cacert-testmgr/external/ZendFramework-1.9.5/externals/dojo/dojox/lang/functional/multirec.js

dojo.provide("dojox.lang.functional.multirec");

dojo.require("dojox.lang.functional.lambda");
dojo.require("dojox.lang.functional.util");

// This module provides recursion combinators:
//	- a multi-way recursion combinator.

// Acknoledgements:
//	- recursion combinators are inspired by Manfred von Thun's article
//		"Recursion Theory and Joy"
//		(http://www.latrobe.edu.au/philosophy/phimvt/joy/j05cmp.html)

// Notes:
//	- recursion combinators produce a function, which implements
//	their respective recusion patterns. String lambdas are inlined, if possible.

(function(){
	var df = dojox.lang.functional, inline = df.inlineLambda,
		_x ="_x", _y_r_y_o = ["_y.r", "_y.o"];

	df.multirec = function(
					/*Function|String|Array*/ cond,
					/*Function|String|Array*/ then,
					/*Function|String|Array*/ before,
					/*Function|String|Array*/ after){
		// summary:
		//		Generates a function for the multi-way recursion pattern.
		//		All parameter functions are called in the context of "this" object.
		// cond:
		//		The lambda expression, which is used to detect the termination of recursion.
		//		It accepts the same parameter as the generated recursive function itself.
		//		This function should return "true", if the recursion should be stopped,
		//		and the "then" part should be executed. Otherwise the recursion will proceed.
		// then:
		//		The lambda expression, which is called upon termination of the recursion.
		//		It accepts the same parameters as the generated recursive function itself.
		//		The returned value will be returned as the value of the generated function.
		// before:
		//		The lambda expression, which is called before the recursive step.
		//		It accepts the same parameter as the generated recursive function itself.
		//		The returned value should be an array, which is used to call
		//		the generated function recursively. Each member of the array should be
		//		an array of parameters. The length of it defines how many times
		//		the generated function is called recursively.
		// above:
		//		The lambda expression, which is called after the recursive step.
		//		It accepts two parameters: the array of returned values from recursive steps,
		//		and the original array of parameters used with all other functions.
		//		The returned value will be returned as the value of the generated function.

		var c, t, b, a, cs, ts, bs, as, dict1 = {}, dict2 = {},
			add2dict = function(x){ dict1[x] = 1; };
		if(typeof cond == "string"){
			cs = inline(cond, _x, add2dict);
		}else{
			c = df.lambda(cond);
			cs = "_c.apply(this, _x)";
			dict2["_c=_t.c"] = 1;
		}
		if(typeof then == "string"){
			ts = inline(then, _x, add2dict);
		}else{
			t = df.lambda(then);
			ts = "_t.apply(this, _x)";
		}
		if(typeof before == "string"){
			bs = inline(before, _x, add2dict);
		}else{
			b = df.lambda(before);
			bs = "_b.apply(this, _x)";
			dict2["_b=_t.b"] = 1;
		}
		if(typeof after == "string"){
			as = inline(after, _y_r_y_o, add2dict);
		}else{
			a = df.lambda(after);
			as = "_a.call(this, _y.r, _y.o)";
			dict2["_a=_t.a"] = 1;
		}
		var locals1 = df.keys(dict1), locals2 = df.keys(dict2),
			f = new Function([], "var _y={a:arguments},_x,_r,_z,_i".concat(	// Function
				locals1.length ? "," + locals1.join(",") : "",
				locals2.length ? ",_t=arguments.callee," + locals2.join(",") : "",
				t ? (locals2.length ? ",_t=_t.t" : "_t=arguments.callee.t") : "",
				";for(;;){for(;;){if(_y.o){_r=",
				as,
				";break}_x=_y.a;if(",
				cs,
				"){_r=",
				ts,
				";break}_y.o=_x;_x=",
				bs,
				";_y.r=[];_z=_y;for(_i=_x.length-1;_i>=0;--_i){_y={p:_y,a:_x[_i],z:_z}}}if(!(_z=_y.z)){return _r}_z.r.push(_r);_y=_y.p}"
			));
		if(c){ f.c = c; }
		if(t){ f.t = t; }
		if(b){ f.b = b; }
		if(a){ f.a = a; }
		return f;
	};
})();

/*
For documentation only:

1) The original recursive version:

var multirec1 = function(cond, then, before, after){
	var cond   = df.lambda(cond),
		then   = df.lambda(then),
		before = df.lambda(before),
		after  = df.lambda(after);
	return function(){
		if(cond.apply(this, arguments)){
			return then.apply(this, arguments);
		}
		var args = before.apply(this, arguments),
			ret  = new Array(args.length);
		for(var i = 0; i < args.length; ++i){
			ret[i] = arguments.callee.apply(this, args[i]);
		}
		return after.call(this, ret, arguments);
	};
};

2) The original iterative version (before minification and inlining):

var multirec2 = function(cond, then, before, after){
	var cond   = df.lambda(cond),
		then   = df.lambda(then),
		before = df.lambda(before),
		after  = df.lambda(after);
	return function(){
		var top = {args: arguments}, args, ret, parent, i;
		for(;;){
			for(;;){
				if(top.old){
					ret = after.call(this, top.ret, top.old);
					break;
				}
				args = top.args;
				if(cond.apply(this, args)){
					ret = then.apply(this, args);
					break;
				}
				top.old = args;
				args = before.apply(this, args);
				top.ret = [];
				parent = top;
				for(i = args.length - 1; i >= 0; --i){
					top = {prev: top, args: args[i], parent: parent};
				}
			}
			if(!(parent = top.parent)){
				return ret;
			}
			parent.ret.push(ret);
			top = top.prev;
		}
	};
};

*/
initially import ZendFramework-1.9.5 into repository code was modified slightly, so the code differs from the original downloadable 1.9.5 version 15 years ago			`dojo.provide("dojox.lang.functional.multirec");`

			`dojo.require("dojox.lang.functional.lambda");`
			`dojo.require("dojox.lang.functional.util");`

			`// This module provides recursion combinators:`
			`// - a multi-way recursion combinator.`

			`// Acknoledgements:`
			`// - recursion combinators are inspired by Manfred von Thun's article`
			`// "Recursion Theory and Joy"`
			`// (http://www.latrobe.edu.au/philosophy/phimvt/joy/j05cmp.html)`

			`// Notes:`
			`// - recursion combinators produce a function, which implements`
			`// their respective recusion patterns. String lambdas are inlined, if possible.`

			`(function(){`
			`var df = dojox.lang.functional, inline = df.inlineLambda,`
			`_x ="_x", _y_r_y_o = ["_y.r", "_y.o"];`

			`df.multirec = function(`
			`/Function\|String\|Array/ cond,`
			`/Function\|String\|Array/ then,`
			`/Function\|String\|Array/ before,`
			`/Function\|String\|Array/ after){`
			`// summary:`
			`// Generates a function for the multi-way recursion pattern.`
			`// All parameter functions are called in the context of "this" object.`
			`// cond:`
			`// The lambda expression, which is used to detect the termination of recursion.`
			`// It accepts the same parameter as the generated recursive function itself.`
			`// This function should return "true", if the recursion should be stopped,`
			`// and the "then" part should be executed. Otherwise the recursion will proceed.`
			`// then:`
			`// The lambda expression, which is called upon termination of the recursion.`
			`// It accepts the same parameters as the generated recursive function itself.`
			`// The returned value will be returned as the value of the generated function.`
			`// before:`
			`// The lambda expression, which is called before the recursive step.`
			`// It accepts the same parameter as the generated recursive function itself.`
			`// The returned value should be an array, which is used to call`
			`// the generated function recursively. Each member of the array should be`
			`// an array of parameters. The length of it defines how many times`
			`// the generated function is called recursively.`
			`// above:`
			`// The lambda expression, which is called after the recursive step.`
			`// It accepts two parameters: the array of returned values from recursive steps,`
			`// and the original array of parameters used with all other functions.`
			`// The returned value will be returned as the value of the generated function.`

			`var c, t, b, a, cs, ts, bs, as, dict1 = {}, dict2 = {},`
			`add2dict = function(x){ dict1[x] = 1; };`
			`if(typeof cond == "string"){`
			`cs = inline(cond, _x, add2dict);`
			`}else{`
			`c = df.lambda(cond);`
			`cs = "_c.apply(this, _x)";`
			`dict2["_c=_t.c"] = 1;`
			`}`
			`if(typeof then == "string"){`
			`ts = inline(then, _x, add2dict);`
			`}else{`
			`t = df.lambda(then);`
			`ts = "_t.apply(this, _x)";`
			`}`
			`if(typeof before == "string"){`
			`bs = inline(before, _x, add2dict);`
			`}else{`
			`b = df.lambda(before);`
			`bs = "_b.apply(this, _x)";`
			`dict2["_b=_t.b"] = 1;`
			`}`
			`if(typeof after == "string"){`
			`as = inline(after, _y_r_y_o, add2dict);`
			`}else{`
			`a = df.lambda(after);`
			`as = "_a.call(this, _y.r, _y.o)";`
			`dict2["_a=_t.a"] = 1;`
			`}`
			`var locals1 = df.keys(dict1), locals2 = df.keys(dict2),`
			`f = new Function([], "var _y={a:arguments},_x,_r,_z,_i".concat( // Function`
			`locals1.length ? "," + locals1.join(",") : "",`
			`locals2.length ? ",_t=arguments.callee," + locals2.join(",") : "",`
			`t ? (locals2.length ? ",_t=_t.t" : "_t=arguments.callee.t") : "",`
			`";for(;;){for(;;){if(_y.o){_r=",`
			`as,`
			`";break}_x=_y.a;if(",`
			`cs,`
			`"){_r=",`
			`ts,`
			`";break}_y.o=_x;_x=",`
			`bs,`
			`";_y.r=[];_z=_y;for(_i=_x.length-1;_i>=0;--_i){_y={p:_y,a:_x[_i],z:_z}}}if(!(_z=_y.z)){return _r}_z.r.push(_r);_y=_y.p}"`
			`));`
			`if(c){ f.c = c; }`
			`if(t){ f.t = t; }`
			`if(b){ f.b = b; }`
			`if(a){ f.a = a; }`
			`return f;`
			`};`
			`})();`

			`/*`
			`For documentation only:`

			`1) The original recursive version:`

			`var multirec1 = function(cond, then, before, after){`
			`var cond = df.lambda(cond),`
			`then = df.lambda(then),`
			`before = df.lambda(before),`
			`after = df.lambda(after);`
			`return function(){`
			`if(cond.apply(this, arguments)){`
			`return then.apply(this, arguments);`
			`}`
			`var args = before.apply(this, arguments),`
			`ret = new Array(args.length);`
			`for(var i = 0; i < args.length; ++i){`
			`ret[i] = arguments.callee.apply(this, args[i]);`
			`}`
			`return after.call(this, ret, arguments);`
			`};`
			`};`

			`2) The original iterative version (before minification and inlining):`

			`var multirec2 = function(cond, then, before, after){`
			`var cond = df.lambda(cond),`
			`then = df.lambda(then),`
			`before = df.lambda(before),`
			`after = df.lambda(after);`
			`return function(){`
			`var top = {args: arguments}, args, ret, parent, i;`
			`for(;;){`
			`for(;;){`
			`if(top.old){`
			`ret = after.call(this, top.ret, top.old);`
			`break;`
			`}`
			`args = top.args;`
			`if(cond.apply(this, args)){`
			`ret = then.apply(this, args);`
			`break;`
			`}`
			`top.old = args;`
			`args = before.apply(this, args);`
			`top.ret = [];`
			`parent = top;`
			`for(i = args.length - 1; i >= 0; --i){`
			`top = {prev: top, args: args[i], parent: parent};`
			`}`
			`}`
			`if(!(parent = top.parent)){`
			`return ret;`
			`}`
			`parent.ret.push(ret);`
			`top = top.prev;`
			`}`
			`};`
			`};`

			`*/`