carto/lib/less/parser.js

844 lines
27 KiB
JavaScript

if (typeof(require) !== 'undefined') {
var less = exports || {};
var tree = require('less/tree');
}
//
// less.js - parser
//
// A relatively straight-forward recursive-descent parser.
// There is no tokenization/lexing stage, the input is parsed
// in one sweep.
//
// To make the parser fast enough to run in the browser, several
// optimization had to be made:
//
// - Instead of the more commonly used technique of slicing the
// input string on every match, we use global regexps (/g),
// and move the `lastIndex` pointer on match, foregoing `slice()`
// completely. This gives us a 3x speed-up.
//
// - Matching on a huge input is often cause of slowdowns,
// especially with the /g flag. The solution to that is to
// chunkify the input: we split it by /\n\n/, just to be on
// the safe side. The chunks are stored in the `chunks` var,
// `j` holds the current chunk index, and `current` holds
// the index of the current chunk in relation to `input`.
// This gives us an almost 4x speed-up.
//
// - In many cases, we don't need to match individual tokens;
// for example, if a value doesn't hold any variables, operations
// or dynamic references, the parser can effectively 'skip' it,
// treating it as a literal.
// An example would be '1px solid #000' - which evaluates to itself,
// we don't need to know what the individual components are.
// The drawback, of course is that you don't get the benefits of
// syntax-checking on the CSS. This gives us a 50% speed-up in the parser,
// and a smaller speed-up in the code-gen.
//
//
// Token matching is done with the `$` function, which either takes
// a terminal string or regexp, or a non-terminal function to call.
// It also takes care of moving all the indices forwards.
//
//
var input, // LeSS input string
i, // current index in `input`
j, // current chunk
chunks, // chunkified input
current, // index of current chunk, in `input`
inputLength;
//
// Parse from a token, regexp or string, and move forward if match
//
function $(tok) {
var match, args, length, c, index, endIndex;
//
// Non-terminal
//
if (tok instanceof Function) {
return tok.call(less.parser.parsers);
//
// Terminal
//
// Either match a single character in the input,
// or match a regexp in the current chunk (chunk[j]).
//
} else if (typeof(tok) === 'string') {
match = input[i] === tok ? tok : null;
length = 1;
// 1. We move to the next chunk, if necessary.
// 2. Set the `lastIndex` to be relative
// to the current chunk, and try to match in it.
// 3. Make sure we matched at `index`. Because we use
// the /g flag, the match could be anywhere in the
// chunk. We have to make sure it's at our previous
// index, which we stored in [2].
//
} else {
if (i >= current + chunks[j].length &&
j < chunks.length - 1) { // 1.
current += chunks[j++].length;
}
tok.lastIndex = index = i - current; // 2.
match = tok.exec(chunks[j]);
if (match) {
length = match[0].length;
if (tok.lastIndex - length !== index) { return } // 3.
}
}
// The match is confirmed, add the match length to `i`,
// and consume any extra white-space characters (' ' || '\n')
// which come after that. The reason for this is that LeSS's
// grammar is mostly white-space insensitive.
//
if (match) {
i += length;
endIndex = current + chunks[j].length;
while (i <= endIndex) {
c = input.charCodeAt(i);
if (! (c === 32 || c === 10 || c === 9)) { break }
i++;
}
return match.length === 1 ? match[0] : match;
}
}
// Same as $(), but don't change the state of the parser,
// just return the match.
function peek(tok) {
var match;
if (typeof(tok) === 'string') {
return input[i] === tok;
} else {
tok.lastIndex = i;
if ((match = tok.exec(input)) &&
(tok.lastIndex - match[0].length === i)) {
return match;
}
}
}
//
// The Parser
//
less.parser = {
// The optimization level dictates the thoroughness of the parser,
// the lower the number, the less nodes it will create in the tree.
// This could matter for debugging, or if you want to access
// the individual nodes in the tree.
optimization: 2,
//
// Parse an input string into an abstract syntax tree,
// call `callback` when done.
//
parse: function (str, callback) {
var root, start, end, zone, line, buff = [], c, error = null;
i = j = current = 0;
chunks = [];
input = str.replace(/\r\n/g, '\n');
inputLength = input.length;
// Split the input into chunks,
// Either delimited by /\n\n/ or
// delmited by '\n}' (see rationale above),
// depending on the level of optimization.
if (this.optimization > 0) {
if (this.optimization > 2) {
input = input.replace(/\/\*(?:[^*]|\*+[^\/*])*\*+\//g, '');
chunks = input.split(/^(?=\n)/mg);
} else {
for (var k = 0; k < input.length; k++) {
if ((c = input.charAt(k)) === '}' && input.charCodeAt(k - 1) === 10) {
chunks.push(buff.concat('}').join(''));
buff = [];
} else {
buff.push(c);
}
}
chunks.push(buff.join(''));
}
} else {
chunks = [input];
}
// Start with the primary rule.
// The whole syntax tree is held under a Ruleset node,
// with the `root` property set to true, so no `{}` are
// output.
root = new(tree.Ruleset)([], $(this.parsers.primary));
root.root = true;
// If `i` is smaller than the `input.length - 1`,
// it means the parser wasn't able to parse the whole
// string, so we've got a parsing error.
//
// We try to extract a \n delimited string,
// showing the line where the parse error occured.
// We split it up into two parts (the part which parsed,
// and the part which didn't), so we can color them differently.
if (i < input.length - 1) {
start = (function () {
for (var n = i; n > 0; n--) {
if (input[n] === '\n') { break }
}
return n;
})() + 1;
line = (input.slice(0, i).match(/\n/g) || "").length + 1;
end = input.slice(i).indexOf('\n') + i;
zone = stylize(input.slice(start, i), 'green') +
stylize(stylize(input[i], 'inverse') +
input.slice(i + 1, end),'yellow') + '\033[0m\n';
error = { name: "ParseError", message: "Parse Error on line " + line + ":\n" + zone };
}
callback(error, root);
},
//
// Here in, the parsing rules/functions
//
// The basic structure of the syntax tree generated is as follows:
//
// Ruleset -> Rule -> Value -> Expression -> Entity
//
// Here's some LESS code:
//
// .class {
// color: #fff;
// border: 1px solid #000;
// width: @w + 4px;
// > .child {...}
// }
//
// And here's what the parse tree might look like:
//
// Ruleset (Selector '.class', [
// Rule ("color", Value ([Expression [Color #fff]]))
// Rule ("border", Value ([Expression [Dimension 1px][Keyword "solid"][Color #000]]))
// Rule ("width", Value ([Expression [Operation "+" [Variable "@w"][Dimension 4px]]]))
// Ruleset (Selector [Element '>', '.child'], [...])
// ])
//
// In general, most rules will try to parse a token with the `$()` function, and if the return
// value is truly, will return a new node, of the relevant type. Sometimes, we need to check
// first, before parsing, that's when we use `peek()`.
//
parsers: {
//
// The `primary` rule is the *entry* and *exit* point of the parser.
// The rules here can appear at any level of the parse tree.
//
// The recursive nature of the grammar is an interplay between the `block`
// rule, which represents `{ ... }`, the `ruleset` rule, and this `primary` rule,
// as represented by this simplified grammar:
//
// primary → (ruleset | rule)+
// ruleset → selector+ block
// block → '{' primary '}'
//
// Only at one point is the primary rule not called from the
// block rule: at the root level.
//
primary: function () {
var node, root = [];
while (node = $(this.mixin.definition) || $(this.ruleset) || $(this.rule) ||
$(this.mixin.call) || $(this.comment) ||
$(/[\n\s]+/g) || $(this.directive)) {
root.push(node);
}
return root;
},
// We create a Comment node for CSS comments `/* */`,
// but keep the LeSS comments `//` silent, by just skipping
// over them.
comment: function () {
var comment;
if (input[i] !== '/') return;
if (comment = $(/\/\*(?:[^*]|\*+[^\/*])*\*+\/\n?/g)) {
return new(tree.Comment)(comment);
} else {
return $(/\/\/.*/g);
}
},
//
// Entities are tokens which can be found inside an Expression
//
entities: {
//
// A string, which supports escaping " and '
//
// "milky way" 'he\'s the one!'
//
quoted: function () {
var str;
if (input[i] !== '"' && input[i] !== "'") return;
if (str = $(/"((?:[^"\\\r\n]|\\.)*)"|'((?:[^'\\\r\n]|\\.)*)'/g)) {
return new(tree.Quoted)(str[0], str[1] || str[2]);
}
},
//
// A catch-all word, such as:
//
// black border-collapse
//
keyword: function () {
var k;
if (k = $(/[A-Za-z-]+/g)) { return new(tree.Keyword)(k) }
},
//
// A function call
//
// rgb(255, 0, 255)
//
// We also try to catch IE's `alpha()`, but let the `alpha` parser
// deal with the details.
//
// The arguments are parsed with the `entities.arguments` parser.
//
call: function () {
var name, args;
if (! (name = $(/([a-zA-Z0-9_-]+)\(/g))) return;
if (name[1].toLowerCase() === 'alpha') { return $(this.alpha) }
args = $(this.entities.arguments);
if (! $(')')) return;
if (name) { return new(tree.Call)(name[1], args) }
},
arguments: function () {
var args = [], arg;
while (arg = $(this.expression)) {
args.push(arg);
if (! $(',')) { break }
}
return args;
},
literal: function () {
return $(this.entities.dimension) ||
$(this.entities.color) ||
$(this.entities.quoted);
},
//
// Parse url() tokens
//
// We use a specific rule for urls, because they don't really behave like
// standard function calls. The difference is that the argument doesn't have
// to be enclosed within a string, so it can't be parsed as an Expression.
//
url: function () {
var value;
if (input[i] !== 'u' || !$(/url\(/g)) return;
value = $(this.entities.quoted) || $(/[-a-zA-Z0-9_%@$\/.&=:;#+?]+/g);
if (! $(')')) throw new(Error)("missing closing ) for url()");
return new(tree.URL)(value);
},
//
// A Variable entity, such as `@fink`, in
//
// width: @fink + 2px
//
// We use a different parser for variable definitions,
// see `parsers.variable`.
//
variable: function () {
var name;
if (input[i] === '@' && (name = $(/@[a-zA-Z0-9_-]+/g))) {
return new(tree.Variable)(name);
}
},
//
// A Hexadecimal color
//
// #4F3C2F
//
// `rgb` and `hsl` colors are parsed through the `entities.call` parser.
//
color: function () {
var rgb;
if (input[i] === '#' && (rgb = $(/#([a-fA-F0-9]{6}|[a-fA-F0-9]{3})/g))) {
return new(tree.Color)(rgb[1]);
}
},
//
// A Dimension, that is, a number and a unit
//
// 0.5em 95%
//
dimension: function () {
var value, c = input.charCodeAt(i);
if ((c > 57 || c < 45) || c === 47) return;
if (value = $(/(-?[0-9]*\.?[0-9]+)(px|%|em|pc|ex|in|deg|s|ms|pt|cm|mm)?/g)) {
return new(tree.Dimension)(value[1], value[2]);
}
}
},
//
// The variable part of a variable definition. Used in the `rule` parser
//
// @fink:
//
variable: function () {
var name;
if (input[i] === '@' && (name = $(/(@[a-zA-Z0-9_-]+)\s*:/g))) { return name[1] }
},
//
// A font size/line-height shorthand
//
// small/12px
//
// We need to peek first, or we'll match on keywords and dimensions
//
shorthand: function () {
var a, b;
if (! peek(/[@\w.-]+\/[@\w.-]+/g)) return;
if ((a = $(this.entity)) && $('/') && (b = $(this.entity))) {
return new(tree.Shorthand)(a, b);
}
},
//
// Mixins
//
mixin: {
//
// A Mixin call, with an optional argument list
//
// #mixins > .square(#fff);
// .rounded(4px, black);
// .button;
//
// The `while` loop is there because mixins can be
// namespaced, but we only support the child and descendant
// selector for now.
//
call: function () {
var elements = [], e, c, args;
while (e = $(/[#.]?[a-zA-Z0-9_-]+/g)) {
elements.push(new(tree.Element)(c, e));
c = $('>');
}
$('(') && (args = $(this.entities.arguments)) && $(')');
if (elements.length > 0 && ($(';') || peek('}'))) {
return new(tree.mixin.Call)(elements, args);
}
},
//
// A Mixin definition, with a list of parameters
//
// .rounded (@radius: 2px, @color) {
// ...
// }
//
// Until we have a finer grained state-machine, we have to
// do a look-ahead, to make sure we don't have a mixin call.
// See the `rule` function for more information.
//
// We start by matching `.rounded (`, and then proceed on to
// the argument list, which has optional default values.
// We store the parameters in `params`, with a `value` key,
// if there is a value, such as in the case of `@radius`.
//
// Once we've got our params list, and a closing `)`, we parse
// the `{...}` block.
//
definition: function () {
var name, params = [], match, ruleset, param, value;
if (input[i] !== '.' || peek(/[^{]*(;|})/g)) return;
if (match = $(/([#.][a-zA-Z0-9_-]+)\s*\(/g)) {
name = match[1];
while (param = $(/@[\w-]+/g)) {
if ($(':')) {
if (value = $(this.expression)) {
params.push({ name: param, value: value });
} else {
throw new(Error)("Expected value");
}
} else {
params.push({ name: param });
}
if (! $(',')) { break }
}
if (! $(')')) throw new(Error)("Expected )");
ruleset = $(this.block);
if (ruleset) {
return new(tree.mixin.Definition)(name, params, ruleset);
}
}
}
},
//
// Entities are the smallest recognized token,
// and can be found inside a rule's value.
//
entity: function () {
return $(this.entities.literal) || $(this.entities.variable) || $(this.entities.url) ||
$(this.entities.call) || $(this.entities.keyword);
},
//
// A Rule terminator. Note that we use `peek()` to check for '}',
// because the `block` rule will be expecting it, but we still need to make sure
// it's there, if ';' was ommitted.
//
end: function () {
return $(';') || peek('}');
},
//
// IE's alpha function
//
// alpha(opacity=88)
//
alpha: function () {
var value;
if (! $(/opacity=/gi)) return;
if (value = $(/[0-9]+/g) || $(this.entities.variable)) {
if (! $(')')) throw new(Error)("missing closing ) for alpha()");
return new(tree.Alpha)(value);
}
},
//
// A Selector Element
//
// div
// + h1
// #socks
// input[type="text"]
//
// Elements are the building blocks for Selectors,
// they are made out of a `Combinator` (see combinator rule),
// and an element name, such as a tag a class, or `*`.
//
element: function () {
var e, t;
c = $(this.combinator);
e = $(/[.#:]?[a-zA-Z0-9_-]+/g) || $('*') || $(this.attribute) || $(/\([^)@]+\)/g);
if (e) { return new(tree.Element)(c, e) }
},
//
// Combinators combine elements together, in a Selector.
//
// Because our parser isn't white-space sensitive, special care
// has to be taken, when parsing the descendant combinator, ` `,
// as it's an empty space. We have to check the previous character
// in the input, to see if it's a ` ` character. More info on how
// we deal with this in *combinator.js*.
//
combinator: function () {
var match;
if (match = $(/[+>~]/g) || $('&') || $(/::/g)) {
return new(tree.Combinator)(match);
} else {
return new(tree.Combinator)(input[i - 1] === " " ? " " : null);
}
},
//
// A CSS Selector
//
// .class > div + h1
// li a:hover
//
// Selectors are made out of one or more Elements, see above.
//
selector: function () {
var sel, e, elements = [], match;
while (e = $(this.element)) { elements.push(e) }
if (elements.length > 0) { return new(tree.Selector)(elements) }
},
tag: function () {
return $(/[a-zA-Z][a-zA-Z-]*[0-9]?/g) || $('*');
},
attribute: function () {
var attr = '', key, val, op;
if (! $('[')) return;
if (key = $(/[a-z]+/g) || $(this.entities.quoted)) {
if ((op = $(/[|~*$^]?=/g)) &&
(val = $(this.entities.quoted) || $(/[\w-]+/g))) {
attr = [key, op, val.toCSS ? val.toCSS() : val].join('');
} else { attr = key }
}
if (! $(']')) return;
if (attr) { return "[" + attr + "]" }
},
//
// The `block` rule is used by `ruleset` and `mixin.definition`.
// It's a wrapper around the `primary` rule, with added `{}`.
//
block: function () {
var content;
if ($('{') && (content = $(this.primary)) && $('}')) {
return content;
}
},
//
// div, .class, body > p {...}
//
ruleset: function () {
var selectors = [], s, rules, match;
if (peek(/[^{]+[@;}]/g)) return;
if (match = peek(/([a-z.#: _-]+)[\s\n]*\{/g)) {
i += match[0].length - 1;
selectors = [new(tree.Selector)([new(tree.Element)(null, match[1])])];
} else {
while (s = $(this.selector)) {
selectors.push(s);
if (! $(',')) { break }
}
if (s) $(this.comment);
}
rules = $(this.block);
if (selectors.length > 0 && rules) {
return new(tree.Ruleset)(selectors, rules);
}
},
rule: function () {
var value;
if (name = $(this.property) || $(this.variable)) {
if ((name[0] != '@') && (match = peek(/([^@+\/*(;{}-]*);/g))) {
i += match[0].length - 1;
value = match[1];
} else if (name === "font") {
value = $(this.font);
} else {
value = $(this.value);
}
if ($(this.end)) {
return new(tree.Rule)(name, value);
}
}
},
//
// An @import directive
//
// @import "lib";
//
// Depending on our environemnt, importing is done differently:
// In the browser, it's an XHR request, in Node, it would be a
// file-system operation. The function used for importing is
// stored in `less.import`, which we pass to the Import constructor.
//
import: function () {
var path;
if ($(/@import\s+/) &&
(path = $(this.entities.quoted) || $(this.entities.url)) &&
$(';')) {
return new(tree.Import)(path, less.import);
}
},
//
// A CSS Directive
//
// @charset "utf-8";
//
directive: function () {
var name, value, rules, types;
if (input[i] !== '@') return;
if (value = $(this.import)) {
return value;
} else if (name = $(/@media|@page/g)) {
types = $(/[a-z:, ]+/g).trim();
if (rules = $(this.block)) {
return new(tree.Directive)(name + " " + types, rules);
}
} else if (name = $(/@[-a-z]+/g)) {
if (name === '@font-face') {
if (rules = $(this.block)) {
return new(tree.Directive)(name, rules);
}
} else if ((value = $(this.entity)) && $(';')) {
return new(tree.Directive)(name, value);
}
}
},
font: function () {
var value = [], expression = [], weight, shorthand, font, e;
while (e = $(this.shorthand) || $(this.entity)) {
expression.push(e);
}
value.push(new(tree.Expression)(expression));
if ($(',')) {
while (e = $(this.expression)) {
value.push(e);
if (! $(',')) { break }
}
}
return new(tree.Value)(value, $(this.important));
},
//
// A Value is a comma-delimited list of Expressions
//
// font-family: Baskerville, Georgia, serif;
//
// In a Rule, a Value represents everything after the `:`,
// and before the `;`.
//
value: function () {
var e, expressions = [], important;
while (e = $(this.expression)) {
expressions.push(e);
if (! $(',')) { break }
}
important = $(this.important);
if (expressions.length > 0) {
return new(tree.Value)(expressions, important);
}
},
important: function () {
return $(/!\s*important/g);
},
sub: function () {
var e;
if ($('(') && (e = $(this.expression)) && $(')')) {
return e;
}
},
multiplication: function () {
var m, a, op;
if (m = $(this.operand)) {
if ((op = $(/[\/*]/g)) && (a = $(this.multiplication))) {
return new(tree.Operation)(op, [m, a]);
} else {
return m;
}
}
},
addition: function () {
var m, a, op;
if (m = $(this.multiplication)) {
if ((op = $(/[-+]\s+/g) || (input[i - 1] != ' ' && $(/[-+]/g))) &&
(a = $(this.addition))) {
return new(tree.Operation)(op, [m, a]);
} else {
return m;
}
}
},
//
// An operand is anything that can be part of an operation,
// such as a Color, or a Variable
//
operand: function () {
return $(this.sub) || $(this.entities.dimension) ||
$(this.entities.color) || $(this.entities.variable);
},
//
// Expressions either represent mathematical operations,
// or white-space delimited Entities.
//
// 1px solid black
// @var * 2
//
expression: function () {
var e, delim, entities = [], d;
while (e = $(this.addition) || $(this.entity)) {
entities.push(e);
}
if (entities.length > 0) {
return new(tree.Expression)(entities);
}
},
property: function () {
var name;
if (name = $(/(\*?-?[-a-z]+)\s*:/g)) {
return name[1];
}
}
}
};
// Stylize a string
function stylize(str, style) {
var styles = {
'bold' : [1, 22],
'inverse' : [7, 27],
'underline' : [4, 24],
'yellow' : [33, 39],
'green' : [32, 39],
'red' : [31, 39]
};
return '\033[' + styles[style][0] + 'm' + str +
'\033[' + styles[style][1] + 'm';
}