WORLD); //p0[Y] = (p0[Y] * PX2WORLD); p1[Y] = (p1[Y] * PX2WORLD); p2[Y] = (p2[Y] * PX2WORLD); p3[Y] = (p3[Y] * PX2WORLD); //int32_t const x0 = (int32_t) round(p0[X]); //int32_t const y0 = (int32_t) round(p0[Y]); int32_t const x1 = (int32_t) round(p1[X]); int32_t const y1 = (int32_t) round(p1[Y]); int32_t const x2 = (int32_t) round(p2[X]); int32_t const y2 = (int32_t) round(p2[Y]); int32_t const x3 = (int32_t) round(p3[X]); int32_t const y3 = (int32_t) round(p3[Y]); U_POINTL pt[3]; pt[0].x = x1; pt[0].y = y1; pt[1].x = x2; pt[1].y = y2; pt[2].x = x3; pt[2].y = y3; rec = U_EMRPOLYBEZIERTO_set(U_RCL_DEF, 3, pt); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRPOLYBEZIERTO_set"); } } else { g_warning("logical error, because pathv_to_linear_and_cubic_beziers was used"); } } if (pit.end_default() == pit.end_closed()) { // there may be multiples of this on a single path rec = U_EMRCLOSEFIGURE_set(); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRCLOSEFIGURE_set"); } } } rec = U_EMRENDPATH_set(); // there may be only be one of these on a single path if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::print_pathv at U_EMRENDPATH_set"); } return(0); } // may also be called with a simple_shape or an empty path, whereupon it just returns without doing anything unsigned int PrintEmf::print_pathv(Geom::PathVector const &pathv, const Geom::Affine &transform) { Geom::Affine tf = transform; char *rec = nullptr; simple_shape = print_simple_shape(pathv, tf); if (simple_shape || pathv.empty()) { if (use_fill) { destroy_brush(); // these must be cleared even if nothing is drawn or hbrush,hpen fill up } if (use_stroke) { destroy_pen(); } return TRUE; } (void) draw_pathv_to_EMF(pathv, tf); // explicit FILL/STROKE commands are needed for each sub section of the path if (use_fill && !use_stroke) { rec = U_EMRFILLPATH_set(U_RCL_DEF); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::fill at U_EMRFILLPATH_set"); } } else if (use_fill && use_stroke) { rec = U_EMRSTROKEANDFILLPATH_set(U_RCL_DEF); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::stroke at U_EMRSTROKEANDFILLPATH_set"); } } else if (!use_fill && use_stroke) { rec = U_EMRSTROKEPATH_set(U_RCL_DEF); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::stroke at U_EMRSTROKEPATH_set"); } } // clean out brush and pen, but only after all parts of the draw complete if (use_fill) { destroy_brush(); } if (use_stroke) { destroy_pen(); } return TRUE; } unsigned int PrintEmf::text(Inkscape::Extension::Print * /*mod*/, char const *text, Geom::Point const &p, SPStyle const *const style) { if (!et || !text) { return 0; } do_clip_if_present(style); // If clipping is needed set it up char *rec = nullptr; int ccount, newfont; int fix90n = 0; uint32_t hfont = 0; Geom::Affine tf = m_tr_stack.top(); double rot = -1800.0 * std::atan2(tf[1], tf[0]) / M_PI; // 0.1 degree rotation, - sign for MM_TEXT double rotb = -std::atan2(tf[1], tf[0]); // rotation for baseline offset for superscript/subscript, used below double dx, dy; double ky; // the dx array is smuggled in like: textw1 w2 w3 ...wn, where the widths are floats 7 characters wide, including the space int ndx, rtl; uint32_t *adx; smuggle_adxkyrtl_out(text, &adx, &ky, &rtl, &ndx, PX2WORLD * std::min(tf.expansionX(), tf.expansionY())); // side effect: free() adx uint32_t textalignment; if (rtl > 0) { textalignment = U_TA_BASELINE | U_TA_LEFT; } else { textalignment = U_TA_BASELINE | U_TA_RIGHT | U_TA_RTLREADING; } if (textalignment != htextalignment) { htextalignment = textalignment; rec = U_EMRSETTEXTALIGN_set(textalignment); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at U_EMRSETTEXTALIGN_set"); } } char *text2 = strdup(text); // because U_Utf8ToUtf16le calls iconv which does not like a const char * uint16_t *unicode_text = U_Utf8ToUtf16le(text2, 0, nullptr); free(text2); //translates Unicode to NonUnicode, if possible. If any translate, all will, and all to //the same font, because of code in Layout::print UnicodeToNon(unicode_text, &ccount, &newfont); //PPT gets funky with text within +-1 degree of a multiple of 90, but only for SOME fonts.Snap those to the central value //Some funky ones: Arial, Times New Roman //Some not funky ones: Symbol and Verdana. //Without a huge table we cannot catch them all, so just the most common problem ones. FontfixParams params; if (FixPPTCharPos) { switch (newfont) { case CVTSYM: _lookup_ppt_fontfix("Convert To Symbol", params); break; case CVTZDG: _lookup_ppt_fontfix("Convert To Zapf Dingbats", params); break; case CVTWDG: _lookup_ppt_fontfix("Convert To Wingdings", params); break; default: //also CVTNON _lookup_ppt_fontfix(style->font_family.value(), params); break; } if (params.f2 != 0 || params.f3 != 0) { int irem = ((int) round(rot)) % 900 ; if (irem <= 9 && irem >= -9) { fix90n = 1; //assume vertical rot = (double)(((int) round(rot)) - irem); rotb = rot * M_PI / 1800.0; if (std::abs(rot) == 900.0) { fix90n = 2; } } } } /* Note that text font sizes are stored into the EMF as fairly small integers and that limits their precision. The EMF output files produced here have been designed so that the integer valued pt sizes land right on an integer value in the EMF file, so those are exact. However, something like 18.1 pt will be somewhat off, so that when it is read back in it becomes 18.11 pt. (For instance.) */ int textheight = round(-style->font_size.computed * PX2WORLD * std::min(tf.expansionX(), tf.expansionY())); if (!hfont) { // Get font face name. Use changed font name if unicode mapped to one // of the special fonts. uint16_t *wfacename; if (!newfont) { wfacename = U_Utf8ToUtf16le(style->font_family.value(), 0, nullptr); } else { wfacename = U_Utf8ToUtf16le(FontName(newfont), 0, nullptr); } // Scale the text to the minimum stretch. (It tends to stay within bounding rectangles even if // it was streteched asymmetrically.) Few applications support text from EMF which is scaled // differently by height/width, so leave lfWidth alone. U_LOGFONT lf = logfont_set( textheight, 0, round(rot), round(rot), _translate_weight(style->font_weight.computed), (style->font_style.computed == SP_CSS_FONT_STYLE_ITALIC), style->text_decoration_line.underline, style->text_decoration_line.line_through, U_DEFAULT_CHARSET, U_OUT_DEFAULT_PRECIS, U_CLIP_DEFAULT_PRECIS, U_DEFAULT_QUALITY, U_DEFAULT_PITCH | U_FF_DONTCARE, wfacename); free(wfacename); rec = extcreatefontindirectw_set(&hfont, eht, (char *) &lf, nullptr); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at extcreatefontindirectw_set"); } } rec = selectobject_set(hfont, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at selectobject_set"); } float rgb[3]; style->fill.value.color.get_rgb_floatv(rgb); // only change the text color when it needs to be changed if (memcmp(htextcolor_rgb, rgb, 3 * sizeof(float))) { memcpy(htextcolor_rgb, rgb, 3 * sizeof(float)); rec = U_EMRSETTEXTCOLOR_set(U_RGB(255 * rgb[0], 255 * rgb[1], 255 * rgb[2])); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at U_EMRSETTEXTCOLOR_set"); } } Geom::Point p2 = p * tf; //Handle super/subscripts and vertical kerning /* Previously used this, but vertical kerning was not supported p2[Geom::X] -= style->baseline_shift.computed * std::sin( rotb ); p2[Geom::Y] -= style->baseline_shift.computed * std::cos( rotb ); */ p2[Geom::X] += ky * std::sin(rotb); p2[Geom::Y] += ky * std::cos(rotb); //Conditionally handle compensation for PPT EMF import bug (affects PPT 2003-2010, at least) if (FixPPTCharPos) { if (fix90n == 1) { //vertical dx = 0.0; dy = params.f3 * style->font_size.computed * std::cos(rotb); } else if (fix90n == 2) { //horizontal dx = params.f2 * style->font_size.computed * std::sin(rotb); dy = 0.0; } else { dx = params.f1 * style->font_size.computed * std::sin(rotb); dy = params.f1 * style->font_size.computed * std::cos(rotb); } p2[Geom::X] += dx; p2[Geom::Y] += dy; } p2[Geom::X] = (p2[Geom::X] * PX2WORLD); p2[Geom::Y] = (p2[Geom::Y] * PX2WORLD); int32_t const xpos = (int32_t) round(p2[Geom::X]); int32_t const ypos = (int32_t) round(p2[Geom::Y]); // The number of characters in the string is a bit fuzzy. ndx, the number of entries in adx is // the number of VISIBLE characters, since some may combine from the UTF (8 originally, // now 16) encoding. Conversely strlen() or wchar16len() would give the absolute number of // encoding characters. Unclear if emrtext wants the former or the latter but for now assume the former. // This is currently being smuggled in from caller as part of text, works // MUCH better than the fallback hack below // uint32_t *adx = dx_set(textheight, U_FW_NORMAL, slen); // dx is needed, this makes one up char *rec2; if (rtl > 0) { rec2 = emrtext_set((U_POINTL) { xpos, ypos }, ndx, 2, unicode_text, U_ETO_NONE, U_RCL_DEF, adx); } else { // RTL text, U_TA_RTLREADING should be enough, but set this one too just in case rec2 = emrtext_set((U_POINTL) { xpos, ypos }, ndx, 2, unicode_text, U_ETO_RTLREADING, U_RCL_DEF, adx); } free(unicode_text); free(adx); rec = U_EMREXTTEXTOUTW_set(U_RCL_DEF, U_GM_COMPATIBLE, 1.0, 1.0, (PU_EMRTEXT)rec2); free(rec2); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at U_EMREXTTEXTOUTW_set"); } // Must deselect an object before deleting it. Put the default font (back) in. rec = selectobject_set(U_DEVICE_DEFAULT_FONT, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at selectobject_set"); } if (hfont) { rec = deleteobject_set(&hfont, eht); if (!rec || emf_append((PU_ENHMETARECORD)rec, et, U_REC_FREE)) { g_error("Fatal programming error in PrintEmf::text at deleteobject_set"); } } return 0; } void PrintEmf::init() { /* EMF print */ // clang-format off Inkscape::Extension::build_from_mem( "\n" "Enhanced Metafile Print\n" "org.inkscape.print.emf\n" "\n" "true\n" "true\n" "false\n" "false\n" "false\n" "false\n" "false\n" "false\n" "\n" "", new PrintEmf()); // clang-format on return; } } /* namespace Internal */ } /* namespace Extension */ } /* namespace Inkscape */ /* Local Variables: mode:c++ c-file-style:"stroustrup" c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +)) indent-tabs-mode:nil fill-column:99 End: */ // vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:fileencoding=utf-8:textwidth=99 :