Provided by: tpm2-tools_5.2-1build1_amd64 bug

NAME

       tpm2_incrementalselftest(1) - Request testing of specified algorithm list

SYNOPSIS

       tpm2_incrementalselftest [OPTIONS] ALG_SPEC_LIST

DESCRIPTION

       tpm2_incrementalselftest(1)  Request the TPM to perform testing on specified algorithm and
       print a list of algorithm scheduled to be tested OR remain to be tested but not scheduled.

       The main interest of this command is to reduce delays that might  occur  on  cryptographic
       operations as TPM must test the algorithm prior using it.

ALG_SPEC_LIST

       A  space-separated  list  of  algorithm  suite to be tested.  Algorithms should follow the
       “formatting standards”, see section “Algorithm Specifiers”.  Also, see section  “Supported
       Hash Algorithms” for a list of supported hash algorithms.

       If  ALG_SPEC_LIST  is  left  empty,  tpm2_incrementalselftest(1)  will  return the list of
       algorithms left to be tested.  Please note that in this  case  these  algorithms  are  NOT
       scheduled to be tested.

       If  ALG_SPEC_LIST  is  not  empty,  tpm2_incrementalselftest(1)  will  return  the list of
       algorithms that remains to be tested.  This list contains algorithms scheduled for testing
       AND  algorithms  that  remains  to  be  tested  and not yet scheduled.  This can occur for
       instance if all AES mode have not been already tested yet.

Output

       List of algorithms to  be  tested  (implying  scheduled)  or  remain  to  be  tested  (not
       scheduled) is also printed in YAML format.

       If  none  of  the  specified  algorithm  is printed, that means both that they are already
       tested AND that these algorithms won’t be tested again.

OPTIONS

       This tool accepts no tool specific options.

   References

Algorithm Specifiers

       Options that take algorithms support “nice-names”.

       There are two major algorithm specification string  classes,  simple  and  complex.   Only
       certain algorithms will be accepted by the TPM, based on usage and conditions.

   Simple specifiers
       These  are  strings  with  no  additional specification data.  When creating objects, non-
       specified portions of an object are assumed to defaults.  You can find the list  of  known
       “Simple Specifiers Below”.

   Asymmetric
       • rsa

       • ecc

   Symmetric
       • aes

       • camellia

   Hashing Algorithms
       • sha1

       • sha256

       • sha384

       • sha512

       • sm3_256

       • sha3_256

       • sha3_384

       • sha3_512

   Keyed Hash
       • hmac

       • xor

   Signing Schemes
       • rsassa

       • rsapss

       • ecdsa

       • ecdaa

       • ecschnorr

   Asymmetric Encryption Schemes
       • oaep

       • rsaes

       • ecdh

   Modes
       • ctr

       • ofb

       • cbc

       • cfb

       • ecb

   Misc
       • null

   Complex Specifiers
       Objects,  when  specified for creation by the TPM, have numerous algorithms to populate in
       the public data.  Things like type, scheme and asymmetric details, key size,  etc.   Below
       is the general format for specifying this data: <type>:<scheme>:<symmetric-details>

   Type Specifiers
       This  portion  of  the  complex algorithm specifier is required.  The remaining scheme and
       symmetric details will default based on the type specified and  the  type  of  the  object
       being created.

       • aes - Default AES: aes128

       • aes128<mode>  -  128  bit  AES with optional mode (ctr|ofb|cbc|cfb|ecb).  If mode is not
         specified, defaults to null.

       • aes192<mode> - Same as aes128<mode>, except for a 192 bit key size.

       • aes256<mode> - Same as aes128<mode>, except for a 256 bit key size.

       • ecc - Elliptical Curve, defaults to ecc256.

       • ecc192 - 192 bit ECC

       • ecc224 - 224 bit ECC

       • ecc256 - 256 bit ECC

       • ecc384 - 384 bit ECC

       • ecc521 - 521 bit ECC

       • rsa - Default RSA: rsa2048

       • rsa1024 - RSA with 1024 bit keysize.

       • rsa2048 - RSA with 2048 bit keysize.

       • rsa4096 - RSA with 4096 bit keysize.

   Scheme Specifiers
       Next, is an optional field, it can be skipped.

       Schemes are usually Signing  Schemes  or  Asymmetric  Encryption  Schemes.   Most  signing
       schemes  take  a  hash  algorithm  directly  following  the  signing  scheme.  If the hash
       algorithm is missing, it defaults to sha256.   Some  take  no  arguments,  and  some  take
       multiple arguments.

   Hash Optional Scheme Specifiers
       These  scheme  specifiers  are followed by a dash and a valid hash algorithm, For example:
       oaep-sha256.

       • oaep

       • ecdh

       • rsassa

       • rsapss

       • ecdsa

       • ecschnorr

   Multiple Option Scheme Specifiers
       This scheme specifier is followed by a count (max size UINT16) then followed by a  dash(-)
       and  a  valid  hash  algorithm.   *  ecdaa  For  example,  ecdaa4-sha256.   If no count is
       specified, it defaults to 4.

   No Option Scheme Specifiers
       This scheme specifier takes NO arguments.  * rsaes

   Symmetric Details Specifiers
       This field is optional, and defaults based on the type of object being  created  and  it’s
       attributes.  Generally, any valid Symmetric specifier from the Type Specifiers list should
       work.  If not specified, an asymmetric objects symmetric details defaults to aes128cfb.

   Examples
   Create an rsa2048 key with an rsaes asymmetric encryption scheme
       tpm2_create -C parent.ctx -G rsa2048:rsaes -u key.pub -r key.priv

   Create an ecc256 key with an ecdaa signing scheme with a count of 4 and sha384 hash
       /tpm2_create -C parent.ctx -G ecc256:ecdaa4-sha384 -u key.pub  -r  key.priv  cryptographic
       algorithms ALGORITHM.

COMMON OPTIONS

       This  collection  of options are common to many programs and provide information that many
       users may expect.

       • -h, --help=[man|no-man]: Display the tools manpage.  By default, it attempts  to  invoke
         the  manpager  for the tool, however, on failure will output a short tool summary.  This
         is the same behavior if the “man” option argument  is  specified,  however  if  explicit
         “man”  is  requested,  the tool will provide errors from man on stderr.  If the “no-man”
         option if specified, or the manpager fails, the short options will be output to stdout.

         To successfully use the manpages feature requires the manpages to  be  installed  or  on
         MANPATH, See man(1) for more details.

       • -v, --version: Display version information for this tool, supported tctis and exit.

       • -V,  --verbose:  Increase the information that the tool prints to the console during its
         execution.  When using this option the file and line number are printed.

       • -Q, --quiet: Silence normal tool output to stdout.

       • -Z, --enable-errata: Enable the application of errata fixups.  Useful if an errata fixup
         needs   to   be  applied  to  commands  sent  to  the  TPM.   Defining  the  environment
         TPM2TOOLS_ENABLE_ERRATA is equivalent.  information many users may expect.

TCTI Configuration

       The TCTI or “Transmission Interface” is the communication mechanism with the  TPM.   TCTIs
       can be changed for communication with TPMs across different mediums.

       To control the TCTI, the tools respect:

       1. The command line option -T or --tcti

       2. The environment variable: TPM2TOOLS_TCTI.

       Note: The command line option always overrides the environment variable.

       The current known TCTIs are:

       • tabrmd         -         The        resource        manager,        called        tabrmd
         (https://github.com/tpm2-software/tpm2-abrmd).  Note that tabrmd and  abrmd  as  a  tcti
         name are synonymous.

       • mssim - Typically used for communicating to the TPM software simulator.

       • device - Used when talking directly to a TPM device file.

       • none - Do not initalize a connection with the TPM.  Some tools allow for off-tpm options
         and thus support not using a TCTI.  Tools  that  do  not  support  it  will  error  when
         attempted  to  be used without a TCTI connection.  Does not support ANY options and MUST
         BE presented as the exact text of “none”.

       The arguments to either the command line option or the environment  variable  are  in  the
       form:

       <tcti-name>:<tcti-option-config>

       Specifying  an  empty string for either the <tcti-name> or <tcti-option-config> results in
       the default being used for that portion respectively.

   TCTI Defaults
       When a TCTI is not specified, the default TCTI is searched for using dlopen(3)  semantics.
       The  tools  will search for tabrmd, device and mssim TCTIs IN THAT ORDER and USE THE FIRST
       ONE FOUND.  You can query what TCTI will be chosen as the default by using the  -v  option
       to  print  the version information.  The “default-tcti” key-value pair will indicate which
       of the aforementioned TCTIs is the default.

   Custom TCTIs
       Any TCTI that implements the dynamic TCTI interface can be loaded.  The  tools  internally
       use  dlopen(3), and the raw tcti-name value is used for the lookup.  Thus, this could be a
       path to the shared library, or a library name as understood by dlopen(3) semantics.

TCTI OPTIONS

       This collection of options are used to configure the various known TCTI modules available:

       • device: For the device TCTI, the TPM character device file for use by  the  device  TCTI
         can be specified.  The default is /dev/tpm0.

         Example: -T device:/dev/tpm0 or export TPM2TOOLS_TCTI=“device:/dev/tpm0”mssim:  For  the  mssim  TCTI, the domain name or IP address and port number used by the
         simulator can be specified.  The default are 127.0.0.1 and 2321.

         Example:          -T          mssim:host=localhost,port=2321          or          export
         TPM2TOOLS_TCTI=“mssim:host=localhost,port=2321”abrmd:  For  the  abrmd  TCTI, the configuration string format is a series of simple key
         value pairs separated by a `,' character.  Each key and value string are separated by  a
         `=' character.

         • TCTI abrmd supports two keys:

           1. `bus_name' : The name of the tabrmd service on the bus (a string).

           2. `bus_type'  :  The  type  of  the dbus instance (a string) limited to `session' and
              `system'.

         Specify the tabrmd tcti name and a config string of bus_name=com.example.FooBar:

                \--tcti=tabrmd:bus_name=com.example.FooBar

         Specify the default (abrmd) tcti and a config string of bus_type=session:

                \--tcti:bus_type=session

         NOTE: abrmd and tabrmd are synonymous.  the various known TCTI modules.

EXAMPLES

   Request testing of RSA algorithm
              tpm2_incrementalselftest rsa

   Request testing of multiple algorithms
              tpm2_incrementalselftest rsa ecc xor aes cbc

NOTES

       Algorithm suite specified can imply either testing the combination or the complete  suite,
       depending on TPM manufacturer implementation.

       e.g : One TPM might only test AES with CTR mode if “aes ctr” is specified.  An other might
       also test complete AES mode list AND test ctr mode.

       If an algorithm has already been tested, this command won’t permit re-executing the  test.
       Only issuing tpm2_selftest(1) in full-test mode enabled will force re-testing.

Returns

       Tools can return any of the following codes:

       • 0 - Success.

       • 1 - General non-specific error.

       • 2 - Options handling error.

       • 3 - Authentication error.

       • 4 - TCTI related error.

       • 5 - Non supported scheme.  Applicable to tpm2_testparams.

BUGS

       Github Issues (https://github.com/tpm2-software/tpm2-tools/issues)

HELP

       See the Mailing List (https://lists.01.org/mailman/listinfo/tpm2)