Cryptographic file security for multiple domain networks4203166Abstract A file security system for data files created at a first host system in one domain and recovered at a second host system in another domain of a multiple domain network. Each of said host systems contain a data security device provided with multiple host keys capable of performing a variety of cryptographic operations. Creation and recovery of a secure data file is accomplished without revealing the keys of either of the host systems to the other of the host systems. When the data file is to be created at the first host system, the first host system data security device provides a file recovery key for subsequent recovery of the data file at the second host system and enciphers first host system plaintext under a primary file key, which is related to the file recovery key, to obtain first host system ciphertext as the data file. The file recovery key is used as header information for the data file or maintained as a private file recovery key. When the data file is to be recovered at the second host system, the file recovery key is provided at the second host system and the second host system data security device performs a cryptographic operation to transform the file recovery key into a form which is usable to decipher the data file. The second host system data security device then uses the transformed file recovery key to perform a cryptographic operation to obtain the first host system ciphertext in clear form at the second host system. Claims What is claimed is: Description CROSS REFERENCE TO RELATED APPLICATIONS
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SECURITY
CATEGORY CLASS TYPE USE
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Key Encrypting
Key
Primary System Key Host Master Encipher
Key (KMH)
Secondary File
Other
Key (KNF)
Secondary Private Second-
ary File Key
Cryptographic
Secondary (KNFP)
File Keys
Cross Domain
Key (KNF.sup.jk)
Keys Private Cross
Domain Key
(KNFP.sup.jk)
Data Encrypt- Encipher
ing Keys Primary System File
Key (KF) Or
File
(Operational Private System
Decipher
Keys KO) File Key
Keys (KFP) Data
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GENERATION, DISTRIBUTION, INSTALLATION AND MANAGEMENT OF CRYPTOGRAPHIC KEYS Key generation is the process which provides for the creation of the cipher keys required by a cryptographic system. Key generation includes the specification of a system master key and primary and secondary file keys. The host master key is the primary key encrypting key and is the only cipher key that needs to be present in the host cryptographic facility in clear form. Since the host master key does not generally change for long periods of time, great care must be taken to select this key in a random manner. This may be accomplished by using some random experiment such as coin tossing where bit values 0 and 1 are determined by the occurrence of heads and tails of the coin or by throwing dice where bit values 0 and 1 are determined by the occurrence of even or odd rolls of the dice, with the occurrence of each group of coins or dice being converted into corresponding parity adjusted digits. By enciphering all other cipher keys stored in or passed outside the host system, overall security is enhanced and secrecy for such other cipher keys reduces to that of providing secrecy for the single host master key. Secrecy for the host master key may be accomplished by storing it in a non-volatile master key memory so that the host master key need only be installed once. Once installed, the master key is generally used by the cryptographic apparatus for internally deciphering enciphered keys which may then be used as the working key in a subsequent encipher/decipher operation. Installation of the host master key may be accomplished by a direct manual entry process using mechanical switches, dials, or a hand-held key entry device. Alternately, an indirect entry method may be used in which case the host master key may be entered from a non-volatile media such as a magnetic card or tape which is maintained in a secure location (safe, vault, etc.) accessible only to the security administrator. Another alternative indirect entry method may be to use a keyboard entry device, though this method is subject to human error. In any event, whichever indirect method is chosen, during initialization, the host master key may be read into and temporarily stored in the host memory and then transferred to the master key memory with the host memory entry being subsequently erased so that only one copy is present and accessible only by the cryptographic facility. The secondary file key is a key encrypting key and since there may be numerous data files associated with the data processing network, it may not be practical or prudent to have these keys generated by a human user using some type of random experiment. Therefore, to relieve the system administrator from the burden of creating cryptographic keys, except for the single system master key, the cryptographic apparatus of the host system can be used as a pseudo random generator for generating the required secondary file keys used by the various data files of the network. In addition to the system generated secondary file keys, off line means may be used by end users to establish a private secondary file key. The cross-domain key is a secondary key encrypting key which is used as a secondary file key to allow a system file key generated at the host system in one domain to be transmitted and recovered at the host system in another domain of a multiple domain data processing system. The cryptographic apparatus of the sending host system used as a pseudo random generator, as in the case of generating secondary file keys, can also be used to generate the cross-domain key. Because there may be numerous host systems interconnected in the multiple domain communication network, it is necessary to generate a separate cross-domain key for each cross-domain file communication between each host system and the other host systems of the network. In addition to the system generated cross-domain keys, off line means may be used by end users to establish a private cross-domain key. In either event, the clear form of the system or private generated cross-domain keys must be distributed from each host system to each of the other host systems in the data processing system in a secure manner. This may be accomplished by transporting the key by courier, registered mail, public telephone, etc. The likihood of an opponent obtaining the key during transit can be lessened by transmitting different portions of the key over independent paths and then combining them at the destination. Once having properly received a valid system or private generated cross-domain key in clear form, it becomes necessary to maintain its secrecy. The manner in which this is accomplished will be described hereafter. However, once installed at the receiving host system in a protected form, the cross-domain key is used only by the receiving host system for internally transforming enciphered system file keys transmitted as a file recovery key by a sending host system into a form usable by the receiving host system to carry out cryptographic operations. Because the ciphering algorithm used is not secret, the degree of protection that can be derived from a cryptographic system ultimately depends upon the security of the cryptographic keys. Therefore, the objectives of key management are: (1) cryptographic keys should never occur in clear form outside the cryptographic device, except under secure conditions during the period when keys are originally distributed and installed or when stored in a secure place such as a safe, vault or similar location for backup or recovery and (2) no cryptographic operation, or combination thereof, using any cryptographic quantities which are routinely stored or routed through the system, or derived therefrom, should permit clear keys to be recoverable outside the cryptographic device. Therefore, in keeping with the first objective, if the system generated secondary file keys are to be stored at the host system they must be protected by being enciphered under another key. Accordingly, to prevent exposing these keys in clear form, a multiple master key approach is adapted, by the present invention, in which a second master key which may be a variant (KMH2) of the host master key (KMH.phi.) is used to encipher the secondary file keys by an Encipher Master Key function (EMK2), which will be described in greater detail hereafter. In the embodiment of the present invention, only the host master key resides in clear form within the cryptographic device. Accordingly, when an EMK2 function is to be performed, the host master key is read out of the master key memory and by selected inversion of certain bits of the host master key the variant KMH2 is derived for use in enciphering the secondary file key. By enciphering the secondary file keys under the variant of the host master key, the enciphered secondary file keys may be stored in a cryptographic data set until required for use in a cryptographic operation and the first objective of key management is obtained, namely, that no key shall occur in clear form. It should be noted that although the relationship between the host master key and its variant are known i.e. which bits are inverted, the cryptographic strength is not weakened because there is no way to use this information to arrive at useful key information because of the complexity of the algorithm. In the case of a multiple domain data processing system, a cross-domain key generated at a host system in one domain for cross-domain file communication with a host system in another domain of the network is communicated in a secure manner to the host system in the other domain and visa versa so that a pair of cross-domain keys is shared between the two host systems. Thus, the cross-domain key generated at the host system in the one domain is designated as the sending cross-domain key for the one domain and as the receiving cross-domain key in the other domain whereas the cross-domain key generated at the host system in the other domain is designated as the sending cross-domain key for the other domain and as the receiving cross-domain key in the one domain. Therefore, each host system must store two cross-domain keys for cross domain file communications between itself and another host system of the network, one being the cross-domain key it generated and designated as the sending cross-domain key and the other being a cross-domain key it received from the other host system and designated as the receiving cross-domain key. Since, these pairs of keys are to be stored at each host system, they must also be protected from being exposed in clear form. This can be accomplished, as in the case of secondary file keys, by having them enciphered under another key. A sending cross-domain key when system generated in a sending host system is used in a privileged transformation process, termed an RFMK function which will be described in greater detail hereafter, to reencipher a system file key from encipherment under the host master key to encipherment under the sending cross-domain key for use as a file recovery key for recovering the data file at the receiving host system. At the receiving host system, the receiving cross-domain key is used in a different type of privileged transformation process, termed an RTMK function which will be described in greater detail hereafter, to reencipher the received system file key from encipherment under the receiving cross-domain key to encipherment under the receiving host master key. In order to achieve cryptographically strong key management, these privileged transform processes should be unidirectional i.e. the transform process should be irreversible at the sending host system and decipherable only at the receiving host system. Unidirectionality is achieved in the present invention by a multiple master key technique in which a first key encrypting key, which may be a first variant (KMH1) of the sending host master key (KMH.phi.), is used to encipher the sending cross-domain key by the Encipher Master Key function (EMK1) and a second key encrypting key, which may be a second variant (KMH2) of the sending host master key (KMH.phi.), is used to encipher the receiving cross-domain key by an Encipher Master Key function (EMK2), which will be described in greater detail hereafter. The EMK2 function is similar to the EMK1 function in that the master key of the associated host system is read out and by selected inversion of certain bits, different from those inverted by the EMK1 function, of the host master key, the variant KMH2 is derived for use in enciphereing the receiving cross-domain key. By enciphering the sending cross-domain key under the first variant of the host master key and by enciphering the receiving cross-domain key under the second variant of the host master key, the enciphered cross-domain keys, now in protected form, may be stored in a cryptographic data set until required for use in the transform processes. Unidirectionality is made possible because the output of the sending RFMK transformation function, the system file key enciphered under the sending cross-domain key, is usable only by the receiving RTMK transformation function. Thus, the sending host system can reencipher the system file key from encipherment under the sending host master key to encipherment under the sending cross-domain key because the sending cross-domain key enciphered under the first variant of the sending host master key is available at the sending host system, but it cannot reencipher the system file key from encipherment under the first variant of the sending cross-domain key to encipherment under the sending host master key because the sending cross-domain key enciphered under a second variant of the sending host master key is not available at the sending host system. Inversely, the receiving host system can reencipher the system file key from encipherment under the sending cross-domain key to encipherment under the receiving host master key because the sending cross-domain key enciphered under the second variant of the receiving host master key is available at the receiving host system, but it cannot reencipher the system file key from encipherment under the receiving host master key to encipherment under the sending cross-domain key because the sending cross-domain key is not available at the receiving host system. In a multiple domain network where cross domain file communication is to be established using a private cross domain key, an RTMK transformation function is required to reencipher the system file key from encipherment under the private cross domain key to encipherment under the sending host master key, as will be described in greater detail hereafter. To perform this transform process the private cross domain key enciphered under the second variant of the sending host master key must be available at the sending host system. Additionally, the private cross domain key is enciphered under the second variant of the associated host system master key to permit this transform process to be performed. The EMK2 function may be used to encipher the private cross domain key under the second variant of the host master key and the private cross domain key, now in protected form, may also be stored in the cryptographic data set until required in the transformation process. System generated primary file keys, i.e. system file keys, are time variant keys which are dynamically generated for each file to be created and are used to protect file data. Since there may be numerous data files created it is impractical to have these keys generated by a human user. Therefore, the cryptographic apparatus of the host system may be used as a pseudo-random generator for generating, as each data file is to be created, a pseudo-random number which, in keeping with the objective that cryptographic keys should never occur in the clear, may be defined as being a system file key enciphered under a host key encrypting key. In a multiple domain network when cross domain file communication is to be established involving a data file created at one host system for recovery only at a designated other host system, the generated random number is defined as being the file key enciphered under the host master key. On the other hand, when cross domain communication is to be established using a private cross domain key, the generated random number is defined as being the system file key enciphered under the private cross domain key associated with the application program of the sending host system. In other private cryptographic systems involving multiple domain systems, where the end users use a private protocol which is unknown to the system, key selection, management and data transfer operations are performed without system knowledge that cryptography is being performed. In such arrangements, the end users may define a private protocol using a mutually agreed upon private primary file key, i.e. a private system file key. In order to meet the objective that no cryptographic key appear in clear form, the private system file key must also be protected. This is accomplished, in this case, by enciphering the private system file key under the host master key by an Encipher Master Key function (EMK.phi.), which will be described in greater detail hereafter. The following table summarizes the protection provided for the various cryptographic keys used at a representative host system in a multiple domain data processing system by a multiple master key arrangement which uses variants of the host master key.
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EXPLANATORY
NAME KMH1 KMH2 NOTE
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FILE l E.sub.KMH2.spsb.j KNF.sub.l.sup.j
. .
.. .
.
FILE i E.sub.KMH2.spsb.j KNF.sub.i.sup.j
File Keys
. .
. .
.
FILE n E.sub.KMH2.spsb.j KNF.sub.n.sup.j
HOST j E.sub.KMH1.spsb.j KNF.sup.jk
E.sub.KMH2.spsb.j KNF.sup.kj
Sending and
. . Receiving
. . Cross Domain
HOST k E.sub.KMH1.spsb.k KNF.sup.kj
E.sub.KMH2.spsb.k KNF.sup.jk
Keys
HOST j E.sub.KMH2.spsb.j KNFP.sup.jk
Private
. .
. . File
HOST k E.sub.KMH2.spsb.k KNFP.sup.jk
Keys
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While it is efficient to use variants of a host master key to provide protection for the various cryptographic keys used in the system, it is well within the skill of the art to provide separate master keys instead of variants of a single master key. This could be accomplished by providing separate master key memories each being loaded with a master which is different from each other and being accessed when needed. While this is a viable alternative, it would substantially increase the cost of the host data security device as opposed to using a single master key memory and obtaining variants as needed. MULTIPLE DOMAIN DATA PROCESSING NETWORKS A modern day data processing system consist of a host system which includes a host processor, host memory, channel and its associated resources such as the host programs and locally attached terminals and data files. As the size of the data processing system increases other host systems may be brought into the data processing system to provide multiple domain systems with each host system having knowledge of and managing its associated resources which make up a portion or domain of the processing system. A representative multiple domain processing system is shown in FIG. 1 with the host and its associated resources shown in block form. While the particular manner in which the host system is implemented is not critical to the present invention, the block diagram of FIG. 1 shows the data flow and control relationships of a representative host system arrangement. The host includes a programmable processor 1 operationally connected to a memory 2 which provides storage for data and the programs which are utilized to control the system and a channel 3 which controls the transfer of data between input/output devices and the processor 1. Channel 3 is connected to the processor 1 and memory 2 and via a channel I/O interface, with control units such as control unit 4 capable of controlling an input/output device which may be a printer, control unit 5 capable of controlling a cluster of input/output devices which may be display or printer type of devices, control unit 6 capable of controlling a mass storage device, communication controller 7 capable of two-direction control that links the Host.sup.j system to communication lines connected to Host.sup.k and Host.sup.l systems, control unit 9 capable of controlling a plurality of magnetic tape units, and control unit 10 capable of controlling a plurality of disk files. A data file may be created at the Host.sup.j system for storage on one of the magnetic tape units or disks for recovery at Host.sup.k system or Host.sup.l system. The data file may be read at the Host.sup.j system and communicated by teleprocessing means over a communication line to either of the other host systems with communication security provided by the technique disclosed in the aforementioned copending application Ser. No. 857,731. Alternatively, the magnetic tape unit or disk may be of a portable nature which permits it to be transported by a human being, registered mail or the like from Host.sup.j system to the designated receiving host system, represented by the dotted line connection between the host systems, where it may then be loaded and the data file recovered at the receiving host system. The collection of data and control lines connected between the channel and I/O control units is commonly referred to as the channel I/O interface providing an information format and signal sequence common to all the I/O control units. The I/O interface lines generally include a data bus out which is used to transmit device addresses, commands and data from the processor to the I/O control unit; a data bus in which is used to transmit device identification, data or status information from the I/O control unit to the channel 3 and tag signal lines which are used to provide signals identifying an I/O operation, the nature of information on the data bus and parity condition. Since each I/O control unit has a unique electrical interface, device adapters are generally provided to allow device connection to the common I/O interface. All I/O data transfers between the processor and the attached control units may be performed in a programmed input/output (PIO) mode on a 1 byte per I/O instruction basis. Into this organization of a general purpose host system is integrated a data security device 11. The host data security device 11 and manner in which it performs cryptographic operations is described in detail in the co-pending application Ser. No. 857,531, filed Dec. 5, 1977 entitled "Cryptographic Communication Security for Multiple Domain Networks", by W. F. Ehrsam et al. FIG. 2 shows, in block diagram form, the major elements of the data security device (DSD) 11 which includes a crypto device 12, a master key (MK) memory 13, a DSD adapter 14 which connects to the I/O interface and a manual entry device 15 for manually loading a host master key into the MK memory 13. Either one of two methods can be used for writing a host master key into the MK memory 13. The first method for writing the host master key into the MK memory 13 is achieved under program control. In this method, an I/O device having a keyboard, magnetic stripe card reader or the like, may use such elements to cause the host master key to be stored in the host memory 2 as in the case of conventional data entry. Subsequently, under program control, the host master key may be read from the host memory 2 to the MK memory 13 of the DSD in a manner as described in greater detail in the aforementioned co-pending application. The other method of writing the host master key into the MK memory 13 consists of manually writing the host master key into the MK memory 13 by means of individual toggle or rotary switches wired to produce binary coded hex digits as described in greater detail in the aforementioned co-pending application. To enable master key writing into the MK memory 13 by either method, an enable write key (EW) switch is provided which is initially turned on when a write master key operation is initiated and turned off at the end of write master key operation. To prevent the key from being changed by unauthorized persons, the EW switch operation may be activated by a physical key lock arrangement. The DSD adapter 14 serves a dual function namely, providing adapter functions for DSD connection to the I/O interface and control functions for the DSD. The I/O interface provides the DSD adapter 14 with overall direction, gives it cipher keys to be used, presents it with data to be processed and accepts the processed results. Overall direction is achieved by use of operation commands which are decoded and subsequently provide control in properly timed sequences of signals to carry out each command. These signals are synchronized with the transfer of data in and out. The DSD adapter 14 also controls the placing of cipher keys in the crypto device 12 and directs the crypto device in the enciphering and deciphering operations. The MK memory 13 in a non-volatile 16.times.4 bit random access memory (RAM) which is battery powered to enable key retention when host power may not be present. The host master key consists of eight master key bytes (64 bits) each of which consists of seven key bits and one parity bit. The crypto device 12 is the heart of the DSD hardware for performing enciphering and deciphering operations. The crypto device 12 performs encipher/decipher operations on a block cipher basis in which a message block of 8 data bytes (64 bits) is enciphered/deciphered under control of a 56 bit cipher working key to produce an enciphered/deciphered message block of 8 data bytes. The block cipher is a product cipher function which is accomplished through successive applications of a combination of non-linear substitutions and transpositions under control of the cipher working key. Sixteen operations, defined as rounds, of the product cipher are executed in which the result of one round serves as the argument of the next round. This block cipher function operation is more fully described in the aforementioned U.S. Pat. No. 3,958,081. A basic encipher/decipher operation of a message block of data starts with the loading of the cipher key from the host memory 2. This key is generally stored under master key encipherment to conceal its true value. Therefore, it is received as a block of data and deciphered under the master key to obtain the enciphering/deciphering key in the clear. The clear key does not leave the crypto device 12 but is loaded back in as the working key. The message block of data to be enciphered/deciphered is then transferred to the crypto device 12 and the cipher function is performed, after which the resultant message block of enciphered/deciphered data is transferred from the crypto device 12 to the host memory 2. If subsequent encipher/decipher functions are to be performed using the same working key, there is no need to repeat the initial steps of loading and deciphering the working key as it will still be stored in the working key register. The crypto device 12 includes duplicate crypto engines operating in synchronism to achieve checking by 100% redundancy. Referring now to FIG. 3, one of the crypto engines is shown in simplified block form with a heavy lined border signifying a secure area. The crypto engine 16 contains a 64 bit input/output buffer register 17 divided into upper and lower buffer registers 18 and 19 of 32 bits each. The buffer register 17 is used in a mutually exclusive manner for receiving input data on a serial by byte basis from the bus in, termed an input cycle, and for providing output data in a serial by byte basis to the bus out, termed an output cycle. Thus, during each input cycle a message block of eight data bytes is written into the buffer register 17 from the host memory 2 while during each output cycle a message block of eight processed data bytes is read from the buffer register 17 to the host memory 2. Serial outputs of the buffer register 17 are also applied as serial inputs to the working key register 20 and a parity check circuit 21, the latter being controlled to be effective only when a 64 bit clear cipher key is to be loaded directly into the working key register 20 from the host memory 2 via the buffer register 17. Only 56 of the 64 bits are stored in the working key register 20, the 8 parity bits being used only in the parity check circuit 21. The buffer register 17 is also provided with parallel input and output paths from and to a 64 bit data register 22 also divided into upper and lower data registers 23 and 24 of 32 bits each. The upper and lower data registers 23 and 24 each possesses parallel outputs and two sets of parallel inputs. The parallel inputs to the lower data register 24 being from the lower buffer register 19 and the upper data register 23 while the parallel inputs to the upper data register being from the upper buffer register 18 and from the lower data register 24 after modification by the cipher function circuits 25. The 64 bit master key is inputted to the crypto engine 16 on a serial by byte basis with each byte being checked for correct parity by the parity check circuit 26. As in the case of the cipher key transfer from the buffer register 17 to the working key register 20, only 56 of the 64 bits are stored in the key register 20, the 8 parity bits being used only in the parity check circuit 26. During the loading process, the key register 20 is configured as seven 8-bit shift right registers to accommodate the eight 7-bit bytes received from the MK memory 13 (or the buffer register 17). When the working key is used for enciphering, the key register 20 is configured as two 28 bit recirculating shift left registers and the working key is shifted left, in accordance with a predetermined shift schedule, after each round of operation of the cipher function so that no set of key bits once used to perform a cipher operation is used again in the same manner. Twenty-four parallel outputs from each of the two shift registers (48 bits) are used during each round of the encipher operation. The shift schedule provided is such that the working key is restored to its initial beginning position at the end of the complete encipher operation. When the working key is used for deciphering, the key register 20 is configured as two 28 bit recirculating shift right registers and the working key is shifted right in accordance with a predetermined shift schedule, after each round of operation of the cipher function, so that again no set of key bits is used again. As in the enciphering operation, twenty-four parallel outputs from each of the two shift registers (48 bits) are used during each round of the decipher operation. The shift schedule provided in this case is also such that the working key is restored to its initial beginning position at the end of the complete decipher operation. The cipher function circuits 25 perform a product cipher through successive application of a combination of non-linear substitutions and transpositions under control of the cipher working key. Sixteen rounds of the product cipher are executed in which the results of one round serves as the argument of the next round. Deciphering is accomplished by using the same key as for enciphering but with the shift schedule for shifting the key being altered so that the deciphering process is the reverse of the enciphering process, thus undoing in reverse order every step that was carried out during the enciphering process. During each round of the cipher function, the data contents of the upper data register 23, designated R, is enciphered under control of the working key, designated K, with the result being added modulo-2 to the contents of the lower data register 24, designated L, the operation being expressed as L.sym.f(R,K). At the end of the cipher round, the contents of the upper data register 23 is parallel transferred to the lower data register 24 while the output of the cipher function circuits 25 is parallel transferred to the upper data register 23 to form the arguments for the next round of the cipher function. After a total of sixteen rounds, which completes the total cipher function, the contents of the upper data register 23 is parallel transferred to the upper buffer register 18 while the output of the cipher function circuits 25 is parallel transferred to the lower buffer register 19. The transformed data contents of the buffer register 17 is then outputted via the bus out to the host memory 2. DSD COMMANDS AND ORDERS Input/output operations of an I/O device are generally directed by the execution of I/O instructions. In executing an I/O instruction, the channel generally provides an address field for addressing the I/O device, a command field for designating the operation to be performed and another address field for addressing the data field in memory from which data is fetched or to which data is stored. The data security device 11 of the present invention is responsive to seven types of commands from the processor as shown in the following table including the mnemonic and bit pattern of the command:
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COMMAND FORMAT
Command
Field
Name Mnemonic 0 1 2 3 4 5 6 7
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1. Reset Adapter
RST -- -- -- -- 0 0 1 0
2. Set Basic
SET BS -- -- -- -- 0 1 1 0
Status
3. Reset Basic
RST BS -- -- -- -- 0 1 0 0
Status
4. Read Basic
RD BS -- -- -- -- 0 1 1 1
Status
5. PIOW Data
PIOW -- -- -- -- 1 1 0 0
6. PIOR Data
PIOR -- -- -- -- 1 1 0 1
7. Write DSD
WR DSD w x y z 1 1 1 0
Order
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The following is a brief description of the function of each of the commands, the operation of which is described in greater detail in the aforementioned co-pending application Ser. No. 857,534. 1. Reset Adapter (RST)--This command causes a reset signal to be created to reset all counters, flip-flops and latches in the adapter and control sections of the DSD. 2. Set Basic Status (SET BS)--This command causes those latches in a status register of the DSD that correspond to 1's in the data field to be set to 1. 3. Reset Basic Status (RST BS)--This command is similar to the SET BS command except that the status latches corresponding to 1's in the data field are set to 0. 4. Read Basic Status (RD BS)--This command causes the contents of the status latches to be applied via the data bus in to the processor. 5. PIOW Data (PIOW)--This command causes the data field to be loaded into the buffer register or the bits 0, 1, 2, and 3 of the data field to be stored in the MK memory depending on the operation to be performed. 6. PIOR Data (PIOR)--This command causes the contents of the buffer register, with correct parity, to be applied via the data bus in to the processor. 7. Write DSD Order (WR DSD)--This command uses the four high order bits of the command field to designate cipher key handling and data processing orders as shown in the following table including the mnemonic and bit pattern of the order field:
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ORDER FORMAT
Order Command
Field Field
Name Mnemonic
W X Y Z 4 5 6 7
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Cipher Key Handling
1. Write Master Key
WMK 0 0 0 0 1 1 1 0
2. Decipher Key
DECK 0 1 1 1 1 1 1 0
3. Generate Random
GRN 1 1 1 1 1 1 1 0
Number
4. Encipher Master Key .phi.
EMK.phi.
1 1 0 0 1 1 1 0
5. Encipher Master Key 1
EMK1 1 1 0 1 1 1 1 0
6. Encipher Master Key 2
EMK2 1 1 0 1 1 1 1 0
7. Reencipher From
RFMK 0 1 0 1 1 1 1 0
Master Key
8. Reencipher To
RTMK 0 1 1 0 1 1 1 0
Master Key
Data Processing
1. Encipher ENC 1 0 0 0 1 1 1 0
2. Decipher DEC 1 0 1 0 1 1 1 0
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DSD FUNCTIONS DSD cryptographic functions may be performed by combinations of the previously defined commands or by a combination of functions. These functions require an input to the cryptographic apparatus consisting of a key parameter or a data parameter. The notation used to describe these functions will be expressed as follows: FUNCTION[KEY PARAMETER].fwdarw.OUTPUT or FUNCTION[DATA PARAMETER].fwdarw.OUTPUT and when functions are combined, the notation used to describe the combined functions will be expressed as follows: FUNCTION[KEY PARAMETER, DATA PARAMETER].fwdarw.OUTPUT The salient characteristics of host cyrptographic functions are that (1) the key parameter, is always in enciphered form and therefore must be internally deciphered by the crypto engine before the clear key is used and that (2) no function allows keys to become available in clear form. The descriptions that follow describe what each function does and how it is performed. These functions are described in greater detail in the aforementioned co-pending application Ser. No. 857,534 but a general description of these functions or combination of functions are given at this point to provide a better understanding of how various security applications may be performed. The descriptions may follow along with reference to FIG. 3 at times. In the diagrams which are referenced in the following, the cryptographic facility is shown in simplified block form for ease of understanding these operations. Before proceeding to the descriptions of the functions, a brief general description will be given of how the manual write key operation is performed. Referring now to FIG. 4, there is shown a simplified block diagram of a manual WMK operation. In the manual WMK operation, an EW switch is set on to enable writing into the MK memory 13 after which a MW switch is closed to enable manual writing and causing the current master key to be overwritten with whatever happens to be set in the data key entry switches. Following this, 16 sets of 4 bits (64 bits) are manually written into the MK memory 13 to complete the manual WMK operation. Referring now to FIG. 5, there is shown a simplified block diagram of a write master key (WMK) function. This function is carried out by the following sequence of commands: (1) WMK and (2) 16 PIOW's. In this operation, as in the manual WMK operation, the EW switch is previously set on to enable writing into the MK memory 13. The execution of this function causes the current master key in the master key memory 13 to be over-written with whatever happens to be present as bits 0, 1, 2 and 3 on the bus in. Thereafter, the crypto engine controls are set to allow a 64 bit master key KM to be written as a key parameter into the MK memory 13 by means of 16 successive PIOW data commands with the bits 0, 1, 2 and 3 in the data fields associated with the 16 PIOW data commands constituting the new master key. The notation WMK[KM].fwdarw.KM is used to describe this operation whereby the term WMK indicates the function, the contents of the brackets indicate the key parameter input to the MK memory 13 and the arrow points to the result. Referring now to FIG. 6, there is shown a simplified block diagram of a decipher key DECK function. This function is carried out by the following sequence of commands: (1) DECK and (2) 8 PIOW's. The execution of this function sets the crypto engine controls to first allow the master key KM in the MK memory 13 to be transferred to the crypto engine 16 as the working key. After or during the master key transfer, a 64 bit data block, defined as an operational key enciphered under the master key, is loaded as a key parameter into the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the 8 PIOW commands constituting the enciphered operational key. After the key parameter loading is completed, the crypto engine 16 performs a decipher operation to obtain the cipher key in clear form. The resultant clear cipher key does not leave the crypto engine 16 but is loaded back into the key register 20 of the crypto engine 16 replacing the master key as the working key. The notation DECK[E.sub.KM KO].fwdarw.KO is used to describe this operation whereby the term DECK indicates the function, the contents of the bracket indicate the key parameter which is inputted to the crypto engine 16 and the arrow points to the result. Referring now to FIG. 7, there is shown a simplified block diagram of an encipher (ENC) function. This function is carried out by the following sequence of commands: (1) ENC (2) 8 PIOW's and (3) 8 PIOR's. The execution of this function sets the crypto engine controls to the encipher mode of operation and allows a 64 bit message block of data to be loaded as a data parameter into the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the 8 PIOW commands constituting the message block of data to be enciphered. After the data parameter loading is completed, the crypto engine 16 performs an encipher operation to encipher the data parameter under the operational key presently stored in the working key register of the crypto device 16. The 64 bit enciphered result is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage is designated data fields of the host memory 2. The notation ENC[DATA].fwdarw.E.sub.KO DATA is used to describe this operation whereby the term ENC indicates the function, the contents of the bracket indicate the data parameter input to the crypto engine 16 and the arrow points to the result. Additionally, so long as the crypto engine controls remain set in the encipher mode of operation, then a message which consists of multiple 8 byte blocks of data may be enciphered by the crypto engine 16 by means of an encipher command followed by a series of successive 8 PIOW data commands and successive 8 PIOR data commands for each block of data. This message encipherment may be expressed by the notation: ENC[DATA.sub.1, DATA.sub.2 - - - - DATA.sub.N ].fwdarw.E.sub.KO (DATA.sub.1, DATA.sub.2 - - - - DATA.sub.N). Referring now to FIG. 8, there is shown a simplified block diagram of a decipher (DEC) function. This function is carried out by the following sequence of commands: (1) DEC (2) 8 PIOW's and (3) 8 PIOR's. The execution of this function sets the crypto engine controls to a decipher mode of operation and allows a 64 bit message block of enciphered data to be loaded as a data parameter into the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the 8 PIOW commands constituting the message block of enciphered data to be deciphered. After the data parameter loading is completed, the crypto engine 16 performs a decipher operation to decipher the data parameter under control of the operational key presently stored in the working key register of the crypto engine 16. The 64 bit deciphered result is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated data fields of the host memory 2. The notation DEC[ E.sub.KO DATA].fwdarw.DATA is used to describe this operation whereby the term DEC indicates the function, the contents of the bracket indicate the data parameter input to the crypto engine 16 and the arrow points to the results. Additionally, so long as the crypto engine controls remain set in the decipher mode of operation, then a message which consists of multiple blocks of enciphered data may be deciphered by the crypto engine 16 by means of a decipher command followed by a series of successive 8 PIOW data commands and successive 8 PIOR data commands for each block of enciphered data. This message decipherment may be expressed by the notation: DEC[E.sub.KO (DATA.sub.1,DATA.sub.2 - - - - DATA.sub.N)].fwdarw.DATA.sub.1,DATA.sub.2 - - - - DATA.sub.N. Referring now to FIG. 9, there is shown a simplified block diagram of a generate random number (GRN) function. This function is carried out by the following sequence of commands (1) GRN and (2) 8 PIOR's. Accordingly, in executing this function, the crypto engine controls are set to the encipher mode of operation and a variant KM3 of the master key KM in the MK memory 13 is transferred to the crypto engines 16 as the working key, the variant KM3 being obtained by inverting predefined bits of the master key. During the transfer of the master key variant KM3 to the crypto engine 16, a 64 bit count value CT from a non-resettable RN counter is loaded as a data parameter into the crypto engine 16. While a 64 bit RN counter is used in this operation to provide a pseudo random number, it should be apparent that it is well within the skill of the art to use a truly random number generator for generating a random value e.g. a noise generator. After the key and the data parameter loading is completed, the RN counter is stepped by one and the crypto engine 16 performs an encipher operation to encipher the data parameter CT under control of the variant KM3 of the master key presently stored in the working key register of the crypto device 16. The 64 bit enciphered result is a pseudo random number RN which is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated data fields of the host memory for use as a cryptographic key in a manner which will be described hereafter. The notation GRN[CT].fwdarw.(E.sub.KM3 CT)=RN is used to describe this operation whereby the tern GRN indicates the function, the contents of the bracket indicates the data parameter input to the crypto engine 16 and the arrow points to the result. Referring now to FIGS. 10, 11, and 12, there are shown simplified block diagrams of the encipher master key (EMK.phi., EMK1 and EMK2) function. This function is carried out by the following sequence of commands (1) EMK.phi. (2) 8 PIOW's and (3) 8 PIOR's; (1) EMK1 (2) 8 PIOW's and (3) 8 PIOR's and (1) EMK2 (2) 8 PIOW's and (3) 8 PIOR's. Accordingly, in executing these functions, the crypto engine controls are set to the encipher mode of operation causing, in the case of the EMK.phi. function, the unmodified master key in the MK memory 13 to be transferred to the crypto engine 16 as the working key, in the case of the EMK1 function, a first variant KM1 of the master key KM in the MK memory 13 to be transferred to the crypto engine 16 as the working key and in the case of the EMK2 function, a second variant KM2 of the master key KM in the MK memory 13 to be transferred to the crypto engine 16 as the working key. The first variant KM1 and second variant KM2 are obtained by inverting different predefined bits of the master key which are different from those used in the GRN function. After or during the master key transfer, a 64 bit data block, defined as an operational key, in the case of the EMK.phi. command, or as a secondary key encrypting key, in the case of the EMK1 and EMK2 commands, are loaded as a data parameter into the crypto engine 16 by means of 8 successive PIOW data commands with successive data fields associated with the 8 PIOW commands constituting the operational key or the secondary key encrypting key. After the key and data parameter loading is completed, the crypto engine 16 performs an encipher operation to encipher the data parameter under the master key or variant of the master key stored in the working key register of the crypto device 16. The 64 bit enciphered result is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated data fields of the host memory. The notation EMK.phi.[KO].fwdarw.E.sub.KM KO is used to describe the EMK.phi. operation while the notations EMK1[KEK].fwdarw.E.sub.KM1 KEK and EMK2[KEK].fwdarw.E.sub.KM2 KEK are used to describe the EMK1 and EMK2 operations whereby the terms EMK.phi., EMK1 and EMK2 indicate the function, the contents of the bracket indicate the data parameter input to the crypto engine 16 and the arrow points to the results. Referring now to FIG. 13, there is shown a simplified block diagram of an encipher data (ECPH) function. This function is a combination of the DECK function and the ENC function and is carried out by the following sequence of commands: (1) DECK (2) 8 PIOW's (3) ENC (4) 8 PIOW's and (5) 8 PIOR's. Accordingly, in executing this function, the crypto engine controls are first set to the decipher key mode of operation by the DECK command causing the master key KM in the master key memory 13 to be transferred as the working key to the working key register of the crypto engine 16. After or during the master key loading, the key parameter of the function, consisting of an operational key enciphered under the master key, is loaded into the crypto engine 16 by means of 8 successive PIOW data commands. The crypto engine 16 then performs a decipher key operation to obtain the operational key in clear form which is then loaded back in as the working key of the crypto engine 16 replacing the previously loaded master key. The crypto engine controls are then set to an encipher mode of operation by the ENC command and the data parameter of the function, consisting of clear data, is loaded into the crypto engine 16 by means of 8 successive PIOW data commands. The crypto engine 16 then performs an encipher operation to encipher the data parameter under the present operational key. The enciphered result is then transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated fields of the host memory 2. The notation ECPH[E.sub.KM KO,DATA].fwdarw.E.sub.KO DATA is used to describe this operation whereby the term ECPH indicates the function, the contents of the bracket indicate the successive key parameter and data parameter inputs to the crypto engine and the arrow points to the result. Referring now to FIG. 14, there is shown a simplified block diagram of a decipher data (DCPH) function. This function is a combination of the DECK function and the DEC function and is carried out by the following sequence of commands: (1) DECK (2) 8 PIOW's (3) DEC (4) 8 PIOW's and (5) 8 PIOR's. The first part of this function is identical to that for the encipher data function insofar as loading an operational key in clear form as the working key of the crypto engine 16. After the operational key loading is completed, the crypto engine controls are then set to a decipher mode of operation by the DEC command and the data parameter of the function, consisting of DATA enciphered under the operational key, is loaded into the crypto engine 16 by means of 8 successive PIOW data commands. The crypto engine 16 then performs the decipher operation to decipher the data parameter under control of the present operational key. The deciphered result is then transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated fields of the host memory 2. The notation DCPH[E.sub.KM KO,E.sub.KO DATA].fwdarw.DATA is used to describe this operation whereby the term DCPH indicates the function, the contents of the bracket indicate the successive key parameter and the data parameter inputs to the crypto engine and the arrow points to the result. Referring now to FIG. 15, there is shown a simplified block diagram of a reencipher from master key (RFMK) function. This is a privileged function and is carried out by the following sequence of commands: (1) RFMK, (2) 8 PIOW's, (3) 8 PIOW's and (4) 8 PIOR's. Accordingly, in executing this function, the crypto engine controls are first set to the decipher mode of operation by the RFMK command and a variant KM1 of the master key KM in the KM memory 13 is transferred to the crypto engine 16 as the working key, the variant KM1 being obtained by inverting the same predefined bits of the master key as in the EMK1 function. During or after the transfer of the master key variant KM1 to the crypto engine 16, a 64 bit data block, defined as a key encrypting key enciphered under the same variant of the master key is loaded as a key parameter to the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the commands constituting the enciphered key encrypting key. After the key parameter loading is completed, the crypto engine 16 performs a decipher operation to obtain the key encrypting key in clear form. The resultant clear key encrypting key does not leave the crypto engine 16 but is retained, with half the resultant clear key available at the upper data registers 23 of the crypto engine 16 and the other half available at the cipher function circuits 25. With the crypto engine control still set for the decipher mode of operation, a special key operation is now performed in which a 64 bit data block, defined as an operational key enciphered under the master key, is loaded as a data parameter into the buffer register 17 of the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the commands constituting the enciphered operational key. After the data parameter loading is completed, the contents of the buffer register 17 is transferred to the data register 22 of the crypto engine 16 while at the same time the contents of the upper data register 23 and the output of the cipher function circuits 25 are transferred to the buffer register 17 of the crypto engine 16. By this swapping action, the key encrypting key resulting from the first decipher operation now resides in the buffer register 17 of the crypto engine 16 while the enciphered operational key now resides in the data register 22 of the crypto engine 16. Because of the fact that a special key operation is being performed, the crypto engine control allows the master key KM in the master key memory 13 to now be transferred to the crypto engine 16 as the working key. After the master key loading is completed, the crypto engine 16 performs a second decipher operation to obtain the operational key in clear form. The resultant clear operational key does not leave the crypto engine 16 but is retained, with half of the resultant clear key available at the upper data register 23 of the crypto engine 16 and the other half available at the cipher function circuits 25. At this time, a special encipher operation is initiated with the crypto engine controls being set for an encipher mode of operation and the half of the clear operational key at the cipher function circuits 25 is transferred to the lower data register 24 so that the clear operational key is now fully available in data register 22. The key encrypting key resulting from the first decipher operation and presently residing in the buffer register 17 of the crypto engine 16 is now loaded as a working key into the key register 20 of the crypto engine 16. After key register loading operation is completed, the crypto engine 16 performes an encipher operation to encipher the operational key under the key encrypting key to complete the reencipherment function by which the operational key enciphered under the master key is now enciphered under the key encrypting key. The reenciphered result is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated data fields of the host memory. The notation RFMK[E.sub.KM1 KEK,E.sub.KM KO].fwdarw.E.sub.KEK KO is used to describe this operation whereby the term RFMK indicates the function, the contents of the brackets indicates the successive key parameter and data parameter inputs to the crypto engine and the arrow points to the results. Referring now to FIG. 16, there is shown a simplified block diagram of a reencipher to master key (RTMK) function. This is a privileged function and is carried out by the following sequence of commands: (1) RTMK, (2) 8 PIOW's, (3) 8 PIOW's and (4) 8 PIOR's. Accordingly, in executing this function the crypto engine controls are first set to the decipher mode of operation by the RTMK command and a variant KM2 of the master key KM in the MK memory 13 is transferred to the crypto engine 16 as the working key, the variant KM2 being obtained by inverting the same predefined bits of the master key as in the EMK2 function. During or after the transfer of the master key variant KM2 to the crypto engine 16, a 64 bit data block, defined as a key encrypting key enciphered under the same variant of the master key, is loaded as a key parameter into the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the 8 PIOW commands constituting the enciphered key encrypting key. After the key parameter loading is completed, the crypto engine 16 performs a decipher operation to obtain the key encrypting key in clear form. The resultant clear key encrypting key does not leave the crypto engine 16 but is loaded back into the key register 20 of the crypto engine 16 replacing the variant KM2 of the master key as the working key. With the crypto engine control still set for the decipher mode of operation, a second decipher operation is now performed in which a 64 bit data block, defined as an operational key enciphered under the same key encrypting key as is in the key register 20 of the crypto engine 16, is loaded as a data parameter into the crypto engine 16 by means of 8 successive PIOW data commands with the successive data fields associated with the command constituting the enciphered operational key. After the data parameter loading is completed, the second decipher operation is performed to obtain the operational key in clear form. The resultant clear operational key does not leave the crypto engine 16 but is retained in the buffer register 17 of the crypto engine 16. At this time, a special key operation is initiated to allow the master key KM in the MK memory 13 to now be transferred to the crypto engine 16 as the working key. After the master key loading is completed, the clear operational key, presently stored in the buffer register 17 of the crypto engine 16, is transferred to the data register 22 of the crypto engine 16 and a special encipher operation is initiated to set the crypto engine controls for an encipher mode of operation. The crypto engine 16 now performs an encipher operation to encipher the operational key under the host master key to complete the reencipherment function by which the operational key enciphered under the key encrypting key is reenciphered to the operational key enciphered under the host master key. The reenciphered result is transferred by a series of 8 PIOR commands from the crypto engine 16 for storage in designated data fields of the host memory. The notation RTMK[E.sub.KM2 KEK,E.sub.KEK KO].fwdarw.E.sub.KM KO is used to describe this operation whereby the term RTMK indicates the function, the contents of the bracket indicates the key parameter and data parameter input to the crypto engine and the arrow points to the result. FILE SECURITY APPLICATIONS The previous section provides a description of the various basic function, command and order capabilities of a host system having a data security device capable of performing a variety of cryptographic operations. Accordingly, the following descriptions will provide an explanation of how such a host system may be used in various file security applications involving a multiple domain data processing system. While the diagrams used to illustrate these applications are simplified block diagrams, it should be understood that the processing system represented by these diagrams is far more complex than that shown. However, this type of representation is used merely to simplify and aid in the understanding of the cryptographic applications to be described. It would be further understood that each host system contains a full complement of known programming support including an operating system, application programs, a storage access method which, in the present case, directs the transmission of file data between a host system and the storage media on which it is stored. FILE SECURITY IN MULTIPLE DOMAIN SYSTEMS Referring now to FIG. 17, there is shown a simplified conceptual block diagram of a multiple domain data processing system comprising a first Host.sup.j system having a data security device and a locally attached storage media such as a magnetic tape or disc for storing data files and a second Host.sup.k system having a data security device and a locally attached storage media which is transported from the Host.sup.j system for recovery at the Host.sup.k system. At host system initialization time, primary key encrypting keys KMH.phi..sup.j and KMH.phi..sup.k are generated in some random manner, as by coin or dice throwing, and then written into the MK memory of the respective host DSD's. Following this, secondary file key encrypting keys e.g. KEK.sup.jk and KEK.sup.kj are generated in clear form which if system generated are designated as cross-domain keys KNF.sup.jk and KNF.sup.kj or if privately generated, are designated as KNFP.sup.jk and KNFP.sup.kj. The clear cross-domain keys are then distributed in a secure manner, as by courier, registered mail, public telephone, etc. to authorized users at each host system. At the Host.sup.j, the Host.sup.j cross-domain key is protected by being enciphered under the first variant of the Host.sup.j master key as E.sub.KMH1.spsb.j KEK.sup.jk by an Encipher Master Key (EMK1) function and the Host.sup.k cross-domain key is protected by being enciphered under the second variant of the Host.sup.j master key as E.sub.KMH2.spsb.j KEK.sup.kj by an Encipher Master Key (EMK2) function. At the Host.sup.k, the Host.sup.k cross-domain key is protected by being enciphered under the first variant of the Host.sup.k master key as E.sub.KMH1.spsb.k KEK.sup.kj by an Encipher Master Key (EMK1) function and the Host.sup.j cross-domain key is protected by being enciphered under the second variant of the Host.sup.k master key as E.sub.KMH2.spsb.k KEK.sup.jk by an Encipher Master Key (EMK2) function. Following the encipherment of the cross-domain keys, they are written out to a cryptographic data set for storage until they are needed for a cryptographic operation. To establish a file recovery key between Host.sup.j system and Host.sup.k system, the next step is to generate a data encrypting key as the common operational key KF. This is initiated at one of the host systems, as for example Host.sup.j, by a procedure in which a pseudo random number is generated and defined as being the system file key enciphered under the Host.sup.j master key E.sub.KMH.phi..spsb.j KF.sup.j. This is in keeping with the rule that no key shall ever appear in the clear. The enciphered system file key is retained at the Host.sup.j system for an encipher operation in creating the data file. Additionally, in order to distribute the system file key from the sending Host.sup.j to the receiving Host.sup.k, Host.sup.J, using the enciphered cross-domain key E.sub.KMH1.spsb.j KEK.sup.jk and the enciphered session key E.sub.KMH.phi..spsb.j KF.sup.j, performs a privileged RFMK transformation function which reenciphers the system file key from encipherment under the Host.sup.j master key to encipherment under the sending cross-domain key i.e. from E.sub.KMH.phi..spsb.j KF.sup.j to E.sub.KEK.spsb.jk KF.sup.j as the file recovery key. Now having generated the enciphered system file key, E.sub.KMH.phi..spsb.j KF.sup.j, the Host.sup.j system can encipher data for the data file by performing the encipher ECPH function ECPH[E.sub.KMH.phi..spsb.j KF.sup.j,DATA].fwdarw.E.sub.KF.spsb.j DATA. In executing this function, a decipher key operation DECK(E.sub.KMH.phi..spsb.j KF.sup.j).fwdarw.KF.sup.j is first performed to obtain the file key in clear form as the working key, after which an encipher data operation ENC(DATA).fwdarw.E.sub.KF.spsb.j DATA is performed on Host.sup.j plaintext to obtain Host.sup.j ciphertext for storage as the data file. Following the completion of the encipher data operation, the parameter E.sub.KMH.phi..spsb.j KF.sup.j is erased from the host memory to prevent unauthorized decipherment of the enciphered data. This could be accomplished if an unauthorized person obtained a copy of the data file containing E.sub.KF.spsb.j DATA and a copy of E.sub.KMH.phi..spsb.j KF.sup.j if it were retained in the Host.sup.j memory by performing a decipher DCPH function DCPH[E.sub.KMH.phi..spsb.j KF.sup.j,E.sub.KF.spsb.j DATA].fwdarw.DATA. By erasing the parameter E.sub.KMH.phi..spsb.j KF.sup.J, which is no longer needed after the data file is created, this exposure is eliminated. Having now obtained the file recovery key E.sub.KEK.spsb.jk KF.sup.j and having enciphered the Host.sup.j data under the file key E.sub.KF.spsb.j DATA, the Host.sup.j system now causes the file recovery key, as header information, together with the enciphered data E.sub.KF.spsb.j DATA to be written on the secondary storage media as the data file. With this arrangement, the sensitive data is now protected and the file key under which it is protected is also protected and kept as header information with the enciphered data to permit recovery of the data file at the Host.sup.k system. The protected data file may now be transported by a courier, registered mail or the like or by teleprocessing means to the Host.sup.k system. It should be noted that the file recovery key was created as the operational key or primary file key enciphered under a host key encrypting key i.e. KEK.sup.jk rather than under the host master key. This enciphered file key is then used as header information in the data file. There are a number of advantages to this arrangement, namely, (1) if the host master key is changed there is no need to change the header information whereas if the file key is enciphered under the host master key, it would be necessary to change the header information everytime the host master key is changes, (2) by using a key encrypting key other than the Host.sup.j system master key there is no need to reveal the Host.sup.j system master key to the Host.sup.k system and (3) if an unauthorized person obtained access the the Host.sup.j system, he must still get access to the secondary file key enciphered under the appropriate variant of the host master key E.sub.KMH2.spsb.j KEK.sup.jk in order to perform the RTMK transformation function, which is itself a privileged function, to obtain the system file key enciphered under the Host.sup.j system master key, E.sub.KMH.phi..spsb.j KF.sup.j, for use in the non-privileged decipher DCPH function DCPH[E.sub.KMH.phi..spsb.j KF.sup.j, E.sub.KF.spsb.j DATA] to obtain the file data in clear form. However, the enciphered key encrypting key is not available in the form E.sub.KMH2 KEK.sup.jk at the Host.sup.j system but rather in the form E.sub.KMH1 KEK.sup.jk which therefore prevents this form of attack whereas, if the file key was enciphered under the host master key KMH.phi..sup.j rather than the key encrypting key KEK.sup.jk and an unauthorized person obtained access to the host system he need only perform the nonprivileged decipher DCPH function DCPH[E.sub.KMH.phi..spsb.j KF.sup.j DATA].fwdarw.DATA to obtain the file data in clear form which permits recovery of the data file at the other Host.sup.k system. The protected data file may now be transported by a human being, registered mail or the like or by a teleprocessing means to the Host.sup.k system. At the receiving Host.sup.k system, when it is desired to recover the data file and decipher the enciphered Host.sup.j data, it is necessary to perform a decipher DCPH function which requires the parameter E.sub.KMH.phi..spsb.k KF.sup.j. However, this parameter must be retrieved from the header information in the data file. Accordingly, the data file is read to the Host.sup.k memory and a transformation function is performed by the Host.sup.k system. This is accomplished by using the enciphered key encrypting key E.sub.KMH2.spsb.k KEK.sup.jk, accessed in an authorized manner and the enciphered file key E.sub.KEK.spsb.jk KF.sup.j read from the data file, to perform a privileged RTMK transformation operation which reenciphers the file key from encipherment under the key encrypting key to encipherment under the host master key i.e. from E.sub.KEK.spsb.jk KF.sup.j to E.sub.KMH.phi..spsb.k KF.sup.j. Now, using the parameter E.sub.KMH.phi..spsb.k KF.sup.j, the data file can be deciphered by performing a decipher DCPH function DCPH[E.sub.KMH.phi..spsb.k KF.sup.j,E.sub.KF.spsb.j DATA].fwdarw.DATA. In executing this operation, a decipher key operation DECK[E.sub.KMH.phi..spsb.k KF.sup.j ].fwdarw.KF.sup.j is first performed to obtain the file key in clear form as the working key, after which a decipher data operation DEC(E.sub.KF.spsb.j DATA).fwdarw.DATA is performed on the enciphered data read from the data file to obtain Host.sup.j ciphertext in clear form at Host.sup.k system. Data management is concerned with the control, retrieval and storage of information to be processed by a data processor. It generally includes an access method which is primarily responsible for organizing and moving information between a host memory and secondary storage media. There are numerous state of the art data management techniques in existence for managing the creation and recovery of data file, none of which are considered critical to the cryptographic techniques of the present invention. Therefore, in order to simplify and aid in understanding the cryptographic techniques of the present invention, as applied to various file security applications, the descriptions which follow assume that the host system contains the normal data management facilities for organizing and moving information between the host memory and secondary storage media and, therefore, the descriptions are generally restricted to the cryptographic techniques used to provide file security. Additionally, the descriptions which follow, in connection with FIGS. 18 through 21, are keyed to numbered notations in order to aid in understanding the sequence of operations performed in carrying out the file security application shown in each figure. FILE SECURITY IN MULTIPLE DOMAIN SYSTEMS USING CROSS-DOMAIN KEYS Referring now to FIG. 18, there is shown in block diagram form, | ||||||