mirror of
https://github.com/tpm2dev/tpm.dev.tutorials.git
synced 2024-11-14 10:42:11 +00:00
395 lines
15 KiB
Markdown
395 lines
15 KiB
Markdown
# Passing a secret to a TPM using only the public key of Endorsement Key (EK)
|
|
|
|
This is example code to pass a secret to a system by just knowing its endorsenment key's public key.
|
|
We will be using the current (commit 07a92e9fa75548ea102ce90b3b6182093b3f7a73 or later) master branch of https://github.com/tpm2-software/tpm2-pytss
|
|
|
|
The terms for the systems are `client`, the system we want to pass the secret to and `server`, the system which has the secret but doesn't need a TPM.
|
|
One assumtion that will be made is that you already have the EKpub for the remote system on the local system, and trust it.
|
|
While we will use the EK in this guide any key accepted by ActivateCredential should work.
|
|
|
|
## Background
|
|
|
|
What we want is something akin to asymmetric encryption, with the local
|
|
system encrypting to the public key of the remote system. The local
|
|
system would send the ciphertext to the remote system, and the remote
|
|
system would decrypt it using its private key.
|
|
|
|
The TPM does support plain asymmetric decryption using
|
|
`TPM2_RSA_Decrypt()`. However, the `EK` is a [restricted
|
|
key](/Intro/README.md#Restricted-Cryptographic-Keys), specifically a
|
|
[restricted decryption key](/Intro/README.md#Restricted-Decryption-Keys)
|
|
which means that `TPM2_RSA_Decrypt()` will not work.
|
|
|
|
The TPM supports two constrained asymmetric decryption operations with
|
|
[restricted decryption
|
|
keys](/Intro/README.md#Restricted-Decryption-Keys):
|
|
|
|
- [`TPM2_Import()`](/TPM-Commands/TPM2_Import.md)
|
|
- [`TPM2_ActivateCredential()`](/TPM-Commands/TPM2_ActivateCredential.md)
|
|
|
|
The sender sides of those two functions are, respectively:
|
|
|
|
- [`TPM2_Duplicate()`](/TPM-Commands/TPM2_Duplicate.md)
|
|
- [`TPM2_MakeCredential()`](/TPM-Commands/TPM2_MakeCredential.md)
|
|
|
|
`TPM2_Duplicate()`/`TPM2_Import()` are specifically about sharing
|
|
private key objects from one TPM to another. We won't use those here.
|
|
|
|
[`TPM2_MakeCredential()`](/TPM-Commands/TPM2_MakeCredential.md) allows
|
|
us to encrypt a small secret (e.g., an AES key) to a remote system's
|
|
`EKpub`, and then the remote system can decrypt that with its `EK` using
|
|
[`TPM2_ActivateCredential()`](/TPM-Commands/TPM2_ActivateCredential.md).
|
|
|
|
The key background concepts here are:
|
|
|
|
- [restricted decryption keys](/Intro/README.md#Restricted-Decryption-Keys),
|
|
- and access controlled decryption with restricted decryption keys.
|
|
|
|
Most importantly,
|
|
[`TPM2_MakeCredential()`](/TPM-Commands/TPM2_MakeCredential.md) allows
|
|
the sender to specify an authorization policy that the caller of
|
|
[`TPM2_ActivateCredential()`](/TPM-Commands/TPM2_ActivateCredential.md)
|
|
must meet in order for it to be willing to decrypt the ciphertext.
|
|
|
|
> Note that `TPM2_MakeCredential()` can be implemented entirely in
|
|
> software.
|
|
|
|
> Note that duplicating a key that is fixed to TPMs requires using
|
|
> `TPM2_Duplicate()` on that TPM, otherwise if the key is not fixed to
|
|
> the TPM then `TPM2_Duplicate()` can be implemented in software.
|
|
|
|
## Concept
|
|
|
|
`TPM2_MakeCredential()` requires three inputs. Besides the target's
|
|
`EKpub` and the small secret to send to it, `TPM2_MakeCredential()` also
|
|
requires the [cryptographic name](/Intro/README.md#Cryptographic-Object-Naming)
|
|
of a key object that must reside on the target system's TPM -- this is
|
|
known as the _activation object_.
|
|
|
|
The key insight is that the actual public key of the object named by the
|
|
activation object name input of `TPM2_MakeCredential()` is not used at
|
|
all. Neither does `TPM2_ActivateCredential()` use the private key of
|
|
that object. The only things that matter about the activation object
|
|
are that:
|
|
|
|
a) it must exist on the target system,
|
|
b) its cryptographic name must be the same as was used on the sender side,
|
|
c) and that the caller of `TPM2_ActivateCredential()` must satisfy the activation object's [_authorization policy_](/Intro/README.md#Policies) (_if_ `adminWithPolicy` is set as an attribute of the activation object).
|
|
|
|
> NOTE: The cryptographic name of an object binds the authorization
|
|
> policy set on that object. Therefore the caller of
|
|
> `TPM2_MakeCredential()` specifies an authorization policy that the
|
|
> caller of `TPM2_ActivateCredential()` must meet if the
|
|
> `adminWithPolicy` attribute is set on the activation object.
|
|
|
|
> NOTE: Learn more about [restricted keys](/Intro/README.md#Restricted-Cryptographic-Keys),
|
|
> [authorization policies](/Intro/README.md#Policies), and
|
|
> user roles in our [introductory tutorial](/Intro/README.md).
|
|
|
|
Since the private and public key parts of the activation object are not
|
|
used and are irrelevant, they can even be fixed and published for all to
|
|
see, even the private key.
|
|
|
|
By using a well-known activation key we can avoid having to know the
|
|
cryptographic name of some unique object on the remote system's TPM!
|
|
|
|
Or we can generate a unique key but send its private part in the clear
|
|
to the remote system.
|
|
|
|
Thus we need only know the target system's TPM's `EKpub`.
|
|
|
|
## server script
|
|
|
|
```python
|
|
#!/usr/bin/python3
|
|
|
|
import sys
|
|
from tpm2_pytss import *
|
|
from tpm2_pytss.makecred import MakeCredential
|
|
from cryptography.hazmat.primitives.asymmetric import ec
|
|
from cryptography.hazmat.backends import default_backend
|
|
from cryptography.hazmat.primitives.serialization import Encoding, PublicFormat, PrivateFormat, NoEncryption
|
|
|
|
def main(ekpath, publicpath, sensitivepath, credpath, secretpath, oursecret):
|
|
# first read the EK and unmarshal it
|
|
with open(ekpath, 'rb') as ef:
|
|
ekb = ef.read()
|
|
ekpub, _ = TPM2B_PUBLIC.Unmarshal(ekb)
|
|
|
|
# Now we generate the temporary key pair
|
|
# We are using ECC keys here as they are generally fast to generate, but RSA should work as well
|
|
# We will use the curve SECP256R1 as it should work on all TPMs
|
|
# One could use a well known/the same pre-generated key for multiple systems
|
|
privatekey = ec.generate_private_key(ec.SECP256R1, backend=default_backend())
|
|
publickey = privatekey.public_key()
|
|
|
|
# Now it's time to TPM structures from the keys
|
|
# First we need to encode it due to how the tpm2_pytss API currently works
|
|
privateenc = privatekey.private_bytes(Encoding.DER, PrivateFormat.PKCS8, NoEncryption())
|
|
publicenc = publickey.public_bytes(Encoding.DER, PublicFormat.SubjectPublicKeyInfo)
|
|
sensitive = TPM2B_SENSITIVE.fromPEM(privateenc)
|
|
# by objectAttributes to 0 we reduce the change that keys will be used for anything
|
|
public = TPM2B_PUBLIC.fromPEM(publicenc, objectAttributes=0)
|
|
# the same applices to authPolicy
|
|
public.publicArea.authPolicy = b"\x00" * 32
|
|
|
|
# now it's time to run the MakeCredential part, using the software implementation in tpm2_pytss
|
|
# the API is slight different to the standard, but behaves the same
|
|
credblob, secret = MakeCredential(ekpub, oursecret, bytes(public.getName()))
|
|
|
|
# time to marshal the structures and save them to disk so we can send them the remote system
|
|
pubb = public.Marshal()
|
|
with open(publicpath, 'xb') as pubf:
|
|
pubf.write(pubb)
|
|
sensb = sensitive.Marshal()
|
|
with open(sensitivepath, 'xb') as sensf:
|
|
sensf.write(sensb)
|
|
credb = credblob.Marshal()
|
|
with open(credpath, 'xb') as credf:
|
|
credf.write(credb)
|
|
secretb = secret.Marshal()
|
|
with open(secretpath, 'xb') as secretf:
|
|
secretf.write(secretb)
|
|
|
|
|
|
if __name__ == '__main__':
|
|
if len(sys.argv) < 6:
|
|
sys.stderr.write(f"usage: {sys.argv[0]} ek-public temp-public temp-sensitive credblob secret\n")
|
|
exit(1)
|
|
main(sys.argv[1], sys.argv[2], sys.argv[3], sys.argv[4], sys.argv[5], b"example secret")
|
|
```
|
|
|
|
Arguments to the script is the following:
|
|
ek-public: the path to the public part of the EK
|
|
temp-public: where to save the public part of the temporary key
|
|
temp-sensitive: where to save the sensitive part of the temporary key
|
|
credlob: where to save the encrypted credential generated by MakeCredential
|
|
secret: where to save the encrypted secret generated by MakeCredential
|
|
|
|
## client script
|
|
|
|
```python
|
|
#!/usr/bin/python3
|
|
|
|
|
|
import sys
|
|
from tpm2_pytss import *
|
|
|
|
def unmarshal_tools_context(ekb):
|
|
ekctx = TPMS_CONTEXT()
|
|
magic = int.from_bytes(ekb[0:4], byteorder='big')
|
|
version = int.from_bytes(ekb[4:8], byteorder='big')
|
|
ekctx.hierarchy = int.from_bytes(ekb[8:12], byteorder='big')
|
|
ekctx.savedHandle = int.from_bytes(ekb[12:16], byteorder='big')
|
|
ekctx.sequence = int.from_bytes(ekb[16:24], byteorder='big')
|
|
ekctx.contextBlob, _ = TPM2B_CONTEXT_DATA.Unmarshal(ekb[24:])
|
|
return ekctx
|
|
|
|
def eksession(ectx):
|
|
session = ectx.StartAuthSession(
|
|
ESYS_TR.NONE,
|
|
ESYS_TR.NONE,
|
|
None,
|
|
TPM2_SE.POLICY,
|
|
TPMT_SYM_DEF(algorithm=TPM2_ALG.NULL),
|
|
TPM2_ALG.SHA256,
|
|
)
|
|
|
|
ectx.PolicySecret(
|
|
ESYS_TR.RH_ENDORSEMENT,
|
|
session,
|
|
TPM2B_NONCE()._cdata,
|
|
TPM2B_DIGEST()._cdata,
|
|
TPM2B_NONCE()._cdata,
|
|
0,
|
|
session1=ESYS_TR.PASSWORD,
|
|
)
|
|
|
|
return session
|
|
|
|
def main(ekpath, publicpath, sensitivepath, credpath, secretpath):
|
|
# time to setup a ESAPI context, we will use the default TCTI for the system
|
|
ectx = ESAPI()
|
|
|
|
# Time to load the EK context, by using tpm2_createek there is no reason the implement the whole setup in this example code
|
|
with open(ekpath, 'rb') as ekf:
|
|
ekb = ekf.read()
|
|
ekctx = unmarshal_tools_context(ekb)
|
|
ekhandle = ectx.ContextLoad(ekctx)
|
|
|
|
# now lets setup the standard EK policy session
|
|
session = eksession(ectx)
|
|
|
|
# Now we should read, unmarshal and load the temporary key pair
|
|
with open(publicpath, 'rb') as pubf:
|
|
pubb = pubf.read()
|
|
public, _ = TPM2B_PUBLIC.Unmarshal(pubb)
|
|
with open(sensitivepath, 'rb') as sensf:
|
|
sensb = sensf.read()
|
|
sensitive, _ = TPM2B_SENSITIVE.Unmarshal(sensb)
|
|
print(sensitive.sensitiveArea.authValue.size, public.publicArea.authPolicy.size)
|
|
# We will load it under the NULL hierarchy as that is the only hierarchy allowing both the public and private part to be loaded for external keys
|
|
handle = ectx.LoadExternal(sensitive, public, ESYS_TR.RH_NULL)
|
|
|
|
|
|
# Time to read and unmarshal the credential and secret for ActivateCredential
|
|
with open(credpath, 'rb') as credf:
|
|
credb = credf.read()
|
|
credblob, _ = TPM2B_ID_OBJECT.Unmarshal(credb)
|
|
with open(secretpath, 'rb') as secretf:
|
|
secretb = secretf.read()
|
|
secret, _ = TPM2B_ENCRYPTED_SECRET.Unmarshal(secretb)
|
|
|
|
# Well, now there is nothing left but calling ActivateCredential and getting our secret on the remove system!
|
|
oursecret = ectx.ActivateCredential(handle, ekhandle, credblob, secret, session2=session)
|
|
|
|
print(f"we got the secret: {bytes(oursecret)}")
|
|
|
|
if __name__ == '__main__':
|
|
if len(sys.argv) < 6:
|
|
sys.stderr.write(f"usage: {sys.argv[0]} ek-ctx temp-public temp-sensitive credblob secret\n")
|
|
exit(1)
|
|
main(sys.argv[1], sys.argv[2], sys.argv[3], sys.argv[4], sys.argv[5])
|
|
```
|
|
|
|
Generate the EK context with `tpm2_createek -c ek.ctx`
|
|
The arguments are:
|
|
ek-ctx: the context generated by tpm2_createek
|
|
temp-public: the temp-public output from the local system script
|
|
temp-sensitive: the temp-sensitive output from the local system script
|
|
credblob: the credblob output from the local system script
|
|
secret: the secret output from the local system script
|
|
|
|
## Example (bash)
|
|
|
|
This example uses two bash scripts:
|
|
|
|
- [`send-to-tpm.sh`](send-to-tpm.sh)
|
|
- [`tpm-receive.sh`](tpm-receive.sh)
|
|
|
|
Usage messages for those two scripts:
|
|
|
|
```
|
|
Usage: send-to-tpm.sh EK-PUB-FILE SECRET-FILE OUT-FILE [POLICY-CMD [ARGS [\; ...]]]
|
|
send-to-tpm.sh -P well-known-key-name EK-PUB-FILE SECRET-FILE OUT-FILE
|
|
|
|
Options:
|
|
|
|
-h This help message.
|
|
-P WKname Use the given cryptographic name binding a policy for
|
|
recipient to meet.
|
|
-f Overwrite OUT-FILE.
|
|
-x Trace this script.
|
|
```
|
|
|
|
```
|
|
Usage: receive.sh CIPHERTEXT-FILE OUT-FILE [POLICY-CMD [ARGS] [;] ...]
|
|
|
|
"Activates" (decrypts) CIPHERTEXT-FILE made with TPM2_MakeCredential and
|
|
writes the plaintext to OUT-FILE.
|
|
|
|
The POLICY-CMD and arguments are one or more commands that must
|
|
leave a policy digest in a file named 'policy' in the current
|
|
directory (which will be a temporary directory).
|
|
|
|
Options:
|
|
|
|
-h This help message.
|
|
-f Overwrite OUT-FILE.
|
|
-x Trace this script.
|
|
```
|
|
|
|
Example (without policy, both scripts running on the same system):
|
|
|
|
```
|
|
: ; # NOTE: The shell prompt ($PS1) is set to ': ; ' to make it easy to
|
|
: ; # cut-and-paste.
|
|
: ;
|
|
: ; # Get the EKpub:
|
|
: ; tpm2 createek --ek-context ek.ctx --public ek.pub
|
|
: ;
|
|
: ; # Make a small secret:
|
|
: ; echo hello world > secret.txt
|
|
: ;
|
|
: ; # Make ciphertext:
|
|
: ; /tmp/send-to-tpm.sh -f ek.pub /tmp/secret /tmp/cipher
|
|
: ;
|
|
: ; # Decrypt ciphertext:
|
|
: ; /tmp/receive.sh -f /tmp/cipher /tmp/plain
|
|
name:
|
|
000b9f40e7a7a85bcc39bba777b7eda5764d91a28512d91d395ca114b14621ae321e
|
|
837197674484b3f81a90cc8d46a5d724fd52d76e06520b64f2a1da1b331469aa
|
|
certinfodata:68656c6c6f20776f726c640a
|
|
: ;
|
|
: ; # Show plaintext:
|
|
: ; cat /tmp/plain
|
|
hello world
|
|
```
|
|
|
|
Example (with policy, both scripts running on the same system):
|
|
|
|
```
|
|
: ; # NOTE: The shell prompt ($PS1) is set to ': ; ' to make it easy to
|
|
: ; # cut-and-paste.
|
|
: ;
|
|
: ; # Get the EKpub:
|
|
: ; tpm2 createek --ek-context ek.ctx --public ek.pub
|
|
: ;
|
|
: ; # Make a small secret:
|
|
: ; echo hello world > secret.txt
|
|
: ;
|
|
: ; /tmp/send-to-tpm.sh -f ek.pub /tmp/secret /tmp/cipher \
|
|
> tpm2 policysecret --session session.ctx \
|
|
> --object-context endorsement -L policy \; \
|
|
> tpm2 policycommandcode -S session.ctx -L policy \
|
|
> TPM2_CC_ActivateCredential
|
|
837197674484b3f81a90cc8d46a5d724fd52d76e06520b64f2a1da1b331469aa
|
|
cd9917cf18c3848c3a2e606986a066c68142f9bc2710a278287a650ca3bbf245
|
|
: ;
|
|
: ; /tmp/tpm-receive.sh -f /tmp/cipher /tmp/plain \
|
|
> tpm2 policysecret --session session.ctx \
|
|
--object-context endorsement \
|
|
-L policy \; \
|
|
tpm2 policycommandcode -S session.ctx -L policy \
|
|
TPM2_CC_ActivateCredential
|
|
837197674484b3f81a90cc8d46a5d724fd52d76e06520b64f2a1da1b331469aa
|
|
cd9917cf18c3848c3a2e606986a066c68142f9bc2710a278287a650ca3bbf245
|
|
name: 000bec987554f57b9918285794542c05549aa778832be169351494066907d6d95abf
|
|
837197674484b3f81a90cc8d46a5d724fd52d76e06520b64f2a1da1b331469aa
|
|
837197674484b3f81a90cc8d46a5d724fd52d76e06520b64f2a1da1b331469aa
|
|
cd9917cf18c3848c3a2e606986a066c68142f9bc2710a278287a650ca3bbf245
|
|
certinfodata:68656c6c6f20776f726c640a
|
|
: ; cat /tmp/plain
|
|
hello world
|
|
: ;
|
|
```
|
|
|
|
You can pass policy commands to the `send-to-tpm.sh` and `tpm-receive.sh`
|
|
commands as arguments, with multiple policy commands separated by a
|
|
single semi-colon (quoted, to avoid evaluation by the shell):
|
|
|
|
```bash
|
|
send-to-tpm.sh ek.pub /tmp/secret /tmp/cipher \
|
|
tpm2 policypcr -S session.ctx -l "sha256:0,1,2,3" -f $PWD/pcr.dat \
|
|
-L policy \; \
|
|
tpm2 policycommandcode -S session.ctx -L policy TPM2_CC_ActivateCredential
|
|
```
|
|
|
|
## Issues
|
|
|
|
- The secret sent this way has to be small: no larger than the digest
|
|
size for the digest algorithm being used.
|
|
|
|
If the application needs to send larger secrets, then it should
|
|
generate an AES key and send that as the small secret, then encrypt
|
|
the larger secret in the AES key and send that ciphertext. (But
|
|
don't forget to also include an HMAC or MAC of the ciphertext to make
|
|
detection of errors / tampering possible.)
|
|
|
|
- There is no protection against replay attacks in this example.
|
|
|
|
Replay protection can be added by adding a timestamp to the secret
|
|
data, and by using a replay cache on the remote system.
|
|
|
|
- There is no authentication of the sender. To authenticate the sender
|
|
simply add a digital signature of the ciphertext.
|