/* * Copyright (c) 2020, Matthew Olsson * Copyright (c) 2022, Sam Atkins * * SPDX-License-Identifier: BSD-2-Clause */ #include "AttributeParser.h" #include #include #include namespace Web::SVG { AttributeParser::AttributeParser(StringView source) : m_source(move(source)) { } Vector AttributeParser::parse_path_data(StringView input) { AttributeParser parser { input }; parser.parse_whitespace(); while (!parser.done()) parser.parse_drawto(); if (!parser.m_instructions.is_empty() && parser.m_instructions[0].type != PathInstructionType::Move) { // Invalid. "A path data segment (if there is one) must begin with a "moveto" command." return {}; } return parser.m_instructions; } Optional AttributeParser::parse_coordinate(StringView input) { AttributeParser parser { input }; parser.parse_whitespace(); if (parser.match_coordinate()) { float result = parser.parse_coordinate(); parser.parse_whitespace(); if (parser.done()) return result; } return {}; } Optional AttributeParser::parse_length(StringView input) { AttributeParser parser { input }; parser.parse_whitespace(); if (parser.match_coordinate()) { float result = parser.parse_length(); parser.parse_whitespace(); if (parser.done()) return result; } return {}; } Optional AttributeParser::parse_positive_length(StringView input) { // FIXME: Where this is used, the spec usually (always?) says "A negative value is an error (see Error processing)." // So, implement error processing! Maybe this should return ErrorOr. auto result = parse_length(input); if (result.has_value() && result.value() < 0) result.clear(); return result; } Vector AttributeParser::parse_points(StringView input) { AttributeParser parser { input }; parser.parse_whitespace(); // FIXME: "If an odd number of coordinates is provided, then the element is in error, with the same user agent behavior // as occurs with an incorrectly specified ‘path’ element. In such error cases the user agent will drop the last, // odd coordinate and otherwise render the shape." // The parser currently doesn't notice that there is a missing coordinate, so make it notice! auto coordinate_pair_sequence = parser.parse_coordinate_pair_sequence(); parser.parse_whitespace(); if (!parser.done()) return {}; // FIXME: This is awkward. Can we return Gfx::FloatPoints from some of these parsing methods instead of Vector? Vector points; points.ensure_capacity(coordinate_pair_sequence.size()); for (auto const& pair : coordinate_pair_sequence) points.empend(pair[0], pair[1]); return points; } void AttributeParser::parse_drawto() { if (match('M') || match('m')) { parse_moveto(); } else if (match('Z') || match('z')) { parse_closepath(); } else if (match('L') || match('l')) { parse_lineto(); } else if (match('H') || match('h')) { parse_horizontal_lineto(); } else if (match('V') || match('v')) { parse_vertical_lineto(); } else if (match('C') || match('c')) { parse_curveto(); } else if (match('S') || match('s')) { parse_smooth_curveto(); } else if (match('Q') || match('q')) { parse_quadratic_bezier_curveto(); } else if (match('T') || match('t')) { parse_smooth_quadratic_bezier_curveto(); } else if (match('A') || match('a')) { parse_elliptical_arc(); } else { dbgln("AttributeParser::parse_drawto failed to match: '{}'", ch()); TODO(); } } void AttributeParser::parse_moveto() { bool absolute = consume() == 'M'; parse_whitespace(); for (auto& pair : parse_coordinate_pair_sequence()) m_instructions.append({ PathInstructionType::Move, absolute, pair }); } void AttributeParser::parse_closepath() { bool absolute = consume() == 'Z'; parse_whitespace(); m_instructions.append({ PathInstructionType::ClosePath, absolute, {} }); } void AttributeParser::parse_lineto() { bool absolute = consume() == 'L'; parse_whitespace(); for (auto& pair : parse_coordinate_pair_sequence()) m_instructions.append({ PathInstructionType::Line, absolute, pair }); } void AttributeParser::parse_horizontal_lineto() { bool absolute = consume() == 'H'; parse_whitespace(); m_instructions.append({ PathInstructionType::HorizontalLine, absolute, parse_coordinate_sequence() }); } void AttributeParser::parse_vertical_lineto() { bool absolute = consume() == 'V'; parse_whitespace(); m_instructions.append({ PathInstructionType::VerticalLine, absolute, parse_coordinate_sequence() }); } void AttributeParser::parse_curveto() { bool absolute = consume() == 'C'; parse_whitespace(); while (true) { m_instructions.append({ PathInstructionType::Curve, absolute, parse_coordinate_pair_triplet() }); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_coordinate()) break; } } void AttributeParser::parse_smooth_curveto() { bool absolute = consume() == 'S'; parse_whitespace(); while (true) { m_instructions.append({ PathInstructionType::SmoothCurve, absolute, parse_coordinate_pair_double() }); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_coordinate()) break; } } void AttributeParser::parse_quadratic_bezier_curveto() { bool absolute = consume() == 'Q'; parse_whitespace(); while (true) { m_instructions.append({ PathInstructionType::QuadraticBezierCurve, absolute, parse_coordinate_pair_double() }); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_coordinate()) break; } } void AttributeParser::parse_smooth_quadratic_bezier_curveto() { bool absolute = consume() == 'T'; parse_whitespace(); while (true) { m_instructions.append({ PathInstructionType::SmoothQuadraticBezierCurve, absolute, parse_coordinate_pair() }); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_coordinate()) break; } } void AttributeParser::parse_elliptical_arc() { bool absolute = consume() == 'A'; parse_whitespace(); while (true) { m_instructions.append({ PathInstructionType::EllipticalArc, absolute, parse_elliptical_arg_argument() }); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_coordinate()) break; } } float AttributeParser::parse_length() { // https://www.w3.org/TR/SVG11/types.html#DataTypeLength return parse_number(); } float AttributeParser::parse_coordinate() { // https://www.w3.org/TR/SVG11/types.html#DataTypeCoordinate // coordinate ::= length return parse_length(); } Vector AttributeParser::parse_coordinate_pair() { Vector coordinates; coordinates.append(parse_coordinate()); if (match_comma_whitespace()) parse_comma_whitespace(); coordinates.append(parse_coordinate()); return coordinates; } Vector AttributeParser::parse_coordinate_sequence() { Vector sequence; while (true) { sequence.append(parse_coordinate()); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_comma_whitespace() && !match_coordinate()) break; } return sequence; } Vector> AttributeParser::parse_coordinate_pair_sequence() { Vector> sequence; while (true) { sequence.append(parse_coordinate_pair()); if (match_comma_whitespace()) parse_comma_whitespace(); if (!match_comma_whitespace() && !match_coordinate()) break; } return sequence; } Vector AttributeParser::parse_coordinate_pair_double() { Vector coordinates; coordinates.extend(parse_coordinate_pair()); if (match_comma_whitespace()) parse_comma_whitespace(); coordinates.extend(parse_coordinate_pair()); return coordinates; } Vector AttributeParser::parse_coordinate_pair_triplet() { Vector coordinates; coordinates.extend(parse_coordinate_pair()); if (match_comma_whitespace()) parse_comma_whitespace(); coordinates.extend(parse_coordinate_pair()); if (match_comma_whitespace()) parse_comma_whitespace(); coordinates.extend(parse_coordinate_pair()); return coordinates; } Vector AttributeParser::parse_elliptical_arg_argument() { Vector numbers; numbers.append(parse_nonnegative_number()); if (match_comma_whitespace()) parse_comma_whitespace(); numbers.append(parse_nonnegative_number()); if (match_comma_whitespace()) parse_comma_whitespace(); numbers.append(parse_number()); parse_comma_whitespace(); numbers.append(parse_flag()); if (match_comma_whitespace()) parse_comma_whitespace(); numbers.append(parse_flag()); if (match_comma_whitespace()) parse_comma_whitespace(); numbers.extend(parse_coordinate_pair()); return numbers; } void AttributeParser::parse_whitespace(bool must_match_once) { bool matched = false; while (!done() && match_whitespace()) { consume(); matched = true; } VERIFY(!must_match_once || matched); } void AttributeParser::parse_comma_whitespace() { if (match(',')) { consume(); parse_whitespace(); } else { parse_whitespace(1); if (match(',')) consume(); parse_whitespace(); } } // https://www.w3.org/TR/SVG11/types.html#DataTypeNumber float AttributeParser::parse_number() { auto sign = parse_sign(); return sign * parse_nonnegative_number(); } // https://www.w3.org/TR/SVG11/paths.html#PathDataBNF float AttributeParser::parse_nonnegative_number() { // NOTE: The grammar is almost a floating point except we cannot have a sign // at the start. That condition should have been checked by the caller. VERIFY(!match('+') && !match('-')); auto remaining_source_text = m_source.substring_view(m_cursor); char const* start = remaining_source_text.characters_without_null_termination(); auto maybe_float = parse_first_floating_point(start, start + remaining_source_text.length()); VERIFY(maybe_float.parsed_value()); m_cursor += maybe_float.end_ptr - start; return maybe_float.value; } float AttributeParser::parse_flag() { if (!match('0') && !match('1')) VERIFY_NOT_REACHED(); return consume() - '0'; } int AttributeParser::parse_sign() { if (match('-')) { consume(); return -1; } if (match('+')) consume(); return 1; } bool AttributeParser::match_whitespace() const { if (done()) return false; char c = ch(); return c == 0x9 || c == 0x20 || c == 0xa || c == 0xc || c == 0xd; } bool AttributeParser::match_comma_whitespace() const { return match_whitespace() || match(','); } bool AttributeParser::match_coordinate() const { return match_length(); } bool AttributeParser::match_length() const { return !done() && (isdigit(ch()) || ch() == '-' || ch() == '+' || ch() == '.'); } }