tpm2_verifysignature(1) | General Commands Manual | tpm2_verifysignature(1) |
tpm2_verifysignature(1) - Validates a signature using the TPM.
tpm2_verifysignature [OPTIONS]
tpm2_verifysignature(1) - Uses loaded keys to validate a signature on a message with the message digest passed to the TPM. If the signature check succeeds, then the TPM will produce a TPMT_TK_VERIFIED. Otherwise, the TPM shall return TPM_RC_SIGNATURE. If object references an asymmetric key, only the public portion of the key needs to be loaded. If object references a symmetric key, both the public and private portions need to be loaded.
Context object for the key context used for the operation. Either a file or a handle number. See section “Context Object Format”.
The hash algorithm used to digest the message. Algorithms should follow the “formatting standards”, see section “Algorithm Specifiers”. Also, see section “Supported Hash Algorithms” for a list of supported hash algorithms.
The message file, containing the content to be digested.
The input hash file, containing the hash of the message. If this option is selected, then the message (-m) and algorithm (-g) options do not need to be specified.
The input signature file of the signature to be validated.
The signing scheme that was used to sign the message. This option should only be specified if the signature comes in from a non tss standard, like openssl. See “Signature format specifiers” for more details. The tss format contains the signature metadata required to understand it’s signature scheme.
Signing schemes should follow the “formatting standards”, see section “Algorithm Specifiers”.
Deprecated. Same as --scheme.
The ticket file to record the validation structure.
The type of a context object, whether it is a handle or file name, is determined according to the following logic in-order:
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.
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.
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>
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.
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.
These scheme specifiers are followed by a dash and a valid hash algorithm, For example: oaep-sha256.
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.
This scheme specifier takes NO arguments. * rsaes
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.
tpm2_create -C parent.ctx -G rsa2048:rsaes -u key.pub -r key.priv
/tpm2_create -C parent.ctx -G ecc256:ecdaa4-sha384 -u key.pub -r key.priv cryptographic algorithms ALGORITHM.
This collection of options are common to many programs and provide information that many users may expect.
To successfully use the manpages feature requires the manpages to be installed or on MANPATH, See man(1) for more details.
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:
Note: The command line option always overrides the environment variable.
The current known TCTIs are:
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.
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.
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.
This collection of options are used to configure the various known TCTI modules available:
Example: -T device:/dev/tpm0 or export TPM2TOOLS_TCTI=“device:/dev/tpm0”
Example: -T mssim:host=localhost,port=2321 or export TPM2TOOLS_TCTI=“mssim:host=localhost,port=2321”
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.
Format selection for the signature output file. tss (the default) will output a binary blob according to the TPM 2.0 specification and any potential compiler padding. The option plain will output the plain signature data as defined by the used cryptographic algorithm.
tpm2_createprimary -C e -c primary.ctx tpm2_create -G rsa -u rsa.pub -r rsa.priv -C primary.ctx tpm2_load -C primary.ctx -u rsa.pub -r rsa.priv -c rsa.ctx echo "my message > message.dat tpm2_sign -c rsa.ctx -g sha256 -m message.dat -s sig.rssa tpm2_verifysignature -c rsa.ctx -g sha256 -m message.dat -s sig.rssa
# Generate an ECC key openssl ecparam -name prime256v1 -genkey -noout -out private.ecc.pem openssl ec -in private.ecc.pem -out public.ecc.pem -pubout # Generate a hash to sign (OSSL needs the hash of the message) echo "data to sign" > data.in.raw sha256sum data.in.raw | awk '{ print "000000 " $1 }' | \ xxd -r -c 32 > data.in.digest # Load the private key for signing tpm2_loadexternal -Q -G ecc -r private.ecc.pem -c key.ctx # Sign in the TPM and verify with OSSL tpm2_sign -Q -c key.ctx -g sha256 -d data.in.digest -f plain -s data.out.signed openssl dgst -verify public.ecc.pem -keyform pem -sha256 \ -signature data.out.signed data.in.raw # Sign with openssl and verify with TPM openssl dgst -sha256 -sign private.ecc.pem -out data.out.signed data.in.raw tpm2_verifysignature -Q -c key.ctx -g sha256 -m data.in.raw -f ecdsa \ -s data.out.signed
Tools can return any of the following codes:
Github Issues (https://github.com/tpm2-software/tpm2-tools/issues)
See the Mailing List (https://lists.linuxfoundation.org/mailman/listinfo/tpm2)
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