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cve-single-line-fixes / JavaScript /parse.js
Asankhaya Sharma
initial dataset
eb67da4
raw
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37.9 kB
 'use strict';
var ArgumentsError = require('../error/ArgumentsError');
var deepMap = require('../utils/collection/deepMap');
function factory (type, config, load, typed) {
var AccessorNode = load(require('./node/AccessorNode'));
var ArrayNode = load(require('./node/ArrayNode'));
var AssignmentNode = load(require('./node/AssignmentNode'));
var BlockNode = load(require('./node/BlockNode'));
var ConditionalNode = load(require('./node/ConditionalNode'));
var ConstantNode = load(require('./node/ConstantNode'));
var FunctionAssignmentNode = load(require('./node/FunctionAssignmentNode'));
var IndexNode = load(require('./node/IndexNode'));
var ObjectNode = load(require('./node/ObjectNode'));
var OperatorNode = load(require('./node/OperatorNode'));
var ParenthesisNode = load(require('./node/ParenthesisNode'));
var FunctionNode = load(require('./node/FunctionNode'));
var RangeNode = load(require('./node/RangeNode'));
var SymbolNode = load(require('./node/SymbolNode'));
/**
* Parse an expression. Returns a node tree, which can be evaluated by
* invoking node.eval();
*
* Syntax:
*
* parse(expr)
* parse(expr, options)
* parse([expr1, expr2, expr3, ...])
* parse([expr1, expr2, expr3, ...], options)
*
* Example:
*
* var node = parse('sqrt(3^2 + 4^2)');
* node.compile(math).eval(); // 5
*
* var scope = {a:3, b:4}
* var node = parse('a * b'); // 12
* var code = node.compile(math);
* code.eval(scope); // 12
* scope.a = 5;
* code.eval(scope); // 20
*
* var nodes = math.parse(['a = 3', 'b = 4', 'a * b']);
* nodes[2].compile(math).eval(); // 12
*
* @param {string | string[] | Matrix} expr
* @param {{nodes: Object<string, Node>}} [options] Available options:
* - `nodes` a set of custom nodes
* @return {Node | Node[]} node
* @throws {Error}
*/
function parse (expr, options) {
if (arguments.length != 1 && arguments.length != 2) {
throw new ArgumentsError('parse', arguments.length, 1, 2);
}
// pass extra nodes
extra_nodes = (options && options.nodes) ? options.nodes : {};
if (typeof expr === 'string') {
// parse a single expression
expression = expr;
return parseStart();
}
else if (Array.isArray(expr) || expr instanceof type.Matrix) {
// parse an array or matrix with expressions
return deepMap(expr, function (elem) {
if (typeof elem !== 'string') throw new TypeError('String expected');
expression = elem;
return parseStart();
});
}
else {
// oops
throw new TypeError('String or matrix expected');
}
}
// token types enumeration
var TOKENTYPE = {
NULL : 0,
DELIMITER : 1,
NUMBER : 2,
SYMBOL : 3,
UNKNOWN : 4
};
// map with all delimiters
var DELIMITERS = {
',': true,
'(': true,
')': true,
'[': true,
']': true,
'{': true,
'}': true,
'\"': true,
';': true,
'+': true,
'-': true,
'*': true,
'.*': true,
'/': true,
'./': true,
'%': true,
'^': true,
'.^': true,
'~': true,
'!': true,
'&': true,
'|': true,
'^|': true,
'\'': true,
'=': true,
':': true,
'?': true,
'==': true,
'!=': true,
'<': true,
'>': true,
'<=': true,
'>=': true,
'<<': true,
'>>': true,
'>>>': true
};
// map with all named delimiters
var NAMED_DELIMITERS = {
'mod': true,
'to': true,
'in': true,
'and': true,
'xor': true,
'or': true,
'not': true
};
var extra_nodes = {}; // current extra nodes
var expression = ''; // current expression
var comment = ''; // last parsed comment
var index = 0; // current index in expr
var c = ''; // current token character in expr
var token = ''; // current token
var token_type = TOKENTYPE.NULL; // type of the token
var nesting_level = 0; // level of nesting inside parameters, used to ignore newline characters
var conditional_level = null; // when a conditional is being parsed, the level of the conditional is stored here
/**
* Get the first character from the expression.
* The character is stored into the char c. If the end of the expression is
* reached, the function puts an empty string in c.
* @private
*/
function first() {
index = 0;
c = expression.charAt(0);
nesting_level = 0;
conditional_level = null;
}
/**
* Get the next character from the expression.
* The character is stored into the char c. If the end of the expression is
* reached, the function puts an empty string in c.
* @private
*/
function next() {
index++;
c = expression.charAt(index);
}
/**
* Preview the previous character from the expression.
* @return {string} cNext
* @private
*/
function prevPreview() {
return expression.charAt(index - 1);
}
/**
* Preview the next character from the expression.
* @return {string} cNext
* @private
*/
function nextPreview() {
return expression.charAt(index + 1);
}
/**
* Preview the second next character from the expression.
* @return {string} cNext
* @private
*/
function nextNextPreview() {
return expression.charAt(index + 2);
}
/**
* Get next token in the current string expr.
* The token and token type are available as token and token_type
* @private
*/
function getToken() {
token_type = TOKENTYPE.NULL;
token = '';
comment = '';
// skip over whitespaces
// space, tab, and newline when inside parameters
while (parse.isWhitespace(c, nesting_level)) {
next();
}
// skip comment
if (c == '#') {
while (c != '\n' && c != '') {
comment += c;
next();
}
}
// check for end of expression
if (c == '') {
// token is still empty
token_type = TOKENTYPE.DELIMITER;
return;
}
// check for new line character
if (c == '\n' && !nesting_level) {
token_type = TOKENTYPE.DELIMITER;
token = c;
next();
return;
}
// check for delimiters consisting of 3 characters
var c2 = c + nextPreview();
var c3 = c2 + nextNextPreview();
if (c3.length == 3 && DELIMITERS[c3]) {
token_type = TOKENTYPE.DELIMITER;
token = c3;
next();
next();
next();
return;
}
// check for delimiters consisting of 2 characters
if (c2.length == 2 && DELIMITERS[c2]) {
token_type = TOKENTYPE.DELIMITER;
token = c2;
next();
next();
return;
}
// check for delimiters consisting of 1 character
if (DELIMITERS[c]) {
token_type = TOKENTYPE.DELIMITER;
token = c;
next();
return;
}
// check for a number
if (parse.isDigitDot(c)) {
token_type = TOKENTYPE.NUMBER;
// get number, can have a single dot
if (c == '.') {
token += c;
next();
if (!parse.isDigit(c)) {
// this is no number, it is just a dot (can be dot notation)
token_type = TOKENTYPE.DELIMITER;
}
}
else {
while (parse.isDigit(c)) {
token += c;
next();
}
if (parse.isDecimalMark(c, nextPreview())) {
token += c;
next();
}
}
while (parse.isDigit(c)) {
token += c;
next();
}
// check for exponential notation like "2.3e-4", "1.23e50" or "2e+4"
c2 = nextPreview();
if (c == 'E' || c == 'e') {
if (parse.isDigit(c2) || c2 == '-' || c2 == '+') {
token += c;
next();
if (c == '+' || c == '-') {
token += c;
next();
}
// Scientific notation MUST be followed by an exponent
if (!parse.isDigit(c)) {
throw createSyntaxError('Digit expected, got "' + c + '"');
}
while (parse.isDigit(c)) {
token += c;
next();
}
if (parse.isDecimalMark(c, nextPreview())) {
throw createSyntaxError('Digit expected, got "' + c + '"');
}
}
else if (c2 == '.') {
next();
throw createSyntaxError('Digit expected, got "' + c + '"');
}
}
return;
}
// check for variables, functions, named operators
if (parse.isAlpha(c, prevPreview(), nextPreview())) {
while (parse.isAlpha(c, prevPreview(), nextPreview()) || parse.isDigit(c)) {
token += c;
next();
}
if (NAMED_DELIMITERS.hasOwnProperty(token)) {
token_type = TOKENTYPE.DELIMITER;
}
else {
token_type = TOKENTYPE.SYMBOL;
}
return;
}
// something unknown is found, wrong characters -> a syntax error
token_type = TOKENTYPE.UNKNOWN;
while (c != '') {
token += c;
next();
}
throw createSyntaxError('Syntax error in part "' + token + '"');
}
/**
* Get next token and skip newline tokens
*/
function getTokenSkipNewline () {
do {
getToken();
}
while (token == '\n');
}
/**
* Open parameters.
* New line characters will be ignored until closeParams() is called
*/
function openParams() {
nesting_level++;
}
/**
* Close parameters.
* New line characters will no longer be ignored
*/
function closeParams() {
nesting_level--;
}
/**
* Checks whether the current character `c` is a valid alpha character:
*
* - A latin letter (upper or lower case) Ascii: a-z, A-Z
* - An underscore Ascii: _
* - A dollar sign Ascii: $
* - A latin letter with accents Unicode: \u00C0 - \u02AF
* - A greek letter Unicode: \u0370 - \u03FF
* - A mathematical alphanumeric symbol Unicode: \u{1D400} - \u{1D7FF} excluding invalid code points
*
* The previous and next characters are needed to determine whether
* this character is part of a unicode surrogate pair.
*
* @param {string} c Current character in the expression
* @param {string} cPrev Previous character
* @param {string} cNext Next character
* @return {boolean}
*/
parse.isAlpha = function isAlpha (c, cPrev, cNext) {
return parse.isValidLatinOrGreek(c)
|| parse.isValidMathSymbol(c, cNext)
|| parse.isValidMathSymbol(cPrev, c);
};
/**
* Test whether a character is a valid latin, greek, or letter-like character
* @param {string} c
* @return {boolean}
*/
parse.isValidLatinOrGreek = function isValidLatinOrGreek (c) {
return /^[a-zA-Z_$\u00C0-\u02AF\u0370-\u03FF\u2100-\u214F]$/.test(c);
};
/**
* Test whether two given 16 bit characters form a surrogate pair of a
* unicode math symbol.
*
* http://unicode-table.com/en/
* http://www.wikiwand.com/en/Mathematical_operators_and_symbols_in_Unicode
*
* Note: In ES6 will be unicode aware:
* http://stackoverflow.com/questions/280712/javascript-unicode-regexes
* https://mathiasbynens.be/notes/es6-unicode-regex
*
* @param {string} high
* @param {string} low
* @return {boolean}
*/
parse.isValidMathSymbol = function isValidMathSymbol (high, low) {
return /^[\uD835]$/.test(high) &&
/^[\uDC00-\uDFFF]$/.test(low) &&
/^[^\uDC55\uDC9D\uDCA0\uDCA1\uDCA3\uDCA4\uDCA7\uDCA8\uDCAD\uDCBA\uDCBC\uDCC4\uDD06\uDD0B\uDD0C\uDD15\uDD1D\uDD3A\uDD3F\uDD45\uDD47-\uDD49\uDD51\uDEA6\uDEA7\uDFCC\uDFCD]$/.test(low);
};
/**
* Check whether given character c is a white space character: space, tab, or enter
* @param {string} c
* @param {number} nestingLevel
* @return {boolean}
*/
parse.isWhitespace = function isWhitespace (c, nestingLevel) {
// TODO: also take '\r' carriage return as newline? Or does that give problems on mac?
return c == ' ' || c == '\t' || (c == '\n' && nestingLevel > 0);
};
/**
* Test whether the character c is a decimal mark (dot).
* This is the case when it's not the start of a delimiter '.*', './', or '.^'
* @param {string} c
* @param {string} cNext
* @return {boolean}
*/
parse.isDecimalMark = function isDecimalMark (c, cNext) {
return c == '.' && cNext !== '/' && cNext !== '*' && cNext !== '^';
};
/**
* checks if the given char c is a digit or dot
* @param {string} c a string with one character
* @return {boolean}
*/
parse.isDigitDot = function isDigitDot (c) {
return ((c >= '0' && c <= '9') || c == '.');
};
/**
* checks if the given char c is a digit
* @param {string} c a string with one character
* @return {boolean}
*/
parse.isDigit = function isDigit (c) {
return (c >= '0' && c <= '9');
};
/**
* Start of the parse levels below, in order of precedence
* @return {Node} node
* @private
*/
function parseStart () {
// get the first character in expression
first();
getToken();
var node = parseBlock();
// check for garbage at the end of the expression
// an expression ends with a empty character '' and token_type DELIMITER
if (token != '') {
if (token_type == TOKENTYPE.DELIMITER) {
// user entered a not existing operator like "//"
// TODO: give hints for aliases, for example with "<>" give as hint " did you mean != ?"
throw createError('Unexpected operator ' + token);
}
else {
throw createSyntaxError('Unexpected part "' + token + '"');
}
}
return node;
}
/**
* Parse a block with expressions. Expressions can be separated by a newline
* character '\n', or by a semicolon ';'. In case of a semicolon, no output
* of the preceding line is returned.
* @return {Node} node
* @private
*/
function parseBlock () {
var node;
var blocks = [];
var visible;
if (token != '' && token != '\n' && token != ';') {
node = parseAssignment();
node.comment = comment;
}
// TODO: simplify this loop
while (token == '\n' || token == ';') {
if (blocks.length == 0 && node) {
visible = (token != ';');
blocks.push({
node: node,
visible: visible
});
}
getToken();
if (token != '\n' && token != ';' && token != '') {
node = parseAssignment();
node.comment = comment;
visible = (token != ';');
blocks.push({
node: node,
visible: visible
});
}
}
if (blocks.length > 0) {
return new BlockNode(blocks);
}
else {
if (!node) {
node = new ConstantNode('undefined', 'undefined');
node.comment = comment;
}
return node
}
}
/**
* Assignment of a function or variable,
* - can be a variable like 'a=2.3'
* - or a updating an existing variable like 'matrix(2,3:5)=[6,7,8]'
* - defining a function like 'f(x) = x^2'
* @return {Node} node
* @private
*/
function parseAssignment () {
var name, args, value, valid;
var node = parseConditional();
if (token == '=') {
if (type.isSymbolNode(node)) {
// parse a variable assignment like 'a = 2/3'
name = node.name;
getTokenSkipNewline();
value = parseAssignment();
return new AssignmentNode(new SymbolNode(name), value);
}
else if (type.isAccessorNode(node)) {
// parse a matrix subset assignment like 'A[1,2] = 4'
getTokenSkipNewline();
value = parseAssignment();
return new AssignmentNode(node.object, node.index, value);
}
// BUG: CWE-94 Improper Control of Generation of Code ('Code Injection')
// else if (type.isFunctionNode(node)) {
// FIXED:
else if (type.isFunctionNode(node) && type.isSymbolNode(node.fn)) {
// parse function assignment like 'f(x) = x^2'
valid = true;
args = [];
name = node.name;
node.args.forEach(function (arg, index) {
if (type.isSymbolNode(arg)) {
args[index] = arg.name;
}
else {
valid = false;
}
});
if (valid) {
getTokenSkipNewline();
value = parseAssignment();
return new FunctionAssignmentNode(name, args, value);
}
}
throw createSyntaxError('Invalid left hand side of assignment operator =');
}
return node;
}
/**
* conditional operation
*
* condition ? truePart : falsePart
*
* Note: conditional operator is right-associative
*
* @return {Node} node
* @private
*/
function parseConditional () {
var node = parseLogicalOr();
while (token == '?') {
// set a conditional level, the range operator will be ignored as long
// as conditional_level == nesting_level.
var prev = conditional_level;
conditional_level = nesting_level;
getTokenSkipNewline();
var condition = node;
var trueExpr = parseAssignment();
if (token != ':') throw createSyntaxError('False part of conditional expression expected');
conditional_level = null;
getTokenSkipNewline();
var falseExpr = parseAssignment(); // Note: check for conditional operator again, right associativity
node = new ConditionalNode(condition, trueExpr, falseExpr);
// restore the previous conditional level
conditional_level = prev;
}
return node;
}
/**
* logical or, 'x or y'
* @return {Node} node
* @private
*/
function parseLogicalOr() {
var node = parseLogicalXor();
while (token == 'or') {
getTokenSkipNewline();
node = new OperatorNode('or', 'or', [node, parseLogicalXor()]);
}
return node;
}
/**
* logical exclusive or, 'x xor y'
* @return {Node} node
* @private
*/
function parseLogicalXor() {
var node = parseLogicalAnd();
while (token == 'xor') {
getTokenSkipNewline();
node = new OperatorNode('xor', 'xor', [node, parseLogicalAnd()]);
}
return node;
}
/**
* logical and, 'x and y'
* @return {Node} node
* @private
*/
function parseLogicalAnd() {
var node = parseBitwiseOr();
while (token == 'and') {
getTokenSkipNewline();
node = new OperatorNode('and', 'and', [node, parseBitwiseOr()]);
}
return node;
}
/**
* bitwise or, 'x | y'
* @return {Node} node
* @private
*/
function parseBitwiseOr() {
var node = parseBitwiseXor();
while (token == '|') {
getTokenSkipNewline();
node = new OperatorNode('|', 'bitOr', [node, parseBitwiseXor()]);
}
return node;
}
/**
* bitwise exclusive or (xor), 'x ^| y'
* @return {Node} node
* @private
*/
function parseBitwiseXor() {
var node = parseBitwiseAnd();
while (token == '^|') {
getTokenSkipNewline();
node = new OperatorNode('^|', 'bitXor', [node, parseBitwiseAnd()]);
}
return node;
}
/**
* bitwise and, 'x & y'
* @return {Node} node
* @private
*/
function parseBitwiseAnd () {
var node = parseRelational();
while (token == '&') {
getTokenSkipNewline();
node = new OperatorNode('&', 'bitAnd', [node, parseRelational()]);
}
return node;
}
/**
* relational operators
* @return {Node} node
* @private
*/
function parseRelational () {
var node, operators, name, fn, params;
node = parseShift();
operators = {
'==': 'equal',
'!=': 'unequal',
'<': 'smaller',
'>': 'larger',
'<=': 'smallerEq',
'>=': 'largerEq'
};
while (operators.hasOwnProperty(token)) {
name = token;
fn = operators[name];
getTokenSkipNewline();
params = [node, parseShift()];
node = new OperatorNode(name, fn, params);
}
return node;
}
/**
* Bitwise left shift, bitwise right arithmetic shift, bitwise right logical shift
* @return {Node} node
* @private
*/
function parseShift () {
var node, operators, name, fn, params;
node = parseConversion();
operators = {
'<<' : 'leftShift',
'>>' : 'rightArithShift',
'>>>' : 'rightLogShift'
};
while (operators.hasOwnProperty(token)) {
name = token;
fn = operators[name];
getTokenSkipNewline();
params = [node, parseConversion()];
node = new OperatorNode(name, fn, params);
}
return node;
}
/**
* conversion operators 'to' and 'in'
* @return {Node} node
* @private
*/
function parseConversion () {
var node, operators, name, fn, params;
node = parseRange();
operators = {
'to' : 'to',
'in' : 'to' // alias of 'to'
};
while (operators.hasOwnProperty(token)) {
name = token;
fn = operators[name];
getTokenSkipNewline();
if (name === 'in' && token === '') {
// end of expression -> this is the unit 'in' ('inch')
node = new OperatorNode('*', 'multiply', [node, new SymbolNode('in')], true);
}
else {
// operator 'a to b' or 'a in b'
params = [node, parseRange()];
node = new OperatorNode(name, fn, params);
}
}
return node;
}
/**
* parse range, "start:end", "start:step:end", ":", "start:", ":end", etc
* @return {Node} node
* @private
*/
function parseRange () {
var node, params = [];
if (token == ':') {
// implicit start=1 (one-based)
node = new ConstantNode('1', 'number');
}
else {
// explicit start
node = parseAddSubtract();
}
if (token == ':' && (conditional_level !== nesting_level)) {
// we ignore the range operator when a conditional operator is being processed on the same level
params.push(node);
// parse step and end
while (token == ':' && params.length < 3) {
getTokenSkipNewline();
if (token == ')' || token == ']' || token == ',' || token == '') {
// implicit end
params.push(new SymbolNode('end'));
}
else {
// explicit end
params.push(parseAddSubtract());
}
}
if (params.length == 3) {
// params = [start, step, end]
node = new RangeNode(params[0], params[2], params[1]); // start, end, step
}
else { // length == 2
// params = [start, end]
node = new RangeNode(params[0], params[1]); // start, end
}
}
return node;
}
/**
* add or subtract
* @return {Node} node
* @private
*/
function parseAddSubtract () {
var node, operators, name, fn, params;
node = parseMultiplyDivide();
operators = {
'+': 'add',
'-': 'subtract'
};
while (operators.hasOwnProperty(token)) {
name = token;
fn = operators[name];
getTokenSkipNewline();
params = [node, parseMultiplyDivide()];
node = new OperatorNode(name, fn, params);
}
return node;
}
/**
* multiply, divide, modulus
* @return {Node} node
* @private
*/
function parseMultiplyDivide () {
var node, last, operators, name, fn;
node = parseUnary();
last = node;
operators = {
'*': 'multiply',
'.*': 'dotMultiply',
'/': 'divide',
'./': 'dotDivide',
'%': 'mod',
'mod': 'mod'
};
while (true) {
if (operators.hasOwnProperty(token)) {
// explicit operators
name = token;
fn = operators[name];
getTokenSkipNewline();
last = parseUnary();
node = new OperatorNode(name, fn, [node, last]);
}
else if ((token_type === TOKENTYPE.SYMBOL) ||
(token === 'in' && type.isConstantNode(node)) ||
(token_type === TOKENTYPE.NUMBER &&
!type.isConstantNode(last) &&
(!type.isOperatorNode(last) || last.op === '!')) ||
(token === '(')) {
// parse implicit multiplication
//
// symbol: implicit multiplication like '2a', '(2+3)a', 'a b'
// number: implicit multiplication like '(2+3)2'
// parenthesis: implicit multiplication like '2(3+4)', '(3+4)(1+2)'
last = parseUnary();
node = new OperatorNode('*', 'multiply', [node, last], true /*implicit*/);
}
else {
break;
}
}
return node;
}
/**
* Unary plus and minus, and logical and bitwise not
* @return {Node} node
* @private
*/
function parseUnary () {
var name, params, fn;
var operators = {
'-': 'unaryMinus',
'+': 'unaryPlus',
'~': 'bitNot',
'not': 'not'
};
if (operators.hasOwnProperty(token)) {
fn = operators[token];
name = token;
getTokenSkipNewline();
params = [parseUnary()];
return new OperatorNode(name, fn, params);
}
return parsePow();
}
/**
* power
* Note: power operator is right associative
* @return {Node} node
* @private
*/
function parsePow () {
var node, name, fn, params;
node = parseLeftHandOperators();
if (token == '^' || token == '.^') {
name = token;
fn = (name == '^') ? 'pow' : 'dotPow';
getTokenSkipNewline();
params = [node, parseUnary()]; // Go back to unary, we can have '2^-3'
node = new OperatorNode(name, fn, params);
}
return node;
}
/**
* Left hand operators: factorial x!, transpose x'
* @return {Node} node
* @private
*/
function parseLeftHandOperators () {
var node, operators, name, fn, params;
node = parseCustomNodes();
operators = {
'!': 'factorial',
'\'': 'transpose'
};
while (operators.hasOwnProperty(token)) {
name = token;
fn = operators[name];
getToken();
params = [node];
node = new OperatorNode(name, fn, params);
node = parseAccessors(node);
}
return node;
}
/**
* Parse a custom node handler. A node handler can be used to process
* nodes in a custom way, for example for handling a plot.
*
* A handler must be passed as second argument of the parse function.
* - must extend math.expression.node.Node
* - must contain a function _compile(defs: Object) : string
* - must contain a function find(filter: Object) : Node[]
* - must contain a function toString() : string
* - the constructor is called with a single argument containing all parameters
*
* For example:
*
* nodes = {
* 'plot': PlotHandler
* };
*
* The constructor of the handler is called as:
*
* node = new PlotHandler(params);
*
* The handler will be invoked when evaluating an expression like:
*
* node = math.parse('plot(sin(x), x)', nodes);
*
* @return {Node} node
* @private
*/
function parseCustomNodes () {
var params = [];
if (token_type == TOKENTYPE.SYMBOL && extra_nodes.hasOwnProperty(token)) {
var CustomNode = extra_nodes[token];
getToken();
// parse parameters
if (token == '(') {
params = [];
openParams();
getToken();
if (token != ')') {
params.push(parseAssignment());
// parse a list with parameters
while (token == ',') {
getToken();
params.push(parseAssignment());
}
}
if (token != ')') {
throw createSyntaxError('Parenthesis ) expected');
}
closeParams();
getToken();
}
// create a new custom node
//noinspection JSValidateTypes
return new CustomNode(params);
}
return parseSymbol();
}
/**
* parse symbols: functions, variables, constants, units
* @return {Node} node
* @private
*/
function parseSymbol () {
var node, name;
if (token_type == TOKENTYPE.SYMBOL ||
(token_type == TOKENTYPE.DELIMITER && token in NAMED_DELIMITERS)) {
name = token;
getToken();
// parse function parameters and matrix index
node = new SymbolNode(name);
node = parseAccessors(node);
return node;
}
return parseString();
}
/**
* parse accessors:
* - function invocation in round brackets (...), for example sqrt(2)
* - index enclosed in square brackets [...], for example A[2,3]
* - dot notation for properties, like foo.bar
* @param {Node} node Node on which to apply the parameters. If there
* are no parameters in the expression, the node
* itself is returned
* @param {string[]} [types] Filter the types of notations
* can be ['(', '[', '.']
* @return {Node} node
* @private
*/
function parseAccessors (node, types) {
var params;
while ((token === '(' || token === '[' || token === '.') &&
(!types || types.indexOf(token) !== -1)) {
params = [];
if (token === '(') {
if (type.isSymbolNode(node) || type.isAccessorNode(node) || type.isFunctionNode(node)) {
// function invocation like fn(2, 3)
openParams();
getToken();
if (token !== ')') {
params.push(parseAssignment());
// parse a list with parameters
while (token === ',') {
getToken();
params.push(parseAssignment());
}
}
if (token !== ')') {
throw createSyntaxError('Parenthesis ) expected');
}
closeParams();
getToken();
node = new FunctionNode(node, params);
}
else {
// implicit multiplication like (2+3)(4+5)
// don't parse it here but let it be handled by parseMultiplyDivide
// with correct precedence
return node;
}
}
else if (token === '[') {
// index notation like variable[2, 3]
openParams();
getToken();
if (token !== ']') {
params.push(parseAssignment());
// parse a list with parameters
while (token === ',') {
getToken();
params.push(parseAssignment());
}
}
if (token !== ']') {
throw createSyntaxError('Parenthesis ] expected');
}
closeParams();
getToken();
node = new AccessorNode(node, new IndexNode(params));
}
else {
// dot notation like variable.prop
getToken();
if (token_type !== TOKENTYPE.SYMBOL) {
throw createSyntaxError('Property name expected after dot');
}
params.push(new ConstantNode(token));
getToken();
var dotNotation = true;
node = new AccessorNode(node, new IndexNode(params, dotNotation));
}
}
return node;
}
/**
* parse a string.
* A string is enclosed by double quotes
* @return {Node} node
* @private
*/
function parseString () {
var node, str;
if (token == '"') {
str = parseStringToken();
// create constant
node = new ConstantNode(str, 'string');
// parse index parameters
node = parseAccessors(node);
return node;
}
return parseMatrix();
}
/**
* Parse a string surrounded by double quotes "..."
* @return {string}
*/
function parseStringToken () {
var str = '';
while (c != '' && c != '\"') {
if (c == '\\') {
// escape character
str += c;
next();
}
str += c;
next();
}
getToken();
if (token != '"') {
throw createSyntaxError('End of string " expected');
}
getToken();
return str;
}
/**
* parse the matrix
* @return {Node} node
* @private
*/
function parseMatrix () {
var array, params, rows, cols;
if (token == '[') {
// matrix [...]
openParams();
getToken();
if (token != ']') {
// this is a non-empty matrix
var row = parseRow();
if (token == ';') {
// 2 dimensional array
rows = 1;
params = [row];
// the rows of the matrix are separated by dot-comma's
while (token == ';') {
getToken();
params[rows] = parseRow();
rows++;
}
if (token != ']') {
throw createSyntaxError('End of matrix ] expected');
}
closeParams();
getToken();
// check if the number of columns matches in all rows
cols = params[0].items.length;
for (var r = 1; r < rows; r++) {
if (params[r].items.length != cols) {
throw createError('Column dimensions mismatch ' +
'(' + params[r].items.length + ' != ' + cols + ')');
}
}
array = new ArrayNode(params);
}
else {
// 1 dimensional vector
if (token != ']') {
throw createSyntaxError('End of matrix ] expected');
}
closeParams();
getToken();
array = row;
}
}
else {
// this is an empty matrix "[ ]"
closeParams();
getToken();
array = new ArrayNode([]);
}
return parseAccessors(array);
}
return parseObject();
}
/**
* Parse a single comma-separated row from a matrix, like 'a, b, c'
* @return {ArrayNode} node
*/
function parseRow () {
var params = [parseAssignment()];
var len = 1;
while (token == ',') {
getToken();
// parse expression
params[len] = parseAssignment();
len++;
}
return new ArrayNode(params);
}
/**
* parse an object, enclosed in angle brackets{...}, for example {value: 2}
* @return {Node} node
* @private
*/
function parseObject () {
if (token == '{') {
var key;
var properties = {};
do {
getToken();
if (token != '}') {
// parse key
if (token == '"') {
key = parseStringToken();
}
else if (token_type == TOKENTYPE.SYMBOL) {
key = token;
getToken();
}
else {
throw createSyntaxError('Symbol or string expected as object key');
}
// parse key/value separator
if (token != ':') {
throw createSyntaxError('Colon : expected after object key');
}
getToken();
// parse key
properties[key] = parseAssignment();
}
}
while (token == ',');
if (token != '}') {
throw createSyntaxError('Comma , or bracket } expected after object value');
}
getToken();
var node = new ObjectNode(properties);
// parse index parameters
node = parseAccessors(node);
return node;
}
return parseNumber();
}
/**
* parse a number
* @return {Node} node
* @private
*/
function parseNumber () {
var number;
if (token_type == TOKENTYPE.NUMBER) {
// this is a number
number = token;
getToken();
return new ConstantNode(number, 'number');
}
return parseParentheses();
}
/**
* parentheses
* @return {Node} node
* @private
*/
function parseParentheses () {
var node;
// check if it is a parenthesized expression
if (token == '(') {
// parentheses (...)
openParams();
getToken();
node = parseAssignment(); // start again
if (token != ')') {
throw createSyntaxError('Parenthesis ) expected');
}
closeParams();
getToken();
node = new ParenthesisNode(node);
node = parseAccessors(node);
return node;
}
return parseEnd();
}
/**
* Evaluated when the expression is not yet ended but expected to end
* @return {Node} res
* @private
*/
function parseEnd () {
if (token == '') {
// syntax error or unexpected end of expression
throw createSyntaxError('Unexpected end of expression');
} else if (token === "'") {
throw createSyntaxError('Value expected. Note: strings must be enclosed by double quotes');
} else {
throw createSyntaxError('Value expected');
}
}
/**
* Shortcut for getting the current row value (one based)
* Returns the line of the currently handled expression
* @private
*/
/* TODO: implement keeping track on the row number
function row () {
return null;
}
*/
/**
* Shortcut for getting the current col value (one based)
* Returns the column (position) where the last token starts
* @private
*/
function col () {
return index - token.length + 1;
}
/**
* Create an error
* @param {string} message
* @return {SyntaxError} instantiated error
* @private
*/
function createSyntaxError (message) {
var c = col();
var error = new SyntaxError(message + ' (char ' + c + ')');
error['char'] = c;
return error;
}
/**
* Create an error
* @param {string} message
* @return {Error} instantiated error
* @private
*/
function createError (message) {
var c = col();
var error = new SyntaxError(message + ' (char ' + c + ')');
error['char'] = c;
return error;
}
return parse;
}
exports.name = 'parse';
exports.path = 'expression';
exports.factory = factory;