import { isAccessorNode, isFunctionAssignmentNode, isIndexNode, isNode, isSymbolNode } from '../../utils/is.js';
import { escape, format } from '../../utils/string.js';
import { hasOwnProperty } from '../../utils/object.js';
import { getSafeProperty, validateSafeMethod } from '../../utils/customs.js';
import { createSubScope } from '../../utils/scope.js';
import { factory } from '../../utils/factory.js';
import { defaultTemplate, latexFunctions } from '../../utils/latex.js';
var name = 'FunctionNode';
var dependencies = ['math', 'Node', 'SymbolNode'];
export var createFunctionNode = /* #__PURE__ */factory(name, dependencies, _ref => {
var {
math,
Node,
SymbolNode
} = _ref;
/**
* @constructor FunctionNode
* @extends {./Node}
* invoke a list with arguments on a node
* @param {./Node | string} fn Node resolving with a function on which to invoke
* the arguments, typically a SymboNode or AccessorNode
* @param {./Node[]} args
*/
function FunctionNode(fn, args) {
if (!(this instanceof FunctionNode)) {
throw new SyntaxError('Constructor must be called with the new operator');
}
if (typeof fn === 'string') {
fn = new SymbolNode(fn);
} // validate input
if (!isNode(fn)) throw new TypeError('Node expected as parameter "fn"');
if (!Array.isArray(args) || !args.every(isNode)) {
throw new TypeError('Array containing Nodes expected for parameter "args"');
}
this.fn = fn;
this.args = args || []; // readonly property name
Object.defineProperty(this, 'name', {
get: function () {
return this.fn.name || '';
}.bind(this),
set: function set() {
throw new Error('Cannot assign a new name, name is read-only');
}
});
}
FunctionNode.prototype = new Node();
FunctionNode.prototype.type = 'FunctionNode';
FunctionNode.prototype.isFunctionNode = true;
/* format to fixed length */
var strin = entity => format(entity, {
truncate: 78
});
/**
* Compile a node into a JavaScript function.
* This basically pre-calculates as much as possible and only leaves open
* calculations which depend on a dynamic scope with variables.
* @param {Object} math Math.js namespace with functions and constants.
* @param {Object} argNames An object with argument names as key and `true`
* as value. Used in the SymbolNode to optimize
* for arguments from user assigned functions
* (see FunctionAssignmentNode) or special symbols
* like `end` (see IndexNode).
* @return {function} Returns a function which can be called like:
* evalNode(scope: Object, args: Object, context: *)
*/
FunctionNode.prototype._compile = function (math, argNames) {
if (!(this instanceof FunctionNode)) {
throw new TypeError('No valid FunctionNode');
} // compile arguments
var evalArgs = this.args.map(arg => arg._compile(math, argNames));
if (isSymbolNode(this.fn)) {
var _name = this.fn.name;
if (!argNames[_name]) {
// we can statically determine whether the function has an rawArgs property
var fn = _name in math ? getSafeProperty(math, _name) : undefined;
var isRaw = typeof fn === 'function' && fn.rawArgs === true;
var resolveFn = scope => {
var value;
if (scope.has(_name)) {
value = scope.get(_name);
} else if (_name in math) {
value = getSafeProperty(math, _name);
} else {
return FunctionNode.onUndefinedFunction(_name);
}
if (typeof value === 'function') {
return value;
}
throw new TypeError("'".concat(_name, "' is not a function; its value is:\n ").concat(strin(value)));
};
if (isRaw) {
// pass unevaluated parameters (nodes) to the function
// "raw" evaluation
var rawArgs = this.args;
return function evalFunctionNode(scope, args, context) {
var fn = resolveFn(scope);
return fn(rawArgs, math, createSubScope(scope, args), scope);
};
} else {
// "regular" evaluation
switch (evalArgs.length) {
case 0:
return function evalFunctionNode(scope, args, context) {
var fn = resolveFn(scope);
return fn();
};
case 1:
return function evalFunctionNode(scope, args, context) {
var fn = resolveFn(scope);
var evalArg0 = evalArgs[0];
return fn(evalArg0(scope, args, context));
};
case 2:
return function evalFunctionNode(scope, args, context) {
var fn = resolveFn(scope);
var evalArg0 = evalArgs[0];
var evalArg1 = evalArgs[1];
return fn(evalArg0(scope, args, context), evalArg1(scope, args, context));
};
default:
return function evalFunctionNode(scope, args, context) {
var fn = resolveFn(scope);
var values = evalArgs.map(evalArg => evalArg(scope, args, context));
return fn(...values);
};
}
}
} else {
// the function symbol is an argName
var _rawArgs = this.args;
return function evalFunctionNode(scope, args, context) {
var fn = args[_name];
if (typeof fn !== 'function') {
throw new TypeError("Argument '".concat(_name, "' was not a function; received: ").concat(strin(fn)));
}
if (fn.rawArgs) {
return fn(_rawArgs, math, createSubScope(scope, args), scope); // "raw" evaluation
} else {
var values = evalArgs.map(evalArg => evalArg(scope, args, context));
return fn.apply(fn, values);
}
};
}
} else if (isAccessorNode(this.fn) && isIndexNode(this.fn.index) && this.fn.index.isObjectProperty()) {
// execute the function with the right context: the object of the AccessorNode
var evalObject = this.fn.object._compile(math, argNames);
var prop = this.fn.index.getObjectProperty();
var _rawArgs2 = this.args;
return function evalFunctionNode(scope, args, context) {
var object = evalObject(scope, args, context);
validateSafeMethod(object, prop);
var isRaw = object[prop] && object[prop].rawArgs;
if (isRaw) {
return object[prop](_rawArgs2, math, createSubScope(scope, args), scope); // "raw" evaluation
} else {
// "regular" evaluation
var values = evalArgs.map(evalArg => evalArg(scope, args, context));
return object[prop].apply(object, values);
}
};
} else {
// node.fn.isAccessorNode && !node.fn.index.isObjectProperty()
// we have to dynamically determine whether the function has a rawArgs property
var fnExpr = this.fn.toString();
var evalFn = this.fn._compile(math, argNames);
var _rawArgs3 = this.args;
return function evalFunctionNode(scope, args, context) {
var fn = evalFn(scope, args, context);
if (typeof fn !== 'function') {
throw new TypeError("Expression '".concat(fnExpr, "' did not evaluate to a function; value is:") + "\n ".concat(strin(fn)));
}
if (fn.rawArgs) {
return fn(_rawArgs3, math, createSubScope(scope, args), scope); // "raw" evaluation
} else {
// "regular" evaluation
var values = evalArgs.map(evalArg => evalArg(scope, args, context));
return fn.apply(fn, values);
}
};
}
};
/**
* Execute a callback for each of the child nodes of this node
* @param {function(child: Node, path: string, parent: Node)} callback
*/
FunctionNode.prototype.forEach = function (callback) {
callback(this.fn, 'fn', this);
for (var i = 0; i < this.args.length; i++) {
callback(this.args[i], 'args[' + i + ']', this);
}
};
/**
* Create a new FunctionNode having it's childs be the results of calling
* the provided callback function for each of the childs of the original node.
* @param {function(child: Node, path: string, parent: Node): Node} callback
* @returns {FunctionNode} Returns a transformed copy of the node
*/
FunctionNode.prototype.map = function (callback) {
var fn = this._ifNode(callback(this.fn, 'fn', this));
var args = [];
for (var i = 0; i < this.args.length; i++) {
args[i] = this._ifNode(callback(this.args[i], 'args[' + i + ']', this));
}
return new FunctionNode(fn, args);
};
/**
* Create a clone of this node, a shallow copy
* @return {FunctionNode}
*/
FunctionNode.prototype.clone = function () {
return new FunctionNode(this.fn, this.args.slice(0));
};
/**
* Throws an error 'Undefined function {name}'
* @param {string} name
*/
FunctionNode.onUndefinedFunction = function (name) {
throw new Error('Undefined function ' + name);
}; // backup Node's toString function
// @private
var nodeToString = FunctionNode.prototype.toString;
/**
* Get string representation. (wrapper function)
* This overrides parts of Node's toString function.
* If callback is an object containing callbacks, it
* calls the correct callback for the current node,
* otherwise it falls back to calling Node's toString
* function.
*
* @param {Object} options
* @return {string} str
* @override
*/
FunctionNode.prototype.toString = function (options) {
var customString;
var name = this.fn.toString(options);
if (options && typeof options.handler === 'object' && hasOwnProperty(options.handler, name)) {
// callback is a map of callback functions
customString = options.handler[name](this, options);
}
if (typeof customString !== 'undefined') {
return customString;
} // fall back to Node's toString
return nodeToString.call(this, options);
};
/**
* Get string representation
* @param {Object} options
* @return {string} str
*/
FunctionNode.prototype._toString = function (options) {
var args = this.args.map(function (arg) {
return arg.toString(options);
});
var fn = isFunctionAssignmentNode(this.fn) ? '(' + this.fn.toString(options) + ')' : this.fn.toString(options); // format the arguments like "add(2, 4.2)"
return fn + '(' + args.join(', ') + ')';
};
/**
* Get a JSON representation of the node
* @returns {Object}
*/
FunctionNode.prototype.toJSON = function () {
return {
mathjs: 'FunctionNode',
fn: this.fn,
args: this.args
};
};
/**
* Instantiate an AssignmentNode from its JSON representation
* @param {Object} json An object structured like
* `{"mathjs": "FunctionNode", fn: ..., args: ...}`,
* where mathjs is optional
* @returns {FunctionNode}
*/
FunctionNode.fromJSON = function (json) {
return new FunctionNode(json.fn, json.args);
};
/**
* Get HTML representation
* @param {Object} options
* @return {string} str
*/
FunctionNode.prototype.toHTML = function (options) {
var args = this.args.map(function (arg) {
return arg.toHTML(options);
}); // format the arguments like "add(2, 4.2)"
return '' + escape(this.fn) + '(' + args.join(',') + ')';
};
/*
* Expand a LaTeX template
*
* @param {string} template
* @param {Node} node
* @param {Object} options
* @private
**/
function expandTemplate(template, node, options) {
var latex = ''; // Match everything of the form ${identifier} or ${identifier[2]} or $$
// while submatching identifier and 2 (in the second case)
var regex = /\$(?:\{([a-z_][a-z_0-9]*)(?:\[([0-9]+)\])?\}|\$)/gi;
var inputPos = 0; // position in the input string
var match;
while ((match = regex.exec(template)) !== null) {
// go through all matches
// add everything in front of the match to the LaTeX string
latex += template.substring(inputPos, match.index);
inputPos = match.index;
if (match[0] === '$$') {
// escaped dollar sign
latex += '$';
inputPos++;
} else {
// template parameter
inputPos += match[0].length;
var property = node[match[1]];
if (!property) {
throw new ReferenceError('Template: Property ' + match[1] + ' does not exist.');
}
if (match[2] === undefined) {
// no square brackets
switch (typeof property) {
case 'string':
latex += property;
break;
case 'object':
if (isNode(property)) {
latex += property.toTex(options);
} else if (Array.isArray(property)) {
// make array of Nodes into comma separated list
latex += property.map(function (arg, index) {
if (isNode(arg)) {
return arg.toTex(options);
}
throw new TypeError('Template: ' + match[1] + '[' + index + '] is not a Node.');
}).join(',');
} else {
throw new TypeError('Template: ' + match[1] + ' has to be a Node, String or array of Nodes');
}
break;
default:
throw new TypeError('Template: ' + match[1] + ' has to be a Node, String or array of Nodes');
}
} else {
// with square brackets
if (isNode(property[match[2]] && property[match[2]])) {
latex += property[match[2]].toTex(options);
} else {
throw new TypeError('Template: ' + match[1] + '[' + match[2] + '] is not a Node.');
}
}
}
}
latex += template.slice(inputPos); // append rest of the template
return latex;
} // backup Node's toTex function
// @private
var nodeToTex = FunctionNode.prototype.toTex;
/**
* Get LaTeX representation. (wrapper function)
* This overrides parts of Node's toTex function.
* If callback is an object containing callbacks, it
* calls the correct callback for the current node,
* otherwise it falls back to calling Node's toTex
* function.
*
* @param {Object} options
* @return {string}
*/
FunctionNode.prototype.toTex = function (options) {
var customTex;
if (options && typeof options.handler === 'object' && hasOwnProperty(options.handler, this.name)) {
// callback is a map of callback functions
customTex = options.handler[this.name](this, options);
}
if (typeof customTex !== 'undefined') {
return customTex;
} // fall back to Node's toTex
return nodeToTex.call(this, options);
};
/**
* Get LaTeX representation
* @param {Object} options
* @return {string} str
*/
FunctionNode.prototype._toTex = function (options) {
var args = this.args.map(function (arg) {
// get LaTeX of the arguments
return arg.toTex(options);
});
var latexConverter;
if (latexFunctions[this.name]) {
latexConverter = latexFunctions[this.name];
} // toTex property on the function itself
if (math[this.name] && (typeof math[this.name].toTex === 'function' || typeof math[this.name].toTex === 'object' || typeof math[this.name].toTex === 'string')) {
// .toTex is a callback function
latexConverter = math[this.name].toTex;
}
var customToTex;
switch (typeof latexConverter) {
case 'function':
// a callback function
customToTex = latexConverter(this, options);
break;
case 'string':
// a template string
customToTex = expandTemplate(latexConverter, this, options);
break;
case 'object':
// an object with different "converters" for different numbers of arguments
switch (typeof latexConverter[args.length]) {
case 'function':
customToTex = latexConverter[args.length](this, options);
break;
case 'string':
customToTex = expandTemplate(latexConverter[args.length], this, options);
break;
}
}
if (typeof customToTex !== 'undefined') {
return customToTex;
}
return expandTemplate(defaultTemplate, this, options);
};
/**
* Get identifier.
* @return {string}
*/
FunctionNode.prototype.getIdentifier = function () {
return this.type + ':' + this.name;
};
return FunctionNode;
}, {
isClass: true,
isNode: true
});