Network Working Group D. Eastlake 3rd Request for Comments: 1898 CyberCash Category: Informational B. Boesch CyberCash S. Crocker CyberCash M. Yesil CyberCash February 1996 CyberCash Credit Card Protocol Version 0.8 Status of this Memo This memo provides information for the Internet community. This memo does not specify an Internet standard of any kind. Distribution of this memo is unlimited. Abstract CyberCash is developing a general payments system for use over the Internet. The structure and communications protocols of version 0.8 are described. This version includes credit card payments only. Additional capabilities are planned for future versions. This document covers only the current CyberCash system which is one of the few operational systems in the rapidly evolving area of Internet payments. CyberCash is committed to the further development of its system and to cooperation with the Internet Engineering Task Force and other standards organizations. Acknowledgements The significant contributions of the following persons (in alphabetic order) to this protocol are gratefully acknowledged: Bruce Binder, Judith Grass, Alden Hart, Steve Kiser, Steve Klebe, Garry Knox, Tom Lee, Bob Lindenberg, Jim Lum, Bill Melton, Denise Paredes, Prasad Chintamaneni, Fred Silverman, Bruce Wilson, Garland Wong, Wei Wu, Mark Zalewski. In addition, Jeff Stapleton and Peter Wagner made useful comments on the first version of this memo. Eastlake, et al Informational [Page 1] RFC 1898 CyberCash Version 0.8 February 1996 History For historic purposes, it should be noted that this document was first posted as an Internet draft, and thus made publicly available, on 8 July 1995. Table of Contents 1. Overall System..........................................3 1.1 System Overview........................................3 1.2 Security Approach......................................5 1.2.1 Authentication and Persona Identity..................5 1.2.2 Privacy..............................................6 1.3 Credit Card Operation..................................6 2. General Message Wrapper Format..........................7 2.1 Message Format.........................................7 2.2 Details of Format......................................8 2.3 Body Parts.............................................8 2.4 Transparent Part.......................................9 2.5 Opaque Part...........................................10 2.6 Trailer...............................................10 2.7 Example Messages......................................11 3. Signatures and Hashes..................................12 3.1 Digital Signatures....................................12 3.2 Hash Codes............................................13 4. Specific Message Formats...............................13 4.1 Persona Registration and Application Retrieval........14 4.1.1 R1 - registration...................................14 4.1.2 R2 - registration-response..........................15 4.1.3 GA1 - get-application...............................16 4.1.4 GA2 - get-application-response......................17 4.2 Binding Credit Cards..................................18 4.2.1 BC1 - bind-credit-card..............................18 4.2.2 BC4 - bind-credit-card-response.....................20 4.3 Customer Credit Card Purchasing Messages..............21 4.3.1 PR1 - payment-request...............................21 4.3.2 CH1 - credit-card-payment...........................23 4.3.3 CH2 - charge-card-response..........................24 4.4 Merchant Credit Card Purchasing Messages..............25 4.4.1 CM1 - auth-only.....................................26 4.4.2 CM2 - auth-capture..................................28 3.4.3 CM3 - post-auth-capture.............................28 4.4.4 CM4 - void..........................................30 4.4.5 CM5 - return........................................32 4.4.6 CM6 - charge-action-response........................32 4.4.7 The MM* Message Series..............................34 4.4.8 CD1 - card-data-request.............................35 4.4.9 CD2 - card-data-response............................37 Eastlake, et al Informational [Page 2] RFC 1898 CyberCash Version 0.8 February 1996 4.5 Utility and Error Messges.............................38 4.5.1 P1 - ping...........................................39 4.5.2 P2 - ping-response..................................39 4.5.3 TQ1 - transaction-query.............................40 4.5.4 TQ2 - transaction-cancel............................41 4.5.5 TQ3 - transaction-response..........................42 4.5.6 UNK1 - unknown-error................................44 4.5.7 DL1 - diagnostic-log................................46 4.5.8 DL2 - merchant-diagnostic-log.......................47 4.6 Table of Messages Described...........................48 5. Future Development.....................................49 5.1 The Credit Card Authorization/Clearance Process.......49 5.2 Lessons Learned.......................................50 6. Security Considerations................................51 References................................................51 Authors' Addresses........................................52 1. Overall System CyberCash, Inc. of Reston, Virginia was founded in August of 1994 to partner with financial institutions and providers of goods and services to deliver a safe, convenient and inexpensive system for making payments on the Internet. The CyberCash approach is based on establishing a trusted link between the new world of cyberspace and the traditional banking world. CyberCash serves as a conduit through which payments can be transported quickly, easily and safely between buyers, sellers and their banks. Significantly - much as it is the real world of commerce - the buyer and seller need not have any prior existing relationship. As a neutral third party whose sole concern is ensuring the delivery of payments from one party to another, CyberCash is the linchpin in delivering spontaneous consumer electronic commerce on the Internet. 1.1 System Overview The CyberCash system will provide several separate payment services on the Internet including credit card and electronic cash. To gain access to CyberCash services, consumers need only a personal computer with a network connection. Similarly, merchants and banks need make only minimal changes to their current operating procedures in order to process CyberCash transactions, enabling them to more quickly integrate safe on-line payments into their existing service offerings. Communications with banks are over existing financial communications networks. Eastlake, et al Informational [Page 3] RFC 1898 CyberCash Version 0.8 February 1996 To get started, consumers download free software from CyberCash on the Internet. This software establishes the electronic link between consumers, merchants and their banks as well as between individuals. To make gaining access to the CyberCash system even easier, CyberCash "PAY" buttons may be incorporated into popular on-line service and software graphical user interfaces so that consumers using these products can easily enter the CyberCash system when they are ready to make payments for goods and services. Consumers need not have any prior relationship with CyberCash to use the CyberCash system. They can easily set up their CyberCash persona on-line. Transactions are automated in that once the consumer enters appropriate information into his own computer, no manual steps are required to process authorization or clearance transactions through the entire system. The consumer need only initiate payment for each transaction by exercising the pay option on an electronic form. Transactions are safe in that they are cryptographicly protected from tampering and modification by eavesdroppers. And they are private in that information about the consumer not relevant to the transaction is not visible to the merchant. +------------+ +------------+ | | | | | Internet | | Internet | | customer +------------+ merchant + | | | / | +------------+ +------------+ / / +------------|-+ | CyberCash | | | server | | +-----+------|-+ | | | | +--------------+------|---------+ | +--------+ +--+-------+ | | | card +-------+ / charge | | | | issuer | | acquirer | | | +--------+ +----------+ | | | | The Banking System | +-------------------------------+ SYSTEM OVERVIEW Eastlake, et al Informational [Page 4] RFC 1898 CyberCash Version 0.8 February 1996 1.2 Security Approach The CyberCash system pays special attention to security issues. It uses encryption technology from the world's leading sources of security technology and is committed over time to employing new security technologies as they emerge. 1.2.1 Authentication and Persona Identity Authentication of messages is based on Public Key encryption as developed by RSA. The CyberCash Server maintains records of the public key associated with every customer and merchant persona. It is thus able to authenticate any information digitally signed by a customer or merchant regardless of the path the data followed on its way to the server. The corresponding private key, which is needed to create such digital signatures, will be held by the customer or merchant and never revealed to other parties. In customer software, the private key is only stored in an encrypted form protected by a passphrase. While the true CyberCash identity of a customer or merchant is recognized by their public/private key pair, such keys are too cumbersome (over 100 hex digits) to be remembered or typed by people. So, the user interface utilizes short alphanumeric ID's selected by the user or merchant for purposes of specifying a persona. CyberCash adds check digits to the requested ID to minimize the chance of accidental wrong persona selection. Persona IDUs are essentially public information. Possession of an persona ID without the corresponding private key is of no benefit in the current system. Individuals or organizations may establish one or more CyberCash customer personas directly with CyberCash. Thus, an individual may have several unrelated CyberCash personas or share a CyberCash persona with other individuals. This approach provides a degree of privacy consistent with Internet presence generally and with cash transactions specifically. However, persona holders who wish to use a credit card for purchases in conjunction with their CyberCash persona must first meet such on-line identification criteria as the card issuing organization requires. Control over a CyberCash persona is normally available only to an entity that possesses the private key for that persona. However, a special provision is made to associate an emergency close out passphrase with a CyberCash persona. On receipt of the emergency close out passphrase, even if received over insecure channels such as a telephone call or ordinary email, CyberCash will suspend activity for the CyberCash persona. This emergency close-out passphrase can be stored separately from and with somewhat less security than the Eastlake, et al Informational [Page 5] RFC 1898 CyberCash Version 0.8 February 1996 private key for the persona since the emergency passphrase can not be used to divert funds to others. This provides some protection against loss or misappropriation of the private key or the passphrase under which the private key in kept encrypted. In the cash system, the emergency close-out passpharase may also transfer the persona balance to a designated bank account. 1.2.2 Privacy Encryption of messages use the Digital Encryption Standard (DES), commonly used in electronic payment systems today. It is planned to superencrypt (i.e., encrypted more than one level) particularly sensitive information, such as PIN numbers, and handle them so that the plain text readable version never exists in the CyberCash system except momentarily, within special purpose secure cryptographic hardware that is part of the server, before being re-encrypted under another key. The processing of card charges through the CyberCash system is organized so that the merchant never learns the customerUs credit card number unless the merchantUs bank chooses to release this information to the merchant or it is required for dispute resolution. In addition, the server maintains no permanent storage of card numbers. They are only present while a transaction involving that card is in progress. These practices greatly reduce the chance of card number misappropriation. 1.3 Credit Card Operation Using the CyberCash system for credit card transactions, once price has been negotiated and the consumer is ready to purchase, the consumer simply clicks on the CyberCash "PAY" button displayed on the merchant interface, which invokes the merchant CyberCash software. The merchant sends the consumer an on-line invoice that includes relevant purchase information which appears on the customerUs screen. (See PR1 message.) The consumer adds his credit card number and other information by simply selecting from a list of credit cards he has registered to his CyberCash persona. All this information is digitally signed by the customer's CyberCash software, encrypted, and passed, along with a hash code of the invoice as seen by the customer, to the merchant. (See CH1 message.) Upon receipt, the merchant adds additional authorization information which is then encrypted, electronically signed by the merchant, and sent to the CyberCash Server. (See CM1 & CM2 messages.) The CyberCash Server can authenticate all the signatures and be sure that the customer and merchant agree on the invoice and charge amount. The CyberCash Server then forwards the relevant information to the Eastlake, et al Informational [Page 6] RFC 1898 CyberCash Version 0.8 February 1996 acquiring bank along with a request on behalf of the merchant for a specific banking operation such as charge authorization. The bank decrypts and then processes the received data as it would normally process a credit card transaction. The bank's response is returned to the CyberCash Server which returns an electronic receipt to the merchant (see CM6 message) part of which the merchant is expected to forward to the customer (see CH2 message). The transaction is complete. 2. General Message Wrapper Format Version 0.8 of the external format for the encoding of CyberCash messages is described below. CyberCash messages are stylized documents for the transmission of financial data over the Internet. While there are numerous schemes for sending information over the Internet (HTTP, SMTP, and others), each is attached to a specific transmission mechanism. Because CyberCash messages will need to travel over each of these media (as well as others) a transmission independent mechanism is needed. 2.1 Message Format CyberCash messages consist of the following components: 1. Header - defines the start of the CyberCash message and includes version information. 2. Transparent Part - contains information that is not private. 3. Opaque Part(s) - contains the financial information in the message and is both privacy protected as well as tamper protected. An opaque part is not present in some messages. When present, the opaque part usually provides tamper protection for the transparent part. 4. Trailer - defines the end of the CyberCash message and includes a check value to enable the receiver to determine that the message has arrived undamaged. Note: this check value is intended only to detect accidental damage to the message, not deliberate tampering. No null characters (zero value) or characters with the eighth bit on are permitted inside a CyberCash message. "Binary" quantities that might have such byte values in them are encoded in base64 as described in RFC 1521. Eastlake, et al Informational [Page 7] RFC 1898 CyberCash Version 0.8 February 1996 2.2 Details of Format The header consists of a single line which looks approximately like this $$-CyberCash-0.8-$$ or like this $$-CyberCash-1.2.3-Extra-$$ It includes a number of fields separated with the minus character "-" 1. "$$" - the literal string with the initial $ in column 1. 2. "CyberCash" - the literal string (case insensitive) 3. x.y or x.y.z - the version number of the message format. x is the primary version number. y is a subversion number. z, if present, is a subsubversion number. 4. "Extra" - an optional additional alphanumeric string. 5. "$$" - the literal string Version numbers start at 0.7 and count up. The ".z" is omitted when z is zero. 0.7 and 0.8 are the test and initial shipped version of the credit card system. 0.9 and 1.0 are expected to also incorporate the test and initial shipped versions of the cash facilities as well as improvements to the credit card system. The "Extra" string is used within secure environments so that one subcomponent can scribble a note to another with minimum overhead. For example, a server firewall could put "HTTP" or "SMTP" here before forwarding the message to the core server within the firewall perimeter. 2.3 Body Parts The body parts of the message (both transparent and opaque) consist of attribute value pairs in formats that are reminiscent of the standard electronic mail header (RFC822) format. However, there are some differences. Attribute names start with and are composed predominantly of letters and internal hyphens except that they sometimes end with a hyphen followed by a number. Such a trailing number is used when there is logically an indexed vector of values. Attribute names are Eastlake, et al Informational [Page 8] RFC 1898 CyberCash Version 0.8 February 1996 frequently referred to as labels. If the label ends with a ":", then RFC822 processing is done. While the existence of trailing white space is significant, all leading white space on continuation lines is stripped. Such lines are wrapped at 64 characters in length, excluding any line termination character(s). However, if the label is terminated with a ";", this indicates a free-form field where new-line characters and any leading white space, after the initial space that indicates a continuation line, is significant. Such lines should not be wrapped except that, to avoid other processing problems, they are forcibly wrapped at 200 characters. Blank lines are ignored and do not signify a change to a different mode of line handling. Another way of looking at the above is as follows: after having found an initial $$ start line, you can treat any following lines according to the first character. If it is alphanumeric, it is a new label which should be terminated with a ":" or ";" and indicates a new label-value pair. If it is a white space character, it indicates the continuation of the value for the preceding new label line. (Exactly how the continuation is processed depends on the label termination character.) If it is "$", it should be the end line for the message. If it is #, it is a comment line and should be ignored. Other initial characters are undefined. (As of this date, no software sends CyberCash messages with # lines but they are convenient for commenting messages stored in files.) 2.4 Transparent Part The transparent part includes any clear-text data associated with the financial transaction as well as information needed by CyberCash and others to decrypt the opaque part(s). It always includes a transaction field which is the transaction number generated by the requester and which is repeated in the response. It always includes a date field that is the local date and time at the requester and is repeated in the response. In all cases other than an initial registration to establish a persona ID, it includes the requester's persona ID. On messages bound for the server, there is a "cyberkey:" field that identifies which server public key was used to encrypt the session key. Eastlake, et al Informational [Page 9] RFC 1898 CyberCash Version 0.8 February 1996 2.5 Opaque Part The opaque part consists of a single block of characters encoded using base64 encoding (see RFC 1521). The data in the opaque section is always encrypted before encoding. The label "opaque" or "merchant-opaque" precedes the opaque part depending on whether the data was encrypted by the client or merchant software. On messages inbound to the server, the data to be opaqued is DES CBC encrypted under a random transacton key and then that DES key is RSA encrypted under one of the server's public keys. The RSA encrypted DES key appears as the first part of the base64 encoded field and is not broken out as a separate value in the message. The corresponding outbound reply from the server can simply be DES encrypted under this transaction key as there is enough plain text information to identify the transaction and the customer or merchant will have remembered the transaction key from the inbound message. A signature is not generally necessary in the opaque part of a reply message. Knowledge of the transaction key is adequate authentication. In order for someone to forge the response, they would have to know the server's private key to be able to get at the transaction key. It is assumed that if anyone tampered with the response opaque part, the probability that it would decrypt to something that would parse is insignificant. (Just the fact that the 8th bit has to be off means a chance of 1 in 2**n where there are n characters and that's ignoring the rest of the formatting.) While someone can tamper with the transparent part, this usually either has no effect or means that the client won't find the transaction key, in which case it's just a particular example of denial of service by damaging a message. 2.6 Trailer The trailer is intended to close the message and provide a definitive and parseable end of the message. The trailer consists of several fields separated by "-" as in header. 1. "$$" - literal string. 2. "CyberCash" - literal string (case insensitive). 3. "End" - literal string (case insensitive). 4. transmission checksum. Eastlake, et al Informational [Page 10] RFC 1898 CyberCash Version 0.8 February 1996 5. "$$" - literal string. The transmission checksum is the MD5 has of all printable characters in the version number in the start line and those appearing after the second $$ of the start line and before the first $$ of the trailer line as transmitted. Note that all white space is left out of this hash, including any new-lines, spaces, tabs, carriage returns, etc. The exact label terminators actually used (: or ;) are included as would any # comment line. Note that the optional "Extra" string in the $ start line is not included. The idea is to check correct transmission while avoiding sensitivity to gateways or processing that might change the line terminator sequence, convert tabs to spaces, or the like. 2.7 Example Messages Simple message from a client: $$-CyberCash-0.8-$$ id: DONALD-69 transaction: 918273645 date: 199512250102 cyberkey:CC1001 opaque: GpOJvDpLH62z+eZlbVkhZJXtTneZH32Qj4T4IwJqv6kjAeMRZw6nR4f0OhvbTFfPm+GG aXmoxyUlwVnFkYcOyTbSOidqrwOjnAwLEVGJ/wa4ciKKI2PsNPA4sThpV2leFp2Vmkm4 elmZdS0Qe350g6OPrkC7TKpqQKHjzczRRytWbFvE+zSi44wMF/ngzmiVsUCW01FXc8T9 EB8KjHEzVSRfZDn+lP/c1nTLTwPrQ0DYiN1lGy9nwM1ImXifijHR19LZIHlRXy8= $$-End-CyberCash-End-jkn38fD3+/DFDF3434mn10==-$$ Message from a merchant: $$-CyberCash-a.b.c-extra-$$ merchant-ccid: acme-69 merchant-date: 19951231115959 merchant-transaction: 987654321 label: value labelx: multiple line value... # comment # another comment line label; text with a real multi-line format ! merchant-cyberkey: CC1001 merchant-opaque: Eastlake, et al Informational [Page 11] RFC 1898 CyberCash Version 0.8 February 1996 C1Q96lU7n9snKN5nv+1SWpDZumJPJY+QNXGAm3SPgB/dlXlTDHwYJ4HDWKZMat+VIJ8y /iomz6/+LgX+Dn0smoAge7W+ESJ6d6Ge3kRAQKVCSpbOVLXF6E7mshlyXgQYmtwIVN2J 66fJMQpo31ErrdPVdtq6MufynN8rJyJtu8xSNolXlqIYNQy5G2I3XCc6D3UnSErPx1VJ 6cbwjLuIHHv58Nk+xxt/FyW7yAMwUb9YNcmOj//6Ru0NiOA9P/IiWczDe2mJRK1uqVpC sDrWehG/UbFTPD26trlYRnnY $$-CyberCash-End-kchfiZ5WAUlpk1/v1ogwuQ==-$$ 3. Signatures and Hashes Inbound CyberCash request messages normally have a signature, as described below, of all of the messages fields outside of the signature. This signature is transmitted inside the opaque part of the message. It enables the server to authenticate the source of the message. Messages from a merchant to a client initiating a purchase sequence have fields signed by the merchant. These fields and this signature are included by the client in the opaque part of their card purchase message to the merchant so that, when all is passed on to the server, it can verify that the client saw the information the merchant intended. More information on CyberCash signatures and the hash codes they are based on, is given below. 3.1 Digital Signatures Digital signatures are a means of authenticating information. In CyberCash messages, they are calculated by first taking the hash of the data to be authenticated, as described below, and then encoding the hash using an RSA private key. Anyone possessing the corresponding public key can then decrypt the hash and compare it with the message hash. If they match, then you can be sure that the signature was generated by someone possessing the private key which corresponded with the public key you used and that the message was not tampered with. In the CyberCash system, clients, merchants, and the server have public-private key pairs. By keeping the private key secret and registering their public key with the server (for a merchant or client) or publishing their public key or keys (for the server), they can provide high quality authentication by signing parts of messages. An RSA digital signature is approximately the size of the modulus used. For example, if that is 768 bits long, then the binary digital signature would be 768 bits or 96 bytes long and its base 64 encoding would be 128 bytes. Eastlake, et al Informational [Page 12] RFC 1898 CyberCash Version 0.8 February 1996 3.2 Hash Codes The hashes used in CyberCash messages are message digests. That is, a non-invertable fingerprint of a message such that it is computationally infeasible to find an alternate message with the same hash. Thus the relatively small hash can be used to secure a larger message. If you are confident in the authenticity of the hash and are presented with a message which matches the hash, you can be sure it is the original message, at least as regards all aspects that have been included in the hash. The hash is calculated using the MD5 algorithm (see RFC 1321) on a synthetic message. The synthetic message is composed of the labels and values specified in a list for the particular hash. Since the hash is input order dependent, it is essential that the label-value pairs be assembled in the order specified. In some cases, a range of matching labels is specified. For example, "card*" to match card- number, card-expiration-date, and all other labels starting with "card". In such cases, all existing matching labels are used in ascending alphabetic order by ASCII character code. If a label is specified in a signature list but is not present in the label-value data on which the hash is being calculated, it is not included in the hash at all. That is, even the label and label terminator are omitted from the synthetic message. Before being hashed, the text of the synthetic message is processed to remove all "white space" characters. White space characters are defined as any with an ASCII value of 32 (space) or less or 127 (rubout) or greater. Thus all forms of new-line/carriage-return and distinctions such as blank lines, trailing spaces, replacement of a horizontal tab character by multiple spaces, etc., are ignored for hash purposes. MD5 hashes are 16 bytes long. This means that the base 64 encoding of such a hash will be 24 characters (of which the last two will always be padding equal signs). 4. Specific Message Formats This section describes the formats of the Verison 0.8 CyberCash messages by example with comments. The reader in assumed to be familiar with terms such as "acquirer", "PAN" (primary account number), etc., defined in ISO 8583, and currency designations as defined in ISO 4217. A few fields not relevant to current operations have been removed to simplify this exposition. Eastlake, et al Informational [Page 13] RFC 1898 CyberCash Version 0.8 February 1996 In the following example messages, signatures, hashes, and encrypted sections are fake nonsense text and ids are fictitious. 4.1 Persona Registration and Application Retrieval The first step in customer use of CyberCash is registering a persona using the customer application. This is done with the R1 message defined below. The CyberCash server responds with the R2 message. When the customer application learns that it is out of date, it can use the GA1 request message to the server and its GA2 response to download a new signed version of itself. 4.1.1 R1 - registration Description: This is the initial message sent to create a new CyberCash persona. ##################################################################### Sender: CyberApp Receiver: CyberServer ##################################################################### Sample Message: $$-CyberCash-0.8-$$ transaction: 123123213 date: 19950121100505.nnn cyberkey: CC1001 opaque: FrYOQrD16lEfrvkrqGWkajM1IZOsLbcouB43A4HzIpV3/EBQM5WzkRJGzYPM1r3noBUc MJ4zvpG0xlroY1de6DccwO9j/0aAZgDi9bcQWV4PFLjsN604j3qxWdYn9evIGQGbqGjF vn1qI1Ckrz/4/eT1oRkBBILbrWsuwTltFd84plvTy+bo5WE3WnhVKsCUJAlkKpXMaX73 JRPoOEVQ3YEmhmD8itutafqvC90atX7ErkfUGDNqcB9iViRQ7HSvGDnKwaihRyfirkgN +lhOg6xSEw2AmYlNiFL5d/Us9eNG8cZM5peTow== $$-CyberCash-End-kchfiZ5WAUlpk1/v1ogwuQ==-$$ ##################################################################### Opaque Key: Generated using CyberCash encrypting public key identified in CyberKey. ##################################################################### Opaque Section Contents: type: registration swversion: 0.8win content-language: en-us requested-id: MyRequestedCCID Eastlake, et al Informational [Page 14] RFC 1898 CyberCash Version 0.8 February 1996 email: myemail@myemailhost.com pubkey: 0VdP1eAUZRrqt3Rlg460Go/TTs4gZYZ+mvI7OlS3l08BVeoms8nELqL1RG1pVYdDrTsX E5L+wcGCLEo5+XU5zTKkdRUnGRW4ratrqtcte7e94F+4gkCN06GlzM/Hux94 signature: v6JGmxIwRiB6iXUK7XAIiHZRQsZwkbLV0L0OpVEvan9l59hVJ3nia/cZc/r5arkLIYEU dw6Uj/R4Z7ZdqO/fZZHldpd9+XPaqNHw/y8Arih6VbwrO5pKerLQfuuPbIom ##################################################################### signature is of the following fields: transaction, date, cyberkey, type, swversion, content-language, requested-id, email, pubkey ##################################################################### Explanation: content-language is taken from the MIME header field (see RFC1766) and is the language text messages should be generated in. (only en-us implemented at this time. swversion used to check if client application is old. 4.1.2 R2 - registration-response Description: This message gives the success/failure response to R1. ##################################################################### Sender: CyberServer Receiver: CyberApp ##################################################################### Sample Message: $$-CyberCash-0.8-$$ transaction: 12312313 date: 19950121100505.nnn opaque: r1XfjSQt+KJYUVOGU60r7voFrm55A8fP5DjJZuPzWdPQjGBIu3B6Geya8AlJfHsW11u8 dIv1yQeeYj/+l9TD1dXW21/1cUDFFK++J2gUMVv8mX1Z6Mi4OU8AfsgoCliwSkWmjSOb kE62sAlZTnw998cKzMFp70TSlI3PEBtvIfpLq5lDCNbWidX8vFZV0ENUmMQ9DTP3du9w fsFGvz1mvtHLT/Gj8GNQRYKF4xiyx4HYzTkSMhgU5B/QDLPS/SawIJuR86b9X0mwsr0a gbGTzECPJTiKkrhxxMG/eymptsVQSLqNaTCx6w== $$-CyberCash-End-kchfiZ5WAUlpk1/v1ogwuQ==-$$ ##################################################################### Opaque Key: Same as session key for R1 for same Transaction and connection (there may be no ID!). ##################################################################### Opaque Section Contents: Eastlake, et al Informational [Page 15] RFC 1898 CyberCash Version 0.8 February 1996 type: registration-response server-date: 19950121100506.nnn requested-id: MyRequestedCCID response-id: CyberCashHandle email: myemail@myemailhost.com response-code: success/failure/etc. pubkey: 0VdP1eAUZRrqt3Rlg460Go/TTs4gZYZ+mvI7OlS3l08BVeoms8nELqL1RG1pVYdDrTsX E5L+wcGCLEo5+XU5zTKkdRUnGRW4ratrqtcte7e94F+4gkCN06GlzM/Hux94 swseverity: fatal/warning [absent if ok] swmessage; Tells CyberApp that it is obsolete. Display this text to the user. [only present if SWSeverity present] message; Free text of the error/success condition. This text is to be displayed to the person by the CyberCash application... In general this includes: duplicate-id, bad-signature, or ill-formed-registration ##################################################################### Signature is of the following fields: no-signature ##################################################################### Explanation: responseid is used to suggest a unique ID if the failure was due to the requested ID being already in use... If the reason for failure was not due to duplicate ID then this field may be omitted. responseid gives the actual ID with check characters appended if success. swseverity can warn user of old client application or indicate failure due to old or known buggy version. 4.1.3 GA1 - get-application Description: Used by CyberApp to get an updated version. ##################################################################### Sender: CyberApp Receiver: CyberServer ##################################################################### Sample Message: $$-CyberCash-0.8-$$ transaction: 123123213 date: 19950121100505.nnn Eastlake, et al Informational [Page 16] RFC 1898 CyberCash Version 0.8 February 1996 cyberkey: CC1001 opaque: VHMS611wGkUmR6bKoI+ODoSbl7L5PKtEo6aM88LCidqN+H/8B4xM3LxdwUiLn7rMPkZi xOGb+5d1lRV7WeTp21QYlqJr8emc6FAnGd5c0csPmcnEpTFh9xZDJaStarxxmSEwm2mw l2VjEUODH6321vjoMAOFQWn7ER0o $$-CyberCash-End-0QXqLlNxrn4GNQPPk9AO1Q==-$$ ##################################################################### Opaque Key: Generated using CyberCash encrypting public key identified in CyberKey. ##################################################################### Opaque Section Contents: type: get-application swversion: 0.8win ##################################################################### Signature is of the following fields: no signature ##################################################################### Explanation: There may not be a customer persona so there is no ID. There may not be a customer public/private key pair so there is no signature. The swversion is mandatory so the server can tell what to return. 4.1.4 GA2 - get-application-response Description: Return success and URL of up to date copy of CyberApp or failure. ##################################################################### Sender: CyberServer Receiver: CyberApp ##################################################################### Sample Message: $$-CyberCash-0.8-$$ transaction: 12312313 date: 19950110102333.nnn opaque: EDD+b9wAfje5f7vscnNTJPkn1Wdi7uG3mHi8MrzLyFC0dj7e0JRjZ2PmjDHuR81kbhqb nX/w4uvsoPgwM5UJEW0Rb9pbB39mUFBDLPVgsNwALySeQGso0KyOjMxNs1mSukHdOmDV 4uZR4HLRRfEhMdX4WmG/2+sbewTYaCMx4tn/+MNDZlJ89Letbz5kupr0ZekQlPix+pJs rHzP5YqaMnk5iRBHvwKb5MaxKXGOOef5ms8M5W8lI2d0XPecH4xNBn8BMAJ6iSkZmszo QfDeWgga48g2tqlA6ifZGp7daDR81lumtGMCvg== Eastlake, et al Informational [Page 17] RFC 1898 CyberCash Version 0.8 February 1996 $$-CyberCash-End-0QXqLlNxrn4GNQPPk9AO1Q==-$$ ##################################################################### Opaque Key: session key from GA1 ##################################################################### Opaque Section Contents: type: get-application-response server-date: 19950110102334.nnn response-code: success/failure/etc. message; Text message to be displayed to the user providing more information on the success/failure. swversion: 0.8win application-url: http://foo.cybercash.com/server/0.8WIN.EXE application-hash: lSLzs/vFQ0BXfU98LZNWhQ== ##################################################################### Signature: none. ##################################################################### Explanation: application-hash is the MD5 of the binary of the application. application-url & application-hash omitted on failure. swversion is the version being transmitted to the customer. 4.2 Binding Credit Cards The CyberCash system is design to give the card issuing organization control over whether a card may be used via the CyberCash system. The customer, after having registered a persona with CyberCash as described above, can then bind each credit card they wish to use to their CyberCash persona. This is done via the BC1 message from the customer to their CyberCash server and the BC4 response from the server. 4.2.1 BC1 - bind-credit-card Description: This is the initial message in the process of binding a credit card to a CyberCash persona. ##################################################################### Sender: CyberApp Receiver: CyberServer ##################################################################### Sample Message: Eastlake, et al Informational [Page 18] RFC 1898 CyberCash Version 0.8 February 1996 $$-CyberCash-0.8-$$ id: MyCyberCashID date: 19950121100505.nnn transaction: 12312314 cyberkey: CC1001 opaque: EDD+b9wAfje5f7vscnNTJPkn1Wdi7uG3mHi8MrzLyFC0dj7e0JRjZ2PmjDHuR81kbhqb nX/w4uvsoPgwM5UJEW0Rb9pbB39mUFBDLPVgsNwALySeQGso0KyOjMxNs1mSukHdOmDV 4uZR4HLRRfEhMdX4WmG/2+sbewTYaCMx4tn/+MNDZlJ89Letbz5kupr0ZekQlPix+pJs rHzP5YqaMnk5iRBHvwKb5MaxKXGOOef5ms8M5W8lI2d0XPecH4xNBn8BMAJ6iSkZmszo QfDeWgga48g2tqlA6ifZGp7daDR81lumtGMCvg== $$-CyberCash-End-kchfiZ5WAUlpk1/v1ogwuQ==-$$ ##################################################################### Opaque Key: generated from CyberCash encryption key identified in CyberKey ##################################################################### Opaque Section Contents: type: bind-credit-card swversion: 0.8win card-number: 1234567887654321 card-type: mastercard card-salt: 46735210 card-expiration-date: 05/99 card-name: John Q. Public card-street: card-city: card-state: card-postal-code: card-country: signature: tX3odBF2xPHqvhN4KVQZZBIXDveNi0eWA7717DNfcyqh2TpXqgCxlDjcKqdJXgsNLkY7 GkyuDyTF/m3SZif64giCLjJRKg0I6mqI1k/Dcm58D9hKCUttz4rFWRqhlFaj ##################################################################### signature is of the following fields: id, date, transaction, cyberkey, type, swversion, card-number, card-salt, card-expiration-date, card-name, card-street, card-city, card-state, card-postal-code, card-country ##################################################################### Explanation: salt is needed so that the hash stored at the server is less informative. Server just remembers the "prefix" of the card number and the hash of the combined card number and salt. If it just hashed the card number, it would be recoverable with modest Eastlake, et al Informational [Page 19] RFC 1898 CyberCash Version 0.8 February 1996 effort by trying to hash all plausible numbers. We don't want to store the card numbers on the server because it would make the server files too valuable to bad guys. 4.2.2 BC4 - bind-credit-card-response Description: Indicates that the process of binding a credit card terminated. Returns success or failure. ##################################################################### Sender: CyberServer Receiver: CyberApp ##################################################################### Sample Message: $$-CyberCash-0.8-$$ id: mycybercashid transaction: 12312314 date: 19950121100505.nnn opaque: EDD+b9wAfje5f7vscnNTJPkn1Wdi7uG3mHi8MrzLyFC0dj7e0JRjZ2PmjDHuR81kbhqb nX/w4uvsoPgwM5UJEW0Rb9pbB39mUFBDLPVgsNwALySeQGso0KyOjMxNs1mSukHdOmDV 4uZR4HLRRfEhMdX4WmG/2+sbewTYaCMx4tn/+MNDZlJ89Letbz5kupr0ZekQlPix+pJs rHzP5YqaMnk5iRBHvwKb5MaxKXGOOef5ms8M5W8lI2d0XPecH4xNBn8BMAJ6iSkZmszo QfDeWgga48g2tqlA6ifZGp7daDR81lumtGMCvg== $$-CyberCash-End-kchfiZ5WAUlpk1/v1ogwuQ==-$$ ##################################################################### Opaque Key: Session key from BC1 with same Transaction and ID ##################################################################### Opaque Section Contents: type: bind-credit-card-response server-date: 19950121100506.nnn swseverity: fatal/warning [absent if ok] swmessage; message about obsoleteness of customer software to be shown to the customer. [only present if SWSeverity present] response-code: success/failure/etc. card-number: 1234567887654321 card-type: visa card-salt: 47562310 card-expiration-date: 01/99 card*: [other card* lines to also be given in CH.1 message] message; Plain text for the user can be multiple lines Eastlake, et al Informational [Page 20] RFC 1898 CyberCash Version 0.8 February 1996 ##################################################################### Signature is of the following fields: no-signature ##################################################################### Explanation: All the card* lines can be saved as a blob to be submitted in CH.1. card-expiration-date, card-number, card-salt, and card-type should always be present. Depending on reason for failure, not all fields may be present. 4.3 Customer Credit Card Purchasing Messages In general, CyberCash involvement in the credit card purchasing cycle starts after the user has determined what they are buying. When they click on the CyberCash payment button, a PR1 message is sent by the merchant to the customer as the body of a message of MIME type application/cybercash. If the customer wishes to proceed, they respond to the merchant with a CH1. The merchant responds with a CH2 but between the receipt of the CH1 and issuance of the CH2, the merchant usually communicates with the CyberCash server via the CM* messages. 4.3.1 PR1 - payment-request Description: This message is the first message that is defined by CyberCash in the purchase-from-a-merchant process. The shopping has completed. Now we are at the point of paying for the purchases. ##################################################################### Sender: MerchantApp Receiver: CyberApp ##################################################################### Sample Message: $$-CyberCash-0.8-$$ type: payment-request merchant-ccid: ACME-012 merchant-order-id: 1231-3424-234242 merchant-date: 19950121100505.nnn note; ACME Products Purchase of 4 pairs "Rocket Shoes" at $39.95 ea. Shipping and handling $5.00 Eastlake, et al Informational [Page 21] RFC 1898 CyberCash Version 0.8 February 1996 Total Price: 164.80 Ship to: Wily Coyote 1234 South St. Somewhere, VA 12345 merchant-amount: usd 164.80 accepts: visa:CC001, master:CC001,amex:CC001,JCPenny:VK005,macy:VK006 url-pay-to: http://www.ACME.com/CybercashPayment url-success: http://www.ACME.com/ordersuccess url-fail: http://www.ACME.com/orderfail merchant-signed-hash: a/0meaMHRinNVd8nq/fKsYg5AfTZZUCX0S3gkjAhZTmcrkp6RZvppmDd/P7lboFLFDBh Ec0oIyxWeHfArb3OtkgXxJ7qe0Gmm/87jG5ClGnpBnw0dY7qcJ6XoGB6WGnD $$-CyberCash-End-lSLzs/vFQ0BXfU98LZNWhQ==-$$ ##################################################################### Opaque Key: no opaque section ##################################################################### Opaque Section Contents: no opaque section ##################################################################### merchant-signed-hash is the signature under the merchant's private key of the hash of the following fields: type, merchant-ccid, merchant-order-id, date, note, merchant-amount, accepts, url-pay-to, url-success, url-fail ##################################################################### Explanation: This message is si