node_modules/node-firefox-forward-ports/node_modules/adbkit/node_modules/node-forge/js/pem.js - cordova-firefoxos - Git at Google

 /**
  * Javascript implementation of basic PEM (Privacy Enhanced Mail) algorithms.
  *
  * See: RFC 1421.
  *
  * @author Dave Longley
  *
  * Copyright (c) 2013-2014 Digital Bazaar, Inc.
  *
  * A Forge PEM object has the following fields:
  *
  * type: identifies the type of message (eg: "RSA PRIVATE KEY").
  *
  * procType: identifies the type of processing performed on the message,
  *   it has two subfields: version and type, eg: 4,ENCRYPTED.
  *
  * contentDomain: identifies the type of content in the message, typically
  *   only uses the value: "RFC822".
  *
  * dekInfo: identifies the message encryption algorithm and mode and includes
  *   any parameters for the algorithm, it has two subfields: algorithm and
  *   parameters, eg: DES-CBC,F8143EDE5960C597.
  *
  * headers: contains all other PEM encapsulated headers -- where order is
  *   significant (for pairing data like recipient ID + key info).
  *
  * body: the binary-encoded body.
  */
 (function() {
 /* ########## Begin module implementation ########## */
 function initModule(forge) {

 // shortcut for pem API
 var pem = forge.pem = forge.pem || {};

 /**
  * Encodes (serializes) the given PEM object.
  *
  * @param msg the PEM message object to encode.
  * @param options the options to use:
  *          maxline the maximum characters per line for the body, (default: 64).
  *
  * @return the PEM-formatted string.
  */
 pem.encode = function(msg, options) {
   options = options || {};
   var rval = '-----BEGIN ' + msg.type + '-----\r\n';

   // encode special headers
   var header;
   if(msg.procType) {
     header = {
       name: 'Proc-Type',
       values: [String(msg.procType.version), msg.procType.type]
     };
     rval += foldHeader(header);
   }
   if(msg.contentDomain) {
     header = {name: 'Content-Domain', values: [msg.contentDomain]};
     rval += foldHeader(header);
   }
   if(msg.dekInfo) {
     header = {name: 'DEK-Info', values: [msg.dekInfo.algorithm]};
     if(msg.dekInfo.parameters) {
       header.values.push(msg.dekInfo.parameters);
     }
     rval += foldHeader(header);
   }

   if(msg.headers) {
     // encode all other headers
     for(var i = 0; i < msg.headers.length; ++i) {
       rval += foldHeader(msg.headers[i]);
     }
   }

   // terminate header
   if(msg.procType) {
     rval += '\r\n';
   }

   // add body
   rval += forge.util.encode64(msg.body, options.maxline || 64) + '\r\n';

   rval += '-----END ' + msg.type + '-----\r\n';
   return rval;
 };

 /**
  * Decodes (deserializes) all PEM messages found in the given string.
  *
  * @param str the PEM-formatted string to decode.
  *
  * @return the PEM message objects in an array.
  */
 pem.decode = function(str) {
   var rval = [];

   // split string into PEM messages (be lenient w/EOF on BEGIN line)
   var rMessage = /\s*-----BEGIN ([A-Z0-9- ]+)-----\r?\n?([\x21-\x7e\s]+?(?:\r?\n\r?\n))?([:A-Za-z0-9+\/=\s]+?)-----END \1-----/g;
   var rHeader = /([\x21-\x7e]+):\s*([\x21-\x7e\s^:]+)/;
   var rCRLF = /\r?\n/;
   var match;
   while(true) {
     match = rMessage.exec(str);
     if(!match) {
       break;
     }

     var msg = {
       type: match[1],
       procType: null,
       contentDomain: null,
       dekInfo: null,
       headers: [],
       body: forge.util.decode64(match[3])
     };
     rval.push(msg);

     // no headers
     if(!match[2]) {
       continue;
     }

     // parse headers
     var lines = match[2].split(rCRLF);
     var li = 0;
     while(match && li < lines.length) {
       // get line, trim any rhs whitespace
       var line = lines[li].replace(/\s+$/, '');

       // RFC2822 unfold any following folded lines
       for(var nl = li + 1; nl < lines.length; ++nl) {
         var next = lines[nl];
         if(!/\s/.test(next[0])) {
           break;
         }
         line += next;
         li = nl;
       }

       // parse header
       match = line.match(rHeader);
       if(match) {
         var header = {name: match[1], values: []};
         var values = match[2].split(',');
         for(var vi = 0; vi < values.length; ++vi) {
           header.values.push(ltrim(values[vi]));
         }

         // Proc-Type must be the first header
         if(!msg.procType) {
           if(header.name !== 'Proc-Type') {
             throw new Error('Invalid PEM formatted message. The first ' +
               'encapsulated header must be "Proc-Type".');
           } else if(header.values.length !== 2) {
             throw new Error('Invalid PEM formatted message. The "Proc-Type" ' +
               'header must have two subfields.');
           }
           msg.procType = {version: values[0], type: values[1]};
         } else if(!msg.contentDomain && header.name === 'Content-Domain') {
           // special-case Content-Domain
           msg.contentDomain = values[0] || '';
         } else if(!msg.dekInfo && header.name === 'DEK-Info') {
           // special-case DEK-Info
           if(header.values.length === 0) {
             throw new Error('Invalid PEM formatted message. The "DEK-Info" ' +
               'header must have at least one subfield.');
           }
           msg.dekInfo = {algorithm: values[0], parameters: values[1] || null};
         } else {
           msg.headers.push(header);
         }
       }

       ++li;
     }

     if(msg.procType === 'ENCRYPTED' && !msg.dekInfo) {
       throw new Error('Invalid PEM formatted message. The "DEK-Info" ' +
         'header must be present if "Proc-Type" is "ENCRYPTED".');
     }
   }

   if(rval.length === 0) {
     throw new Error('Invalid PEM formatted message.');
   }

   return rval;
 };

 function foldHeader(header) {
   var rval = header.name + ': ';

   // ensure values with CRLF are folded
   var values = [];
   var insertSpace = function(match, $1) {
     return ' ' + $1;
   };
   for(var i = 0; i < header.values.length; ++i) {
     values.push(header.values[i].replace(/^(\S+\r\n)/, insertSpace));
   }
   rval += values.join(',') + '\r\n';

   // do folding
   var length = 0;
   var candidate = -1;
   for(var i = 0; i < rval.length; ++i, ++length) {
     if(length > 65 && candidate !== -1) {
       var insert = rval[candidate];
       if(insert === ',') {
         ++candidate;
         rval = rval.substr(0, candidate) + '\r\n ' + rval.substr(candidate);
       } else {
         rval = rval.substr(0, candidate) +
           '\r\n' + insert + rval.substr(candidate + 1);
       }
       length = (i - candidate - 1);
       candidate = -1;
       ++i;
     } else if(rval[i] === ' ' || rval[i] === '\t' || rval[i] === ',') {
       candidate = i;
     }
   }

   return rval;
 }

 function ltrim(str) {
   return str.replace(/^\s+/, '');
 }

 } // end module implementation

 /* ########## Begin module wrapper ########## */
 var name = 'pem';
 if(typeof define !== 'function') {
   // NodeJS -> AMD
   if(typeof module === 'object' && module.exports) {
     var nodeJS = true;
     define = function(ids, factory) {
       factory(require, module);
     };
   } else {
     // <script>
     if(typeof forge === 'undefined') {
       forge = {};
     }
     return initModule(forge);
   }
 }
 // AMD
 var deps;
 var defineFunc = function(require, module) {
   module.exports = function(forge) {
     var mods = deps.map(function(dep) {
       return require(dep);
     }).concat(initModule);
     // handle circular dependencies
     forge = forge || {};
     forge.defined = forge.defined || {};
     if(forge.defined[name]) {
       return forge[name];
     }
     forge.defined[name] = true;
     for(var i = 0; i < mods.length; ++i) {
       mods[i](forge);
     }
     return forge[name];
   };
 };
 var tmpDefine = define;
 define = function(ids, factory) {
   deps = (typeof ids === 'string') ? factory.slice(2) : ids.slice(2);
   if(nodeJS) {
     delete define;
     return tmpDefine.apply(null, Array.prototype.slice.call(arguments, 0));
   }
   define = tmpDefine;
   return define.apply(null, Array.prototype.slice.call(arguments, 0));
 };
 define(['require', 'module', './util'], function() {
   defineFunc.apply(null, Array.prototype.slice.call(arguments, 0));
 });
 })();
	/**
	* Javascript implementation of basic PEM (Privacy Enhanced Mail) algorithms.
	*
	* See: RFC 1421.
	*
	* @author Dave Longley
	*
	* Copyright (c) 2013-2014 Digital Bazaar, Inc.
	*
	* A Forge PEM object has the following fields:
	*
	* type: identifies the type of message (eg: "RSA PRIVATE KEY").
	*
	* procType: identifies the type of processing performed on the message,
	* it has two subfields: version and type, eg: 4,ENCRYPTED.
	*
	* contentDomain: identifies the type of content in the message, typically
	* only uses the value: "RFC822".
	*
	* dekInfo: identifies the message encryption algorithm and mode and includes
	* any parameters for the algorithm, it has two subfields: algorithm and
	* parameters, eg: DES-CBC,F8143EDE5960C597.
	*
	* headers: contains all other PEM encapsulated headers -- where order is
	* significant (for pairing data like recipient ID + key info).
	*
	* body: the binary-encoded body.
	*/
	(function() {
	/* ########## Begin module implementation ########## */
	function initModule(forge) {

	// shortcut for pem API
	var pem = forge.pem = forge.pem \|\| {};

	/**
	* Encodes (serializes) the given PEM object.
	*
	* @param msg the PEM message object to encode.
	* @param options the options to use:
	* maxline the maximum characters per line for the body, (default: 64).
	*
	* @return the PEM-formatted string.
	*/
	pem.encode = function(msg, options) {
	options = options \|\| {};
	var rval = '-----BEGIN ' + msg.type + '-----\r\n';

	// encode special headers
	var header;
	if(msg.procType) {
	header = {
	name: 'Proc-Type',
	values: [String(msg.procType.version), msg.procType.type]
	};
	rval += foldHeader(header);
	}
	if(msg.contentDomain) {
	header = {name: 'Content-Domain', values: [msg.contentDomain]};
	rval += foldHeader(header);
	}
	if(msg.dekInfo) {
	header = {name: 'DEK-Info', values: [msg.dekInfo.algorithm]};
	if(msg.dekInfo.parameters) {
	header.values.push(msg.dekInfo.parameters);
	}
	rval += foldHeader(header);
	}

	if(msg.headers) {
	// encode all other headers
	for(var i = 0; i < msg.headers.length; ++i) {
	rval += foldHeader(msg.headers[i]);
	}
	}

	// terminate header
	if(msg.procType) {
	rval += '\r\n';
	}

	// add body
	rval += forge.util.encode64(msg.body, options.maxline \|\| 64) + '\r\n';

	rval += '-----END ' + msg.type + '-----\r\n';
	return rval;
	};

	/**
	* Decodes (deserializes) all PEM messages found in the given string.
	*
	* @param str the PEM-formatted string to decode.
	*
	* @return the PEM message objects in an array.
	*/
	pem.decode = function(str) {
	var rval = [];

	// split string into PEM messages (be lenient w/EOF on BEGIN line)
	var rMessage = /\s*-----BEGIN ([A-Z0-9- ]+)-----\r?\n?([\x21-\x7e\s]+?(?:\r?\n\r?\n))?([:A-Za-z0-9+\/=\s]+?)-----END \1-----/g;
	var rHeader = /([\x21-\x7e]+):\s*([\x21-\x7e\s^:]+)/;
	var rCRLF = /\r?\n/;
	var match;
	while(true) {
	match = rMessage.exec(str);
	if(!match) {
	break;
	}

	var msg = {
	type: match[1],
	procType: null,
	contentDomain: null,
	dekInfo: null,
	headers: [],
	body: forge.util.decode64(match[3])
	};
	rval.push(msg);

	// no headers
	if(!match[2]) {
	continue;
	}

	// parse headers
	var lines = match[2].split(rCRLF);
	var li = 0;
	while(match && li < lines.length) {
	// get line, trim any rhs whitespace
	var line = lines[li].replace(/\s+$/, '');

	// RFC2822 unfold any following folded lines
	for(var nl = li + 1; nl < lines.length; ++nl) {
	var next = lines[nl];
	if(!/\s/.test(next[0])) {
	break;
	}
	line += next;
	li = nl;
	}

	// parse header
	match = line.match(rHeader);
	if(match) {
	var header = {name: match[1], values: []};
	var values = match[2].split(',');
	for(var vi = 0; vi < values.length; ++vi) {
	header.values.push(ltrim(values[vi]));
	}

	// Proc-Type must be the first header
	if(!msg.procType) {
	if(header.name !== 'Proc-Type') {
	throw new Error('Invalid PEM formatted message. The first ' +
	'encapsulated header must be "Proc-Type".');
	} else if(header.values.length !== 2) {
	throw new Error('Invalid PEM formatted message. The "Proc-Type" ' +
	'header must have two subfields.');
	}
	msg.procType = {version: values[0], type: values[1]};
	} else if(!msg.contentDomain && header.name === 'Content-Domain') {
	// special-case Content-Domain
	msg.contentDomain = values[0] \|\| '';
	} else if(!msg.dekInfo && header.name === 'DEK-Info') {
	// special-case DEK-Info
	if(header.values.length === 0) {
	throw new Error('Invalid PEM formatted message. The "DEK-Info" ' +
	'header must have at least one subfield.');
	}
	msg.dekInfo = {algorithm: values[0], parameters: values[1] \|\| null};
	} else {
	msg.headers.push(header);
	}
	}

	++li;
	}

	if(msg.procType === 'ENCRYPTED' && !msg.dekInfo) {
	throw new Error('Invalid PEM formatted message. The "DEK-Info" ' +
	'header must be present if "Proc-Type" is "ENCRYPTED".');
	}
	}

	if(rval.length === 0) {
	throw new Error('Invalid PEM formatted message.');
	}

	return rval;
	};

	function foldHeader(header) {
	var rval = header.name + ': ';

	// ensure values with CRLF are folded
	var values = [];
	var insertSpace = function(match, $1) {
	return ' ' + $1;
	};
	for(var i = 0; i < header.values.length; ++i) {
	values.push(header.values[i].replace(/^(\S+\r\n)/, insertSpace));
	}
	rval += values.join(',') + '\r\n';

	// do folding
	var length = 0;
	var candidate = -1;
	for(var i = 0; i < rval.length; ++i, ++length) {
	if(length > 65 && candidate !== -1) {
	var insert = rval[candidate];
	if(insert === ',') {
	++candidate;
	rval = rval.substr(0, candidate) + '\r\n ' + rval.substr(candidate);
	} else {
	rval = rval.substr(0, candidate) +
	'\r\n' + insert + rval.substr(candidate + 1);
	}
	length = (i - candidate - 1);
	candidate = -1;
	++i;
	} else if(rval[i] === ' ' \|\| rval[i] === '\t' \|\| rval[i] === ',') {
	candidate = i;
	}
	}

	return rval;
	}

	function ltrim(str) {
	return str.replace(/^\s+/, '');
	}

	} // end module implementation

	/* ########## Begin module wrapper ########## */
	var name = 'pem';
	if(typeof define !== 'function') {
	// NodeJS -> AMD
	if(typeof module === 'object' && module.exports) {
	var nodeJS = true;
	define = function(ids, factory) {
	factory(require, module);
	};
	} else {
	// <script>
	if(typeof forge === 'undefined') {
	forge = {};
	}
	return initModule(forge);
	}
	}
	// AMD
	var deps;
	var defineFunc = function(require, module) {
	module.exports = function(forge) {
	var mods = deps.map(function(dep) {
	return require(dep);
	}).concat(initModule);
	// handle circular dependencies
	forge = forge \|\| {};
	forge.defined = forge.defined \|\| {};
	if(forge.defined[name]) {
	return forge[name];
	}
	forge.defined[name] = true;
	for(var i = 0; i < mods.length; ++i) {
	mods[i](forge);
	}
	return forge[name];
	};
	};
	var tmpDefine = define;
	define = function(ids, factory) {
	deps = (typeof ids === 'string') ? factory.slice(2) : ids.slice(2);
	if(nodeJS) {
	delete define;
	return tmpDefine.apply(null, Array.prototype.slice.call(arguments, 0));
	}
	define = tmpDefine;
	return define.apply(null, Array.prototype.slice.call(arguments, 0));
	};
	define(['require', 'module', './util'], function() {
	defineFunc.apply(null, Array.prototype.slice.call(arguments, 0));
	});
	})();