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webkit / WebKit / 15e4da4b5ce83fcfe6de6863df44c60571019d5f / . / Source / WebCore / svg / SVGPathStringSource.cpp
blob: ff1bf2a9160583d9f3f4452f4cc6a16ea2f6c253 [file] [log] [blame]
/*
* Copyright (C) Research In Motion Limited 2010. All rights reserved.
* Copyright (C) 2013 Apple Inc. All rights reserved.
*
* 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"
#include "SVGPathStringSource.h"
#include "SVGParserUtilities.h"
namespace WebCore {
SVGPathStringSource::SVGPathStringSource(const String& string)
: m_string(string)
, m_is8BitSource(string.is8Bit())
{
ASSERT(!string.isEmpty());
if (m_is8BitSource)
m_buffer8 = { string.characters8(), string.length() };
else
m_buffer16 = { string.characters16(), string.length() };
}
bool SVGPathStringSource::hasMoreData() const
{
if (m_is8BitSource)
return m_buffer8.hasCharactersRemaining();
return m_buffer16.hasCharactersRemaining();
}
bool SVGPathStringSource::moveToNextToken()
{
if (m_is8BitSource)
return skipOptionalSVGSpaces(m_buffer8);
return skipOptionalSVGSpaces(m_buffer16);
}
template <typename CharacterType> static std::optional<SVGPathSegType> nextCommandHelper(StringParsingBuffer<CharacterType>& buffer, SVGPathSegType previousCommand)
{
// Check for remaining coordinates in the current command.
if ((*buffer == '+' || *buffer == '-' || *buffer == '.' || isASCIIDigit(*buffer))
&& previousCommand != PathSegClosePath) {
if (previousCommand == PathSegMoveToAbs)
return PathSegLineToAbs;
if (previousCommand == PathSegMoveToRel)
return PathSegLineToRel;
return previousCommand;
}
return std::nullopt;
}
SVGPathSegType SVGPathStringSource::nextCommand(SVGPathSegType previousCommand)
{
if (m_is8BitSource) {
if (auto nextCommand = nextCommandHelper(m_buffer8, previousCommand))
return *nextCommand;
} else {
if (auto nextCommand = nextCommandHelper(m_buffer16, previousCommand))
return *nextCommand;
}
return *parseSVGSegmentType();
}
template<typename F> decltype(auto) SVGPathStringSource::parse(F&& functor)
{
if (m_is8BitSource)
return functor(m_buffer8);
return functor(m_buffer16);
}
std::optional<SVGPathSegType> SVGPathStringSource::parseSVGSegmentType()
{
return parse([](auto& buffer) -> SVGPathSegType {
auto character = *buffer;
buffer++;
switch (character) {
case 'Z':
case 'z':
return PathSegClosePath;
case 'M':
return PathSegMoveToAbs;
case 'm':
return PathSegMoveToRel;
case 'L':
return PathSegLineToAbs;
case 'l':
return PathSegLineToRel;
case 'C':
return PathSegCurveToCubicAbs;
case 'c':
return PathSegCurveToCubicRel;
case 'Q':
return PathSegCurveToQuadraticAbs;
case 'q':
return PathSegCurveToQuadraticRel;
case 'A':
return PathSegArcAbs;
case 'a':
return PathSegArcRel;
case 'H':
return PathSegLineToHorizontalAbs;
case 'h':
return PathSegLineToHorizontalRel;
case 'V':
return PathSegLineToVerticalAbs;
case 'v':
return PathSegLineToVerticalRel;
case 'S':
return PathSegCurveToCubicSmoothAbs;
case 's':
return PathSegCurveToCubicSmoothRel;
case 'T':
return PathSegCurveToQuadraticSmoothAbs;
case 't':
return PathSegCurveToQuadraticSmoothRel;
default:
return PathSegUnknown;
}
});
}
std::optional<SVGPathSource::MoveToSegment> SVGPathStringSource::parseMoveToSegment()
{
return parse([](auto& buffer) -> std::optional<MoveToSegment> {
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
MoveToSegment segment;
segment.targetPoint = WTFMove(*targetPoint);
return segment;
});
}
std::optional<SVGPathSource::LineToSegment> SVGPathStringSource::parseLineToSegment()
{
return parse([](auto& buffer) -> std::optional<LineToSegment> {
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
LineToSegment segment;
segment.targetPoint = WTFMove(*targetPoint);
return segment;
});
}
std::optional<SVGPathSource::LineToHorizontalSegment> SVGPathStringSource::parseLineToHorizontalSegment()
{
return parse([](auto& buffer) -> std::optional<LineToHorizontalSegment> {
auto x = parseNumber(buffer);
if (!x)
return std::nullopt;
LineToHorizontalSegment segment;
segment.x = *x;
return segment;
});
}
std::optional<SVGPathSource::LineToVerticalSegment> SVGPathStringSource::parseLineToVerticalSegment()
{
return parse([](auto& buffer) -> std::optional<LineToVerticalSegment> {
auto y = parseNumber(buffer);
if (!y)
return std::nullopt;
LineToVerticalSegment segment;
segment.y = *y;
return segment;
});
}
std::optional<SVGPathSource::CurveToCubicSegment> SVGPathStringSource::parseCurveToCubicSegment()
{
return parse([](auto& buffer) -> std::optional<CurveToCubicSegment> {
auto point1 = parseFloatPoint(buffer);
if (!point1)
return std::nullopt;
auto point2 = parseFloatPoint(buffer);
if (!point2)
return std::nullopt;
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
CurveToCubicSegment segment;
segment.point1 = *point1;
segment.point2 = *point2;
segment.targetPoint = *targetPoint;
return segment;
});
}
std::optional<SVGPathSource::CurveToCubicSmoothSegment> SVGPathStringSource::parseCurveToCubicSmoothSegment()
{
return parse([](auto& buffer) -> std::optional<CurveToCubicSmoothSegment> {
auto point2 = parseFloatPoint(buffer);
if (!point2)
return std::nullopt;
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
CurveToCubicSmoothSegment segment;
segment.point2 = *point2;
segment.targetPoint = *targetPoint;
return segment;
});
}
std::optional<SVGPathSource::CurveToQuadraticSegment> SVGPathStringSource::parseCurveToQuadraticSegment()
{
return parse([](auto& buffer) -> std::optional<CurveToQuadraticSegment> {
auto point1 = parseFloatPoint(buffer);
if (!point1)
return std::nullopt;
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
CurveToQuadraticSegment segment;
segment.point1 = *point1;
segment.targetPoint = *targetPoint;
return segment;
});
}
std::optional<SVGPathSource::CurveToQuadraticSmoothSegment> SVGPathStringSource::parseCurveToQuadraticSmoothSegment()
{
return parse([](auto& buffer) -> std::optional<CurveToQuadraticSmoothSegment> {
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
CurveToQuadraticSmoothSegment segment;
segment.targetPoint = *targetPoint;
return segment;
});
}
std::optional<SVGPathSource::ArcToSegment> SVGPathStringSource::parseArcToSegment()
{
return parse([](auto& buffer) -> std::optional<ArcToSegment> {
auto rx = parseNumber(buffer);
if (!rx)
return std::nullopt;
auto ry = parseNumber(buffer);
if (!ry)
return std::nullopt;
auto angle = parseNumber(buffer);
if (!angle)
return std::nullopt;
auto largeArc = parseArcFlag(buffer);
if (!largeArc)
return std::nullopt;
auto sweep = parseArcFlag(buffer);
if (!sweep)
return std::nullopt;
auto targetPoint = parseFloatPoint(buffer);
if (!targetPoint)
return std::nullopt;
ArcToSegment segment;
segment.rx = *rx;
segment.ry = *ry;
segment.angle = *angle;
segment.largeArc = *largeArc;
segment.sweep = *sweep;
segment.targetPoint = *targetPoint;
return segment;
});
}
} // namespace WebKit