/* * Copyright (C) 2006 Apple Computer, Inc. All rights reserved. * Copyright (C) 2007 Alp Toker * Copyright (C) 2008 Dirk Schulze * Copyright (C) 2008 Nuanti Ltd. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY APPLE COMPUTER, INC. ``AS IS'' AND ANY * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE COMPUTER, INC. OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "config.h" #include "GraphicsContext.h" #if PLATFORM(CAIRO) #include "TransformationMatrix.h" #include "CairoPath.h" #include "FloatRect.h" #include "Font.h" #include "ImageBuffer.h" #include "IntRect.h" #include "NotImplemented.h" #include "Path.h" #include "Pattern.h" #include "SimpleFontData.h" #include #include #include #include #if PLATFORM(GTK) #include #include #elif PLATFORM(WIN) #include #endif #include "GraphicsContextPrivate.h" #include "GraphicsContextPlatformPrivateCairo.h" #ifndef M_PI #define M_PI 3.14159265358979323846 #endif namespace WebCore { static inline void setColor(cairo_t* cr, const Color& col) { float red, green, blue, alpha; col.getRGBA(red, green, blue, alpha); cairo_set_source_rgba(cr, red, green, blue, alpha); } // A fillRect helper static inline void fillRectSourceOver(cairo_t* cr, const FloatRect& rect, const Color& col) { setColor(cr, col); cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height()); cairo_set_operator(cr, CAIRO_OPERATOR_OVER); cairo_fill(cr); } GraphicsContext::GraphicsContext(PlatformGraphicsContext* cr) : m_common(createGraphicsContextPrivate()) , m_data(new GraphicsContextPlatformPrivate) { m_data->cr = cairo_reference(cr); m_data->syncContext(cr); setPaintingDisabled(!cr); } GraphicsContext::~GraphicsContext() { destroyGraphicsContextPrivate(m_common); delete m_data; } TransformationMatrix GraphicsContext::getCTM() const { cairo_t* cr = platformContext(); cairo_matrix_t m; cairo_get_matrix(cr, &m); return TransformationMatrix(m.xx, m.yx, m.xy, m.yy, m.x0, m.y0); } cairo_t* GraphicsContext::platformContext() const { return m_data->cr; } void GraphicsContext::savePlatformState() { cairo_save(m_data->cr); m_data->save(); } void GraphicsContext::restorePlatformState() { cairo_restore(m_data->cr); m_data->restore(); } // Draws a filled rectangle with a stroked border. void GraphicsContext::drawRect(const IntRect& rect) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); if (fillColor().alpha()) fillRectSourceOver(cr, rect, fillColor()); if (strokeStyle() != NoStroke) { setColor(cr, strokeColor()); FloatRect r(rect); r.inflate(-.5f); cairo_rectangle(cr, r.x(), r.y(), r.width(), r.height()); cairo_set_line_width(cr, 1.0); cairo_stroke(cr); } cairo_restore(cr); } // FIXME: Now that this is refactored, it should be shared by all contexts. static void adjustLineToPixelBoundaries(FloatPoint& p1, FloatPoint& p2, float strokeWidth, StrokeStyle style) { // For odd widths, we add in 0.5 to the appropriate x/y so that the float arithmetic // works out. For example, with a border width of 3, KHTML will pass us (y1+y2)/2, e.g., // (50+53)/2 = 103/2 = 51 when we want 51.5. It is always true that an even width gave // us a perfect position, but an odd width gave us a position that is off by exactly 0.5. if (style == DottedStroke || style == DashedStroke) { if (p1.x() == p2.x()) { p1.setY(p1.y() + strokeWidth); p2.setY(p2.y() - strokeWidth); } else { p1.setX(p1.x() + strokeWidth); p2.setX(p2.x() - strokeWidth); } } if (static_cast(strokeWidth) % 2) { if (p1.x() == p2.x()) { // We're a vertical line. Adjust our x. p1.setX(p1.x() + 0.5); p2.setX(p2.x() + 0.5); } else { // We're a horizontal line. Adjust our y. p1.setY(p1.y() + 0.5); p2.setY(p2.y() + 0.5); } } } // This is only used to draw borders. void GraphicsContext::drawLine(const IntPoint& point1, const IntPoint& point2) { if (paintingDisabled()) return; StrokeStyle style = strokeStyle(); if (style == NoStroke) return; cairo_t* cr = m_data->cr; cairo_save(cr); float width = strokeThickness(); if (width < 1) width = 1; FloatPoint p1 = point1; FloatPoint p2 = point2; bool isVerticalLine = (p1.x() == p2.x()); adjustLineToPixelBoundaries(p1, p2, width, style); cairo_set_line_width(cr, width); int patWidth = 0; switch (style) { case NoStroke: case SolidStroke: break; case DottedStroke: patWidth = static_cast(width); break; case DashedStroke: patWidth = 3*static_cast(width); break; } setColor(cr, strokeColor()); cairo_set_antialias(cr, CAIRO_ANTIALIAS_NONE); if (patWidth) { // Do a rect fill of our endpoints. This ensures we always have the // appearance of being a border. We then draw the actual dotted/dashed line. if (isVerticalLine) { fillRectSourceOver(cr, FloatRect(p1.x() - width/2, p1.y() - width, width, width), strokeColor()); fillRectSourceOver(cr, FloatRect(p2.x() - width/2, p2.y(), width, width), strokeColor()); } else { fillRectSourceOver(cr, FloatRect(p1.x() - width, p1.y() - width/2, width, width), strokeColor()); fillRectSourceOver(cr, FloatRect(p2.x(), p2.y() - width/2, width, width), strokeColor()); } // Example: 80 pixels with a width of 30 pixels. // Remainder is 20. The maximum pixels of line we could paint // will be 50 pixels. int distance = (isVerticalLine ? (point2.y() - point1.y()) : (point2.x() - point1.x())) - 2*static_cast(width); int remainder = distance%patWidth; int coverage = distance-remainder; int numSegments = coverage/patWidth; float patternOffset = 0; // Special case 1px dotted borders for speed. if (patWidth == 1) patternOffset = 1.0; else { bool evenNumberOfSegments = numSegments%2 == 0; if (remainder) evenNumberOfSegments = !evenNumberOfSegments; if (evenNumberOfSegments) { if (remainder) { patternOffset += patWidth - remainder; patternOffset += remainder/2; } else patternOffset = patWidth/2; } else if (!evenNumberOfSegments) { if (remainder) patternOffset = (patWidth - remainder)/2; } } double dash = patWidth; cairo_set_dash(cr, &dash, 1, patternOffset); } cairo_move_to(cr, p1.x(), p1.y()); cairo_line_to(cr, p2.x(), p2.y()); cairo_stroke(cr); cairo_restore(cr); } // This method is only used to draw the little circles used in lists. void GraphicsContext::drawEllipse(const IntRect& rect) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); float yRadius = .5 * rect.height(); float xRadius = .5 * rect.width(); cairo_translate(cr, rect.x() + xRadius, rect.y() + yRadius); cairo_scale(cr, xRadius, yRadius); cairo_arc(cr, 0., 0., 1., 0., 2 * M_PI); cairo_restore(cr); if (fillColor().alpha()) { setColor(cr, fillColor()); cairo_fill_preserve(cr); } if (strokeStyle() != NoStroke) { setColor(cr, strokeColor()); cairo_set_line_width(cr, strokeThickness()); cairo_stroke(cr); } cairo_new_path(cr); } void GraphicsContext::strokeArc(const IntRect& rect, int startAngle, int angleSpan) { if (paintingDisabled() || strokeStyle() == NoStroke) return; int x = rect.x(); int y = rect.y(); float w = rect.width(); float h = rect.height(); float scaleFactor = h / w; float reverseScaleFactor = w / h; float hRadius = w / 2; float vRadius = h / 2; float fa = startAngle; float falen = fa + angleSpan; cairo_t* cr = m_data->cr; cairo_save(cr); if (w != h) cairo_scale(cr, 1., scaleFactor); cairo_arc_negative(cr, x + hRadius, (y + vRadius) * reverseScaleFactor, hRadius, -fa * M_PI/180, -falen * M_PI/180); if (w != h) cairo_scale(cr, 1., reverseScaleFactor); float width = strokeThickness(); int patWidth = 0; switch (strokeStyle()) { case DottedStroke: patWidth = static_cast(width / 2); break; case DashedStroke: patWidth = 3 * static_cast(width / 2); break; default: break; } setColor(cr, strokeColor()); if (patWidth) { // Example: 80 pixels with a width of 30 pixels. // Remainder is 20. The maximum pixels of line we could paint // will be 50 pixels. int distance; if (hRadius == vRadius) distance = static_cast((M_PI * hRadius) / 2.0); else // We are elliptical and will have to estimate the distance distance = static_cast((M_PI * sqrtf((hRadius * hRadius + vRadius * vRadius) / 2.0)) / 2.0); int remainder = distance % patWidth; int coverage = distance - remainder; int numSegments = coverage / patWidth; float patternOffset = 0.0; // Special case 1px dotted borders for speed. if (patWidth == 1) patternOffset = 1.0; else { bool evenNumberOfSegments = numSegments % 2 == 0; if (remainder) evenNumberOfSegments = !evenNumberOfSegments; if (evenNumberOfSegments) { if (remainder) { patternOffset += patWidth - remainder; patternOffset += remainder / 2.0; } else patternOffset = patWidth / 2.0; } else { if (remainder) patternOffset = (patWidth - remainder) / 2.0; } } double dash = patWidth; cairo_set_dash(cr, &dash, 1, patternOffset); } cairo_stroke(cr); cairo_restore(cr); } void GraphicsContext::drawConvexPolygon(size_t npoints, const FloatPoint* points, bool shouldAntialias) { if (paintingDisabled()) return; if (npoints <= 1) return; cairo_t* cr = m_data->cr; cairo_save(cr); cairo_set_antialias(cr, shouldAntialias ? CAIRO_ANTIALIAS_DEFAULT : CAIRO_ANTIALIAS_NONE); cairo_move_to(cr, points[0].x(), points[0].y()); for (size_t i = 1; i < npoints; i++) cairo_line_to(cr, points[i].x(), points[i].y()); cairo_close_path(cr); if (fillColor().alpha()) { setColor(cr, fillColor()); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_EVEN_ODD); cairo_fill_preserve(cr); } if (strokeStyle() != NoStroke) { setColor(cr, strokeColor()); cairo_set_line_width(cr, strokeThickness()); cairo_stroke(cr); } cairo_new_path(cr); cairo_restore(cr); } void GraphicsContext::fillPath() { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); cairo_set_fill_rule(cr, fillRule() == RULE_EVENODD ? CAIRO_FILL_RULE_EVEN_ODD : CAIRO_FILL_RULE_WINDING); switch (m_common->state.fillColorSpace) { case SolidColorSpace: setColor(cr, fillColor()); cairo_clip(cr); cairo_paint_with_alpha(cr, m_common->state.globalAlpha); break; case PatternColorSpace: { TransformationMatrix affine; cairo_set_source(cr, m_common->state.fillPattern->createPlatformPattern(affine)); cairo_clip(cr); cairo_paint_with_alpha(cr, m_common->state.globalAlpha); break; } case GradientColorSpace: cairo_pattern_t* pattern = m_common->state.fillGradient->platformGradient(); cairo_set_source(cr, pattern); cairo_clip(cr); cairo_paint_with_alpha(cr, m_common->state.globalAlpha); break; } cairo_restore(cr); } void GraphicsContext::strokePath() { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); switch (m_common->state.strokeColorSpace) { case SolidColorSpace: float red, green, blue, alpha; strokeColor().getRGBA(red, green, blue, alpha); if (m_common->state.globalAlpha < 1.0f) alpha *= m_common->state.globalAlpha; cairo_set_source_rgba(cr, red, green, blue, alpha); cairo_stroke(cr); break; case PatternColorSpace: { TransformationMatrix affine; cairo_set_source(cr, m_common->state.strokePattern->createPlatformPattern(affine)); if (m_common->state.globalAlpha < 1.0f) { cairo_push_group(cr); cairo_paint_with_alpha(cr, m_common->state.globalAlpha); cairo_pop_group_to_source(cr); } cairo_stroke(cr); break; } case GradientColorSpace: cairo_pattern_t* pattern = m_common->state.strokeGradient->platformGradient(); cairo_set_source(cr, pattern); if (m_common->state.globalAlpha < 1.0f) { cairo_push_group(cr); cairo_paint_with_alpha(cr, m_common->state.globalAlpha); cairo_pop_group_to_source(cr); } cairo_stroke(cr); break; } cairo_restore(cr); } void GraphicsContext::drawPath() { fillPath(); strokePath(); } void GraphicsContext::fillRect(const FloatRect& rect) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height()); fillPath(); } void GraphicsContext::fillRect(const FloatRect& rect, const Color& color) { if (paintingDisabled()) return; if (color.alpha()) fillRectSourceOver(m_data->cr, rect, color); } void GraphicsContext::clip(const FloatRect& rect) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height()); cairo_fill_rule_t savedFillRule = cairo_get_fill_rule(cr); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_WINDING); cairo_clip(cr); cairo_set_fill_rule(cr, savedFillRule); m_data->clip(rect); } void GraphicsContext::clipPath(WindRule clipRule) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_set_fill_rule(cr, clipRule == RULE_EVENODD ? CAIRO_FILL_RULE_EVEN_ODD : CAIRO_FILL_RULE_WINDING); cairo_clip(cr); } void GraphicsContext::drawFocusRing(const Color& color) { if (paintingDisabled()) return; const Vector& rects = focusRingRects(); unsigned rectCount = rects.size(); cairo_t* cr = m_data->cr; cairo_save(cr); cairo_push_group(cr); cairo_new_path(cr); #if PLATFORM(GTK) GdkRegion* reg = gdk_region_new(); for (unsigned i = 0; i < rectCount; i++) { GdkRectangle rect = rects[i]; gdk_region_union_with_rect(reg, &rect); } gdk_cairo_region(cr, reg); gdk_region_destroy(reg); setColor(cr, color); cairo_set_line_width(cr, 2.0f); setPlatformStrokeStyle(DottedStroke); #else int radius = (focusRingWidth() - 1) / 2; for (unsigned i = 0; i < rectCount; i++) addPath(Path::createRoundedRectangle(rects[i], FloatSize(radius, radius))); // Force the alpha to 50%. This matches what the Mac does with outline rings. Color ringColor(color.red(), color.green(), color.blue(), 127); setColor(cr, ringColor); cairo_set_line_width(cr, focusRingWidth()); setPlatformStrokeStyle(SolidStroke); #endif cairo_set_operator(cr, CAIRO_OPERATOR_OVER); cairo_stroke_preserve(cr); cairo_set_operator(cr, CAIRO_OPERATOR_CLEAR); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_WINDING); cairo_fill(cr); cairo_pop_group_to_source(cr); cairo_set_operator(cr, CAIRO_OPERATOR_OVER); cairo_paint(cr); cairo_restore(cr); } void GraphicsContext::drawLineForText(const IntPoint& origin, int width, bool printing) { if (paintingDisabled()) return; // This is a workaround for http://bugs.webkit.org/show_bug.cgi?id=15659 StrokeStyle savedStrokeStyle = strokeStyle(); setStrokeStyle(SolidStroke); IntPoint endPoint = origin + IntSize(width, 0); drawLine(origin, endPoint); setStrokeStyle(savedStrokeStyle); } void GraphicsContext::drawLineForMisspellingOrBadGrammar(const IntPoint& origin, int width, bool grammar) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); // Convention is green for grammar, red for spelling // These need to become configurable if (grammar) cairo_set_source_rgb(cr, 0, 1, 0); else cairo_set_source_rgb(cr, 1, 0, 0); #if PLATFORM(GTK) // We ignore most of the provided constants in favour of the platform style pango_cairo_show_error_underline(cr, origin.x(), origin.y(), width, cMisspellingLineThickness); #else notImplemented(); #endif cairo_restore(cr); } FloatRect GraphicsContext::roundToDevicePixels(const FloatRect& frect) { FloatRect result; double x = frect.x(); double y = frect.y(); cairo_t* cr = m_data->cr; cairo_user_to_device(cr, &x, &y); x = round(x); y = round(y); cairo_device_to_user(cr, &x, &y); result.setX(static_cast(x)); result.setY(static_cast(y)); x = frect.width(); y = frect.height(); cairo_user_to_device_distance(cr, &x, &y); x = round(x); y = round(y); cairo_device_to_user_distance(cr, &x, &y); result.setWidth(static_cast(x)); result.setHeight(static_cast(y)); return result; } void GraphicsContext::translate(float x, float y) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_translate(cr, x, y); m_data->translate(x, y); } IntPoint GraphicsContext::origin() { cairo_matrix_t matrix; cairo_t* cr = m_data->cr; cairo_get_matrix(cr, &matrix); return IntPoint(static_cast(matrix.x0), static_cast(matrix.y0)); } void GraphicsContext::setPlatformFillColor(const Color& col) { // Cairo contexts can't hold separate fill and stroke colors // so we set them just before we actually fill or stroke } void GraphicsContext::setPlatformStrokeColor(const Color& col) { // Cairo contexts can't hold separate fill and stroke colors // so we set them just before we actually fill or stroke } void GraphicsContext::setPlatformStrokeThickness(float strokeThickness) { if (paintingDisabled()) return; cairo_set_line_width(m_data->cr, strokeThickness); } void GraphicsContext::setPlatformStrokeStyle(const StrokeStyle& strokeStyle) { static double dashPattern[] = {5.0, 5.0}; static double dotPattern[] = {1.0, 1.0}; if (paintingDisabled()) return; switch (strokeStyle) { case NoStroke: // FIXME: is it the right way to emulate NoStroke? cairo_set_line_width(m_data->cr, 0); break; case SolidStroke: cairo_set_dash(m_data->cr, 0, 0, 0); break; case DottedStroke: cairo_set_dash(m_data->cr, dotPattern, 2, 0); break; case DashedStroke: cairo_set_dash(m_data->cr, dashPattern, 2, 0); break; } } void GraphicsContext::setURLForRect(const KURL& link, const IntRect& destRect) { notImplemented(); } void GraphicsContext::concatCTM(const TransformationMatrix& transform) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; const cairo_matrix_t matrix = cairo_matrix_t(transform); cairo_transform(cr, &matrix); m_data->concatCTM(transform); } void GraphicsContext::addInnerRoundedRectClip(const IntRect& rect, int thickness) { if (paintingDisabled()) return; clip(rect); Path p; FloatRect r(rect); // Add outer ellipse p.addEllipse(r); // Add inner ellipse r.inflate(-thickness); p.addEllipse(r); addPath(p); cairo_t* cr = m_data->cr; cairo_fill_rule_t savedFillRule = cairo_get_fill_rule(cr); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_EVEN_ODD); cairo_clip(cr); cairo_set_fill_rule(cr, savedFillRule); } void GraphicsContext::clipToImageBuffer(const FloatRect& rect, const ImageBuffer* imageBuffer) { if (paintingDisabled()) return; notImplemented(); } void GraphicsContext::setPlatformShadow(IntSize const&, int, Color const&) { notImplemented(); } void GraphicsContext::clearPlatformShadow() { notImplemented(); } void GraphicsContext::beginTransparencyLayer(float opacity) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_push_group(cr); m_data->layers.append(opacity); m_data->beginTransparencyLayer(); } void GraphicsContext::endTransparencyLayer() { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_pop_group_to_source(cr); cairo_paint_with_alpha(cr, m_data->layers.last()); m_data->layers.removeLast(); m_data->endTransparencyLayer(); } void GraphicsContext::clearRect(const FloatRect& rect) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height()); cairo_set_operator(cr, CAIRO_OPERATOR_CLEAR); cairo_fill(cr); cairo_restore(cr); } void GraphicsContext::strokeRect(const FloatRect& rect, float width) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); cairo_rectangle(cr, rect.x(), rect.y(), rect.width(), rect.height()); cairo_set_line_width(cr, width); strokePath(); cairo_restore(cr); } void GraphicsContext::setLineCap(LineCap lineCap) { if (paintingDisabled()) return; cairo_line_cap_t cairoCap = CAIRO_LINE_CAP_BUTT; switch (lineCap) { case ButtCap: // no-op break; case RoundCap: cairoCap = CAIRO_LINE_CAP_ROUND; break; case SquareCap: cairoCap = CAIRO_LINE_CAP_SQUARE; break; } cairo_set_line_cap(m_data->cr, cairoCap); } void GraphicsContext::setLineDash(const DashArray& dashes, float dashOffset) { cairo_set_dash(m_data->cr, dashes.data(), dashes.size(), dashOffset); } void GraphicsContext::setLineJoin(LineJoin lineJoin) { if (paintingDisabled()) return; cairo_line_join_t cairoJoin = CAIRO_LINE_JOIN_MITER; switch (lineJoin) { case MiterJoin: // no-op break; case RoundJoin: cairoJoin = CAIRO_LINE_JOIN_ROUND; break; case BevelJoin: cairoJoin = CAIRO_LINE_JOIN_BEVEL; break; } cairo_set_line_join(m_data->cr, cairoJoin); } void GraphicsContext::setMiterLimit(float miter) { if (paintingDisabled()) return; cairo_set_miter_limit(m_data->cr, miter); } void GraphicsContext::setAlpha(float alpha) { m_common->state.globalAlpha = alpha; } float GraphicsContext::getAlpha() { return m_common->state.globalAlpha; } static inline cairo_operator_t toCairoOperator(CompositeOperator op) { switch (op) { case CompositeClear: return CAIRO_OPERATOR_CLEAR; case CompositeCopy: return CAIRO_OPERATOR_SOURCE; case CompositeSourceOver: return CAIRO_OPERATOR_OVER; case CompositeSourceIn: return CAIRO_OPERATOR_IN; case CompositeSourceOut: return CAIRO_OPERATOR_OUT; case CompositeSourceAtop: return CAIRO_OPERATOR_ATOP; case CompositeDestinationOver: return CAIRO_OPERATOR_DEST_OVER; case CompositeDestinationIn: return CAIRO_OPERATOR_DEST_IN; case CompositeDestinationOut: return CAIRO_OPERATOR_DEST_OUT; case CompositeDestinationAtop: return CAIRO_OPERATOR_DEST_ATOP; case CompositeXOR: return CAIRO_OPERATOR_XOR; case CompositePlusDarker: return CAIRO_OPERATOR_SATURATE; case CompositeHighlight: // There is no Cairo equivalent for CompositeHighlight. return CAIRO_OPERATOR_OVER; case CompositePlusLighter: return CAIRO_OPERATOR_ADD; default: return CAIRO_OPERATOR_SOURCE; } } void GraphicsContext::setCompositeOperation(CompositeOperator op) { if (paintingDisabled()) return; cairo_set_operator(m_data->cr, toCairoOperator(op)); } void GraphicsContext::beginPath() { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_new_path(cr); } void GraphicsContext::addPath(const Path& path) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_path_t* p = cairo_copy_path(path.platformPath()->m_cr); cairo_append_path(cr, p); cairo_path_destroy(p); } void GraphicsContext::clip(const Path& path) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_path_t* p = cairo_copy_path(path.platformPath()->m_cr); cairo_append_path(cr, p); cairo_path_destroy(p); cairo_fill_rule_t savedFillRule = cairo_get_fill_rule(cr); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_WINDING); cairo_clip(cr); cairo_set_fill_rule(cr, savedFillRule); m_data->clip(path); } void GraphicsContext::clipOut(const Path& path) { if (paintingDisabled()) return; #if CAIRO_VERSION >= CAIRO_VERSION_ENCODE(1,4,0) cairo_t* cr = m_data->cr; double x1, y1, x2, y2; cairo_clip_extents(cr, &x1, &y1, &x2, &y2); cairo_rectangle(cr, x1, y1, x2 - x1, y2 - y1); addPath(path); cairo_fill_rule_t savedFillRule = cairo_get_fill_rule(cr); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_EVEN_ODD); cairo_clip(cr); cairo_set_fill_rule(cr, savedFillRule); #else notImplemented(); #endif } void GraphicsContext::rotate(float radians) { if (paintingDisabled()) return; cairo_rotate(m_data->cr, radians); m_data->rotate(radians); } void GraphicsContext::scale(const FloatSize& size) { if (paintingDisabled()) return; cairo_scale(m_data->cr, size.width(), size.height()); m_data->scale(size); } void GraphicsContext::clipOut(const IntRect& r) { if (paintingDisabled()) return; #if CAIRO_VERSION >= CAIRO_VERSION_ENCODE(1,4,0) cairo_t* cr = m_data->cr; double x1, y1, x2, y2; cairo_clip_extents(cr, &x1, &y1, &x2, &y2); cairo_rectangle(cr, x1, x2, x2 - x1, y2 - y1); cairo_rectangle(cr, r.x(), r.y(), r.width(), r.height()); cairo_fill_rule_t savedFillRule = cairo_get_fill_rule(cr); cairo_set_fill_rule(cr, CAIRO_FILL_RULE_EVEN_ODD); cairo_clip(cr); cairo_set_fill_rule(cr, savedFillRule); #else notImplemented(); #endif } void GraphicsContext::clipOutEllipseInRect(const IntRect& r) { if (paintingDisabled()) return; Path p; p.addEllipse(r); clipOut(p); } void GraphicsContext::fillRoundedRect(const IntRect& r, const IntSize& topLeft, const IntSize& topRight, const IntSize& bottomLeft, const IntSize& bottomRight, const Color& color) { if (paintingDisabled()) return; cairo_t* cr = m_data->cr; cairo_save(cr); beginPath(); addPath(Path::createRoundedRectangle(r, topLeft, topRight, bottomLeft, bottomRight)); setColor(cr, color); cairo_fill(cr); cairo_restore(cr); } #if PLATFORM(GTK) void GraphicsContext::setGdkExposeEvent(GdkEventExpose* expose) { m_data->expose = expose; } GdkEventExpose* GraphicsContext::gdkExposeEvent() const { return m_data->expose; } GdkDrawable* GraphicsContext::gdkDrawable() const { if (!m_data->expose) return 0; return GDK_DRAWABLE(m_data->expose->window); } #endif void GraphicsContext::setPlatformShouldAntialias(bool enable) { if (paintingDisabled()) return; // When true, use the default Cairo backend antialias mode (usually this // enables standard 'grayscale' antialiasing); false to explicitly disable // antialiasing. This is the same strategy as used in drawConvexPolygon(). cairo_set_antialias(m_data->cr, enable ? CAIRO_ANTIALIAS_DEFAULT : CAIRO_ANTIALIAS_NONE); } void GraphicsContext::setImageInterpolationQuality(InterpolationQuality) { } InterpolationQuality GraphicsContext::imageInterpolationQuality() const { return InterpolationDefault; } } // namespace WebCore #endif // PLATFORM(CAIRO)