/* * This file is part of the WebKit project. * * Copyright (C) 2007 Nikolas Zimmermann * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, * Boston, MA 02110-1301, USA. * */ #include "config.h" #if ENABLE(SVG) #include "SVGCharacterLayoutInfo.h" #include "InlineFlowBox.h" #include "InlineTextBox.h" #include "SVGLengthList.h" #include "SVGNumberList.h" #include "SVGTextPositioningElement.h" #include "RenderSVGTextPath.h" #include namespace WebCore { // Helper function static float calculateBaselineShift(RenderObject* item) { const Font& font = item->style()->font(); const SVGRenderStyle* svgStyle = item->style()->svgStyle(); float baselineShift = 0.0f; if (svgStyle->baselineShift() == BS_LENGTH) { CSSPrimitiveValue* primitive = static_cast(svgStyle->baselineShiftValue()); baselineShift = primitive->getFloatValue(); if (primitive->primitiveType() == CSSPrimitiveValue::CSS_PERCENTAGE) baselineShift = baselineShift / 100.0f * font.pixelSize(); } else { float baselineAscent = font.ascent() + font.descent(); switch (svgStyle->baselineShift()) { case BS_BASELINE: break; case BS_SUB: baselineShift = -baselineAscent / 2.0f; break; case BS_SUPER: baselineShift = baselineAscent / 2.0f; break; default: ASSERT_NOT_REACHED(); } } return baselineShift; } SVGCharacterLayoutInfo::SVGCharacterLayoutInfo(Vector& chars) : curx(0.0f) , cury(0.0f) , angle(0.0f) , dx(0.0f) , dy(0.0f) , shiftx(0.0f) , shifty(0.0f) , pathExtraAdvance(0.0f) , pathTextLength(0.0f) , pathChunkLength(0.0f) , svgChars(chars) , nextDrawnSeperated(false) , xStackChanged(false) , yStackChanged(false) , dxStackChanged(false) , dyStackChanged(false) , angleStackChanged(false) , baselineShiftStackChanged(false) , pathLayout(false) , currentOffset(0.0f) , startOffset(0.0f) , layoutPathLength(0.0f) { } bool SVGCharacterLayoutInfo::xValueAvailable() const { return xStack.isEmpty() ? false : xStack.last().position() < xStack.last().size(); } bool SVGCharacterLayoutInfo::yValueAvailable() const { return yStack.isEmpty() ? false : yStack.last().position() < yStack.last().size(); } bool SVGCharacterLayoutInfo::dxValueAvailable() const { return dxStack.isEmpty() ? false : dxStack.last().position() < dxStack.last().size(); } bool SVGCharacterLayoutInfo::dyValueAvailable() const { return dyStack.isEmpty() ? false : dyStack.last().position() < dyStack.last().size(); } bool SVGCharacterLayoutInfo::angleValueAvailable() const { return angleStack.isEmpty() ? false : angleStack.last().position() < angleStack.last().size(); } bool SVGCharacterLayoutInfo::baselineShiftValueAvailable() const { return !baselineShiftStack.isEmpty(); } float SVGCharacterLayoutInfo::xValueNext() const { ASSERT(!xStack.isEmpty()); return xStack.last().valueAtCurrentPosition(); } float SVGCharacterLayoutInfo::yValueNext() const { ASSERT(!yStack.isEmpty()); return yStack.last().valueAtCurrentPosition(); } float SVGCharacterLayoutInfo::dxValueNext() const { ASSERT(!dxStack.isEmpty()); return dxStack.last().valueAtCurrentPosition(); } float SVGCharacterLayoutInfo::dyValueNext() const { ASSERT(!dyStack.isEmpty()); return dyStack.last().valueAtCurrentPosition(); } float SVGCharacterLayoutInfo::angleValueNext() const { ASSERT(!angleStack.isEmpty()); return angleStack.last().valueAtCurrentPosition(); } float SVGCharacterLayoutInfo::baselineShiftValueNext() const { ASSERT(!baselineShiftStack.isEmpty()); return baselineShiftStack.last(); } void SVGCharacterLayoutInfo::processedSingleCharacter() { xStackWalk(); yStackWalk(); dxStackWalk(); dyStackWalk(); angleStackWalk(); baselineShiftStackWalk(); } void SVGCharacterLayoutInfo::processedChunk(float savedShiftX, float savedShiftY) { // baseline-shift doesn't span across ancestors, unlike dx/dy. curx += savedShiftX - shiftx; cury += savedShiftY - shifty; if (inPathLayout()) { shiftx = savedShiftX; shifty = savedShiftY; } // rotation also doesn't span angle = 0.0f; if (xStackChanged) { ASSERT(!xStack.isEmpty()); xStack.removeLast(); xStackChanged = false; } if (yStackChanged) { ASSERT(!yStack.isEmpty()); yStack.removeLast(); yStackChanged = false; } if (dxStackChanged) { ASSERT(!dxStack.isEmpty()); dxStack.removeLast(); dxStackChanged = false; } if (dyStackChanged) { ASSERT(!dyStack.isEmpty()); dyStack.removeLast(); dyStackChanged = false; } if (angleStackChanged) { ASSERT(!angleStack.isEmpty()); angleStack.removeLast(); angleStackChanged = false; } if (baselineShiftStackChanged) { ASSERT(!baselineShiftStack.isEmpty()); baselineShiftStack.removeLast(); baselineShiftStackChanged = false; } } bool SVGCharacterLayoutInfo::nextPathLayoutPointAndAngle(float glyphAdvance, float extraAdvance, float newOffset) { if (layoutPathLength <= 0.0f) return false; if (newOffset != FLT_MIN) currentOffset = startOffset + newOffset; // Respect translation along path (extraAdvance is orthogonal to the path) currentOffset += extraAdvance; float offset = currentOffset + glyphAdvance / 2.0f; currentOffset += glyphAdvance + pathExtraAdvance; if (offset < 0.0f || offset > layoutPathLength) return false; bool ok = false; FloatPoint point = layoutPath.pointAtLength(offset, ok); ASSERT(ok); curx = point.x(); cury = point.y(); angle = layoutPath.normalAngleAtLength(offset, ok); ASSERT(ok); // fprintf(stderr, "t: %f, x: %f, y: %f, angle: %f, glyphAdvance: %f\n", currentOffset, x, y, angle, glyphAdvance); return true; } bool SVGCharacterLayoutInfo::inPathLayout() const { return pathLayout; } void SVGCharacterLayoutInfo::setInPathLayout(bool value) { pathLayout = value; pathExtraAdvance = 0.0f; pathTextLength = 0.0f; pathChunkLength = 0.0f; } void SVGCharacterLayoutInfo::addLayoutInformation(InlineFlowBox* flowBox, float textAnchorStartOffset) { bool isInitialLayout = xStack.isEmpty() && yStack.isEmpty() && dxStack.isEmpty() && dyStack.isEmpty() && angleStack.isEmpty() && baselineShiftStack.isEmpty() && curx == 0.0f && cury == 0.0f; RenderSVGTextPath* textPath = static_cast(flowBox->object()); Path path = textPath->layoutPath(); float baselineShift = calculateBaselineShift(textPath); layoutPath = path; layoutPathLength = path.length(); if (layoutPathLength <= 0.0f) return; startOffset = textPath->startOffset(); if (textPath->startOffset() >= 0.0f && textPath->startOffset() <= 1.0f) startOffset *= layoutPathLength; startOffset += textAnchorStartOffset; currentOffset = startOffset; // Only baseline-shift is handled through the normal layout system addStackContent(BaselineShiftStack, baselineShift); if (isInitialLayout) { xStackChanged = false; yStackChanged = false; dxStackChanged = false; dyStackChanged = false; angleStackChanged = false; baselineShiftStackChanged = false; } } void SVGCharacterLayoutInfo::addLayoutInformation(SVGTextPositioningElement* element) { bool isInitialLayout = xStack.isEmpty() && yStack.isEmpty() && dxStack.isEmpty() && dyStack.isEmpty() && angleStack.isEmpty() && baselineShiftStack.isEmpty() && curx == 0.0f && cury == 0.0f; float baselineShift = calculateBaselineShift(element->renderer()); addStackContent(XStack, element->x()); addStackContent(YStack, element->y()); addStackContent(DxStack, element->dx()); addStackContent(DyStack, element->dy()); addStackContent(AngleStack, element->rotate()); addStackContent(BaselineShiftStack, baselineShift); if (isInitialLayout) { xStackChanged = false; yStackChanged = false; dxStackChanged = false; dyStackChanged = false; angleStackChanged = false; baselineShiftStackChanged = false; } } void SVGCharacterLayoutInfo::addStackContent(StackType type, SVGNumberList* list) { unsigned length = list->numberOfItems(); if (!length) return; PositionedFloatVector newLayoutInfo; // TODO: Convert more efficiently! ExceptionCode ec = 0; for (unsigned i = 0; i < length; ++i) { float value = list->getItem(i, ec); ASSERT(ec == 0); newLayoutInfo.append(value); } addStackContent(type, newLayoutInfo); } void SVGCharacterLayoutInfo::addStackContent(StackType type, SVGLengthList* list) { unsigned length = list->numberOfItems(); if (!length) return; PositionedFloatVector newLayoutInfo; ExceptionCode ec = 0; for (unsigned i = 0; i < length; ++i) { float value = list->getItem(i, ec).value(); ASSERT(ec == 0); newLayoutInfo.append(value); } addStackContent(type, newLayoutInfo); } void SVGCharacterLayoutInfo::addStackContent(StackType type, const PositionedFloatVector& list) { switch (type) { case XStack: xStackChanged = true; xStack.append(list); break; case YStack: yStackChanged = true; yStack.append(list); break; case DxStack: dxStackChanged = true; dxStack.append(list); break; case DyStack: dyStackChanged = true; dyStack.append(list); break; case AngleStack: angleStackChanged = true; angleStack.append(list); break; default: ASSERT_NOT_REACHED(); } } void SVGCharacterLayoutInfo::addStackContent(StackType type, float value) { if (value == 0.0f) return; switch (type) { case BaselineShiftStack: baselineShiftStackChanged = true; baselineShiftStack.append(value); break; default: ASSERT_NOT_REACHED(); } } void SVGCharacterLayoutInfo::xStackWalk() { unsigned i = 1; while (!xStack.isEmpty()) { PositionedFloatVector& cur = xStack.last(); if (i + cur.position() < cur.size()) { cur.advance(i); break; } i += cur.position(); xStack.removeLast(); xStackChanged = false; } } void SVGCharacterLayoutInfo::yStackWalk() { unsigned i = 1; while (!yStack.isEmpty()) { PositionedFloatVector& cur = yStack.last(); if (i + cur.position() < cur.size()) { cur.advance(i); break; } i += cur.position(); yStack.removeLast(); yStackChanged = false; } } void SVGCharacterLayoutInfo::dxStackWalk() { unsigned i = 1; while (!dxStack.isEmpty()) { PositionedFloatVector& cur = dxStack.last(); if (i + cur.position() < cur.size()) { cur.advance(i); break; } i += cur.position(); dxStack.removeLast(); dxStackChanged = false; } } void SVGCharacterLayoutInfo::dyStackWalk() { unsigned i = 1; while (!dyStack.isEmpty()) { PositionedFloatVector& cur = dyStack.last(); if (i + cur.position() < cur.size()) { cur.advance(i); break; } i += cur.position(); dyStack.removeLast(); dyStackChanged = false; } } void SVGCharacterLayoutInfo::angleStackWalk() { unsigned i = 1; while (!angleStack.isEmpty()) { PositionedFloatVector& cur = angleStack.last(); if (i + cur.position() < cur.size()) { cur.advance(i); break; } i += cur.position(); angleStack.removeLast(); angleStackChanged = false; } } void SVGCharacterLayoutInfo::baselineShiftStackWalk() { if (!baselineShiftStack.isEmpty()) { baselineShiftStack.removeLast(); baselineShiftStackChanged = false; } } bool SVGChar::isHidden() const { return pathData && pathData->hidden; } AffineTransform SVGChar::characterTransform() const { AffineTransform ctm; // Rotate character around angle, and possibly scale. ctm.translate(x, y); ctm.rotate(angle); if (pathData) { ctm.scale(pathData->xScale, pathData->yScale); ctm.translate(pathData->xShift, pathData->yShift); ctm.rotate(pathData->orientationAngle); } ctm.translate(orientationShiftX - x, orientationShiftY - y); return ctm; } } // namespace WebCore #endif // ENABLE(SVG)