/* * Copyright (C) 2014-2016 Igalia S.L. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of Google Inc. nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "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 THE COPYRIGHT * OWNER 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 "GridPositionsResolver.h" #include "GridArea.h" #include "RenderBox.h" #include namespace WebCore { static inline bool isColumnSide(GridPositionSide side) { return side == ColumnStartSide || side == ColumnEndSide; } static inline bool isStartSide(GridPositionSide side) { return side == ColumnStartSide || side == RowStartSide; } static inline GridPositionSide initialPositionSide(GridTrackSizingDirection direction) { return direction == ForColumns ? ColumnStartSide : RowStartSide; } static inline GridPositionSide finalPositionSide(GridTrackSizingDirection direction) { return direction == ForColumns ? ColumnEndSide : RowEndSide; } static inline GridTrackSizingDirection directionFromSide(GridPositionSide side) { return side == ColumnStartSide || side == ColumnEndSide ? ForColumns : ForRows; } static const String implicitNamedGridLineForSide(const String& lineName, GridPositionSide side) { return lineName + (isStartSide(side) ? "-start" : "-end"); } NamedLineCollection::NamedLineCollection(const RenderStyle& gridContainerStyle, const String& namedLine, GridTrackSizingDirection direction, unsigned lastLine, unsigned autoRepeatTracksCount) : m_lastLine(lastLine) , m_autoRepeatTotalTracks(autoRepeatTracksCount) { bool isRowAxis = direction == ForColumns; const NamedGridLinesMap& gridLineNames = isRowAxis ? gridContainerStyle.namedGridColumnLines() : gridContainerStyle.namedGridRowLines(); const NamedGridLinesMap& autoRepeatGridLineNames = isRowAxis ? gridContainerStyle.autoRepeatNamedGridColumnLines() : gridContainerStyle.autoRepeatNamedGridRowLines(); auto linesIterator = gridLineNames.find(namedLine); m_namedLinesIndexes = linesIterator == gridLineNames.end() ? nullptr : &linesIterator->value; auto autoRepeatLinesIterator = autoRepeatGridLineNames.find(namedLine); m_autoRepeatNamedLinesIndexes = autoRepeatLinesIterator == autoRepeatGridLineNames.end() ? nullptr : &autoRepeatLinesIterator->value; m_insertionPoint = isRowAxis ? gridContainerStyle.gridAutoRepeatColumnsInsertionPoint() : gridContainerStyle.gridAutoRepeatRowsInsertionPoint(); m_autoRepeatTrackListLength = isRowAxis ? gridContainerStyle.gridAutoRepeatColumns().size() : gridContainerStyle.gridAutoRepeatRows().size(); } bool NamedLineCollection::isValidNamedLineOrArea(const String& namedLine, const RenderStyle& gridContainerStyle, GridPositionSide side) { bool isRowAxis = directionFromSide(side) == ForColumns; auto& gridLineNames = isRowAxis ? gridContainerStyle.namedGridColumnLines() : gridContainerStyle.namedGridRowLines(); auto& autoRepeatGridLineNames = isRowAxis ? gridContainerStyle.autoRepeatNamedGridColumnLines() : gridContainerStyle.autoRepeatNamedGridRowLines(); if (gridLineNames.contains(namedLine) || autoRepeatGridLineNames.contains(namedLine)) return true; String implicitName = implicitNamedGridLineForSide(namedLine, side); return gridLineNames.contains(implicitName) || autoRepeatGridLineNames.contains(implicitName); } bool NamedLineCollection::hasNamedLines() const { return m_namedLinesIndexes || m_autoRepeatNamedLinesIndexes; } size_t NamedLineCollection::find(unsigned line) const { if (line > m_lastLine) return notFound; if (!m_autoRepeatNamedLinesIndexes || line < m_insertionPoint) return m_namedLinesIndexes ? m_namedLinesIndexes->find(line) : notFound; if (line <= (m_insertionPoint + m_autoRepeatTotalTracks)) { size_t localIndex = line - m_insertionPoint; size_t indexInFirstRepetition = localIndex % m_autoRepeatTrackListLength; if (indexInFirstRepetition) return m_autoRepeatNamedLinesIndexes->find(indexInFirstRepetition); // The line names defined in the last line are also present in the first line of the next // repetition (if any). Same for the line names defined in the first line. if (localIndex == m_autoRepeatTotalTracks) return m_autoRepeatNamedLinesIndexes->find(m_autoRepeatTrackListLength); size_t position = m_autoRepeatNamedLinesIndexes->find(0u); if (position != notFound) return position; return localIndex ? m_autoRepeatNamedLinesIndexes->find(m_autoRepeatTrackListLength) : notFound; } return m_namedLinesIndexes ? m_namedLinesIndexes->find(line - (m_autoRepeatTotalTracks - 1)) : notFound; } bool NamedLineCollection::contains(unsigned line) const { ASSERT(hasNamedLines()); return find(line) != notFound; } unsigned NamedLineCollection::firstPosition() const { ASSERT(hasNamedLines()); unsigned firstLine = 0; if (!m_autoRepeatNamedLinesIndexes) { if (!m_insertionPoint || m_insertionPoint < m_namedLinesIndexes->at(firstLine)) return m_namedLinesIndexes->at(firstLine) + (m_autoRepeatTotalTracks ? m_autoRepeatTotalTracks - 1 : 0); return m_namedLinesIndexes->at(firstLine); } if (!m_namedLinesIndexes) return m_autoRepeatNamedLinesIndexes->at(firstLine) + m_insertionPoint; if (!m_insertionPoint) return std::min(m_namedLinesIndexes->at(firstLine) + m_autoRepeatTotalTracks, m_autoRepeatNamedLinesIndexes->at(firstLine)); return std::min(m_namedLinesIndexes->at(firstLine), m_autoRepeatNamedLinesIndexes->at(firstLine) + m_insertionPoint); } static void adjustGridPositionsFromStyle(const RenderStyle& gridContainerStyle, const RenderBox& gridItem, GridTrackSizingDirection direction, GridPosition& initialPosition, GridPosition& finalPosition) { bool isForColumns = direction == ForColumns; initialPosition = isForColumns ? gridItem.style().gridItemColumnStart() : gridItem.style().gridItemRowStart(); finalPosition = isForColumns ? gridItem.style().gridItemColumnEnd() : gridItem.style().gridItemRowEnd(); // We must handle the placement error handling code here instead of in the StyleAdjuster because we don't want to // overwrite the specified values. if (initialPosition.isSpan() && finalPosition.isSpan()) finalPosition.setAutoPosition(); if (gridItem.isOutOfFlowPositioned()) { // Early detect the case of non existing named grid lines for positioned items. if (initialPosition.isNamedGridArea() && !NamedLineCollection::isValidNamedLineOrArea(initialPosition.namedGridLine(), gridContainerStyle, initialPositionSide(direction))) initialPosition.setAutoPosition(); if (finalPosition.isNamedGridArea() && !NamedLineCollection::isValidNamedLineOrArea(finalPosition.namedGridLine(), gridContainerStyle, finalPositionSide(direction))) finalPosition.setAutoPosition(); } // If the grid item has an automatic position and a grid span for a named line in a given dimension, instead treat the grid span as one. if (initialPosition.isAuto() && finalPosition.isSpan() && !finalPosition.namedGridLine().isNull()) finalPosition.setSpanPosition(1, String()); if (finalPosition.isAuto() && initialPosition.isSpan() && !initialPosition.namedGridLine().isNull()) initialPosition.setSpanPosition(1, String()); } unsigned GridPositionsResolver::explicitGridColumnCount(const RenderStyle& gridContainerStyle, unsigned autoRepeatTracksCount) { return std::min(std::max(gridContainerStyle.gridColumns().size() + autoRepeatTracksCount, gridContainerStyle.namedGridAreaColumnCount()), kGridMaxTracks); } unsigned GridPositionsResolver::explicitGridRowCount(const RenderStyle& gridContainerStyle, unsigned autoRepeatTracksCount) { return std::min(std::max(gridContainerStyle.gridRows().size() + autoRepeatTracksCount, gridContainerStyle.namedGridAreaRowCount()), kGridMaxTracks); } static unsigned explicitGridSizeForSide(const RenderStyle& gridContainerStyle, GridPositionSide side, unsigned autoRepeatTracksCount) { return isColumnSide(side) ? GridPositionsResolver::explicitGridColumnCount(gridContainerStyle, autoRepeatTracksCount) : GridPositionsResolver::explicitGridRowCount(gridContainerStyle, autoRepeatTracksCount); } static unsigned lookAheadForNamedGridLine(int start, unsigned numberOfLines, unsigned gridLastLine, NamedLineCollection& linesCollection) { ASSERT(numberOfLines); // Only implicit lines on the search direction are assumed to have the given name, so we can start to look from first line. // See: https://drafts.csswg.org/css-grid/#grid-placement-span-int unsigned end = std::max(start, 0); if (!linesCollection.hasNamedLines()) return std::max(end, gridLastLine + 1) + numberOfLines - 1; for (; numberOfLines; ++end) { if (end > gridLastLine || linesCollection.contains(end)) numberOfLines--; } ASSERT(end); return end - 1; } static int lookBackForNamedGridLine(int end, unsigned numberOfLines, int gridLastLine, NamedLineCollection& linesCollection) { ASSERT(numberOfLines); // Only implicit lines on the search direction are assumed to have the given name, so we can start to look from last line. // See: https://drafts.csswg.org/css-grid/#grid-placement-span-int int start = std::min(end, gridLastLine); if (!linesCollection.hasNamedLines()) return std::min(start, -1) - numberOfLines + 1; for (; numberOfLines; --start) { if (start < 0 || linesCollection.contains(start)) numberOfLines--; } return start + 1; } static int resolveNamedGridLinePositionFromStyle(const RenderStyle& gridContainerStyle, const GridPosition& position, GridPositionSide side, unsigned autoRepeatTracksCount) { ASSERT(!position.namedGridLine().isNull()); unsigned lastLine = explicitGridSizeForSide(gridContainerStyle, side, autoRepeatTracksCount); NamedLineCollection linesCollection(gridContainerStyle, position.namedGridLine(), directionFromSide(side), lastLine, autoRepeatTracksCount); if (position.isPositive()) return lookAheadForNamedGridLine(0, std::abs(position.integerPosition()), lastLine, linesCollection); return lookBackForNamedGridLine(lastLine, std::abs(position.integerPosition()), lastLine, linesCollection); } static GridSpan definiteGridSpanWithNamedLineSpanAgainstOpposite(int oppositeLine, const GridPosition& position, GridPositionSide side, unsigned lastLine, NamedLineCollection& linesCollection) { int start, end; if (side == RowStartSide || side == ColumnStartSide) { start = lookBackForNamedGridLine(oppositeLine - 1, position.spanPosition(), lastLine, linesCollection); end = oppositeLine; } else { start = oppositeLine; end = lookAheadForNamedGridLine(oppositeLine + 1, position.spanPosition(), lastLine, linesCollection); } return GridSpan::untranslatedDefiniteGridSpan(start, end); } static GridSpan resolveNamedGridLinePositionAgainstOppositePosition(const RenderStyle& gridContainerStyle, int oppositeLine, const GridPosition& position, GridPositionSide side, unsigned autoRepeatTracksCount) { ASSERT(position.isSpan()); ASSERT(!position.namedGridLine().isNull()); // Negative positions are not allowed per the specification and should have been handled during parsing. ASSERT(position.spanPosition() > 0); unsigned lastLine = explicitGridSizeForSide(gridContainerStyle, side, autoRepeatTracksCount); NamedLineCollection linesCollection(gridContainerStyle, position.namedGridLine(), directionFromSide(side), lastLine, autoRepeatTracksCount); return definiteGridSpanWithNamedLineSpanAgainstOpposite(oppositeLine, position, side, lastLine, linesCollection); } static GridSpan resolveGridPositionAgainstOppositePosition(const RenderStyle& gridContainerStyle, int oppositeLine, const GridPosition& position, GridPositionSide side, unsigned autoRepeatTracksCount) { if (position.isAuto()) { if (isStartSide(side)) return GridSpan::untranslatedDefiniteGridSpan(oppositeLine - 1, oppositeLine); return GridSpan::untranslatedDefiniteGridSpan(oppositeLine, oppositeLine + 1); } ASSERT(position.isSpan()); ASSERT(position.spanPosition() > 0); if (!position.namedGridLine().isNull()) { // span 2 'c' -> we need to find the appropriate grid line before / after our opposite position. return resolveNamedGridLinePositionAgainstOppositePosition(gridContainerStyle, oppositeLine, position, side, autoRepeatTracksCount); } // 'span 1' is contained inside a single grid track regardless of the direction. // That's why the CSS span value is one more than the offset we apply. unsigned positionOffset = position.spanPosition(); if (isStartSide(side)) return GridSpan::untranslatedDefiniteGridSpan(oppositeLine - positionOffset, oppositeLine); return GridSpan::untranslatedDefiniteGridSpan(oppositeLine, oppositeLine + positionOffset); } unsigned GridPositionsResolver::spanSizeForAutoPlacedItem(const RenderStyle& gridContainerStyle, const RenderBox& gridItem, GridTrackSizingDirection direction) { GridPosition initialPosition, finalPosition; adjustGridPositionsFromStyle(gridContainerStyle, gridItem, direction, initialPosition, finalPosition); // This method will only be used when both positions need to be resolved against the opposite one. ASSERT(initialPosition.shouldBeResolvedAgainstOppositePosition() && finalPosition.shouldBeResolvedAgainstOppositePosition()); if (initialPosition.isAuto() && finalPosition.isAuto()) return 1; GridPosition position = initialPosition.isSpan() ? initialPosition : finalPosition; ASSERT(position.isSpan()); ASSERT(position.spanPosition()); return position.spanPosition(); } static int resolveGridPositionFromStyle(const RenderStyle& gridContainerStyle, const GridPosition& position, GridPositionSide side, unsigned autoRepeatTracksCount) { switch (position.type()) { case ExplicitPosition: { ASSERT(position.integerPosition()); if (!position.namedGridLine().isNull()) return resolveNamedGridLinePositionFromStyle(gridContainerStyle, position, side, autoRepeatTracksCount); // Handle explicit position. if (position.isPositive()) return position.integerPosition() - 1; unsigned resolvedPosition = std::abs(position.integerPosition()) - 1; const unsigned endOfTrack = explicitGridSizeForSide(gridContainerStyle, side, autoRepeatTracksCount); return endOfTrack - resolvedPosition; } case NamedGridAreaPosition: { // First attempt to match the grid area's edge to a named grid area: if there is a named line with the name // ''-start (for grid-*-start) / -end'' (for grid-*-end), contributes the first such // line to the grid item's placement. String namedGridLine = position.namedGridLine(); ASSERT(!position.namedGridLine().isNull()); unsigned lastLine = explicitGridSizeForSide(gridContainerStyle, side, autoRepeatTracksCount); NamedLineCollection implicitLines(gridContainerStyle, implicitNamedGridLineForSide(namedGridLine, side), directionFromSide(side), lastLine, autoRepeatTracksCount); if (implicitLines.hasNamedLines()) return implicitLines.firstPosition(); // Otherwise, if there is a named line with the specified name, contributes the first such line to the grid // item's placement. NamedLineCollection explicitLines(gridContainerStyle, namedGridLine, directionFromSide(side), lastLine, autoRepeatTracksCount); if (explicitLines.hasNamedLines()) return explicitLines.firstPosition(); ASSERT(!NamedLineCollection::isValidNamedLineOrArea(namedGridLine, gridContainerStyle, side)); // If none of the above works specs mandate to assume that all the lines in the implicit grid have this name. return lastLine + 1; } case AutoPosition: case SpanPosition: // 'auto' and span depend on the opposite position for resolution (e.g. grid-row: auto / 1 or grid-column: span 3 / "myHeader"). ASSERT_NOT_REACHED(); return 0; } ASSERT_NOT_REACHED(); return 0; } GridSpan GridPositionsResolver::resolveGridPositionsFromStyle(const RenderStyle& gridContainerStyle, const RenderBox& gridItem, GridTrackSizingDirection direction, unsigned autoRepeatTracksCount) { GridPosition initialPosition, finalPosition; adjustGridPositionsFromStyle(gridContainerStyle, gridItem, direction, initialPosition, finalPosition); GridPositionSide initialSide = initialPositionSide(direction); GridPositionSide finalSide = finalPositionSide(direction); // We can't get our grid positions without running the auto placement algorithm. if (initialPosition.shouldBeResolvedAgainstOppositePosition() && finalPosition.shouldBeResolvedAgainstOppositePosition()) return GridSpan::indefiniteGridSpan(); if (initialPosition.shouldBeResolvedAgainstOppositePosition()) { // Infer the position from the final position ('auto / 1' or 'span 2 / 3' case). auto endLine = resolveGridPositionFromStyle(gridContainerStyle, finalPosition, finalSide, autoRepeatTracksCount); return resolveGridPositionAgainstOppositePosition(gridContainerStyle, endLine, initialPosition, initialSide, autoRepeatTracksCount); } if (finalPosition.shouldBeResolvedAgainstOppositePosition()) { // Infer our position from the initial position ('1 / auto' or '3 / span 2' case). auto startLine = resolveGridPositionFromStyle(gridContainerStyle, initialPosition, initialSide, autoRepeatTracksCount); return resolveGridPositionAgainstOppositePosition(gridContainerStyle, startLine, finalPosition, finalSide, autoRepeatTracksCount); } int startLine = resolveGridPositionFromStyle(gridContainerStyle, initialPosition, initialSide, autoRepeatTracksCount); int endLine = resolveGridPositionFromStyle(gridContainerStyle, finalPosition, finalSide, autoRepeatTracksCount); if (startLine > endLine) std::swap(startLine, endLine); else if (startLine == endLine) endLine = startLine + 1; return GridSpan::untranslatedDefiniteGridSpan(startLine, std::max(startLine, endLine)); } } // namespace WebCore