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add example code + basic concept of passing a secret to a TPM just knowing the EK
Signed-off-by: Erik Larsson <who+github@cnackers.org>
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Attestation/ek-secret.md
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Attestation/ek-secret.md
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# `Passing a secret to a TPM using only the EK`
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This is example code to pass a secret to a system by just knowing the endorsenment key.
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We will be using the current (commit 07a92e9fa75548ea102ce90b3b6182093b3f7a73 or later) master branch of https://github.com/tpm2-software/tpm2-pytss
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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.
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One assumtion that will be made is that you already have the EKpub for the remote system on the local system, and trust it.
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While we will use the EK in this guide any key accepted by ActivateCredential should work.
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## Concept
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The concept is that the key being activated by a call to ActivateCredential on the remote system doesn't have to be generated on the TPM, as long as the public and private parts are loaded it will succeed.
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By generating a temporary key pair on the local system we can run MakeCredential with the remote system EK, name of the locally generated key and the secret.
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## server script
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```python
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#!/usr/bin/python3
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import sys
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from tpm2_pytss import *
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from tpm2_pytss.makecred import MakeCredential
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from cryptography.hazmat.primitives.asymmetric import ec
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from cryptography.hazmat.backends import default_backend
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from cryptography.hazmat.primitives.serialization import Encoding, PublicFormat, PrivateFormat, NoEncryption
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def main(ekpath, publicpath, sensitivepath, credpath, secretpath, oursecret):
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# first read the EK and unmarshal it
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with open(ekpath, 'rb') as ef:
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ekb = ef.read()
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ekpub, _ = TPM2B_PUBLIC.Unmarshal(ekb)
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# Now we generate the temporary key pair
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# We are using ECC keys here as they are generally fast to generate, but RSA should work as well
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# We will use the curve SECP256R1 as it should work on all TPMs
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# One could use a well known/the same pre-generated key for multiple systems
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privatekey = ec.generate_private_key(ec.SECP256R1, backend=default_backend())
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publickey = privatekey.public_key()
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# Now it's time to TPM structures from the keys
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# First we need to encode it due to how the tpm2_pytss API currently works
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privateenc = privatekey.private_bytes(Encoding.DER, PrivateFormat.PKCS8, NoEncryption())
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publicenc = publickey.public_bytes(Encoding.DER, PublicFormat.SubjectPublicKeyInfo)
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sensitive = TPM2B_SENSITIVE.fromPEM(privateenc)
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# by objectAttributes to 0 we reduce the change that keys will be used for anything
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public = TPM2B_PUBLIC.fromPEM(publicenc, objectAttributes=0)
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# the same applices to authPolicy
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public.publicArea.authPolicy = b"\x00" * 32
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# now it's time to run the MakeCredential part, using the software implementation in tpm2_pytss
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# the API is slight different to the standard, but behaves the same
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credblob, secret = MakeCredential(ekpub, oursecret, bytes(public.getName()))
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# time to marshal the structures and save them to disk so we can send them the remote system
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pubb = public.Marshal()
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with open(publicpath, 'xb') as pubf:
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pubf.write(pubb)
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sensb = sensitive.Marshal()
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with open(sensitivepath, 'xb') as sensf:
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sensf.write(sensb)
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credb = credblob.Marshal()
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with open(credpath, 'xb') as credf:
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credf.write(credb)
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secretb = secret.Marshal()
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with open(secretpath, 'xb') as secretf:
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secretf.write(secretb)
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if __name__ == '__main__':
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if len(sys.argv) < 6:
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sys.stderr.write(f"usage: {sys.argv[0]} ek-public temp-public temp-sensitive credblob secret\n")
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exit(1)
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main(sys.argv[1], sys.argv[2], sys.argv[3], sys.argv[4], sys.argv[5], b"example secret")
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```
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Arguments to the script is the following:
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ek-public: the path to the public part of the EK
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temp-public: where to save the public part of the temporary key
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temp-sensitive: where to save the sensitive part of the temporary key
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credlob: where to save the encrypted credential generated by MakeCredential
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secret: where to save the encrypted secret generated by MakeCredential
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## client script
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```python
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#!/usr/bin/python3
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import sys
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from tpm2_pytss import *
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def unmarshal_tools_context(ekb):
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ekctx = TPMS_CONTEXT()
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magic = int.from_bytes(ekb[0:4], byteorder='big')
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version = int.from_bytes(ekb[4:8], byteorder='big')
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ekctx.hierarchy = int.from_bytes(ekb[8:12], byteorder='big')
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ekctx.savedHandle = int.from_bytes(ekb[12:16], byteorder='big')
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ekctx.sequence = int.from_bytes(ekb[16:24], byteorder='big')
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ekctx.contextBlob, _ = TPM2B_CONTEXT_DATA.Unmarshal(ekb[24:])
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return ekctx
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def eksession(ectx):
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session = ectx.StartAuthSession(
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ESYS_TR.NONE,
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ESYS_TR.NONE,
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None,
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TPM2_SE.POLICY,
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TPMT_SYM_DEF(algorithm=TPM2_ALG.NULL),
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TPM2_ALG.SHA256,
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)
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ectx.PolicySecret(
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ESYS_TR.RH_ENDORSEMENT,
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session,
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TPM2B_NONCE()._cdata,
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TPM2B_DIGEST()._cdata,
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TPM2B_NONCE()._cdata,
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0,
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session1=ESYS_TR.PASSWORD,
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)
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return session
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def main(ekpath, publicpath, sensitivepath, credpath, secretpath):
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# time to setup a ESAPI context, we will use the default TCTI for the system
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ectx = ESAPI()
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# Time to load the EK context, by using tpm2_createek there is no reason the implement the whole setup in this example code
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with open(ekpath, 'rb') as ekf:
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ekb = ekf.read()
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ekctx = unmarshal_tools_context(ekb)
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ekhandle = ectx.ContextLoad(ekctx)
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# now lets setup the standard EK policy session
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session = eksession(ectx)
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# Now we should read, unmarshal and load the temporary key pair
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with open(publicpath, 'rb') as pubf:
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pubb = pubf.read()
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public, _ = TPM2B_PUBLIC.Unmarshal(pubb)
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with open(sensitivepath, 'rb') as sensf:
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sensb = sensf.read()
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sensitive, _ = TPM2B_SENSITIVE.Unmarshal(sensb)
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print(sensitive.sensitiveArea.authValue.size, public.publicArea.authPolicy.size)
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# 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
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handle = ectx.LoadExternal(sensitive, public, ESYS_TR.RH_NULL)
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# Time to read and unmarshal the credential and secret for ActivateCredential
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with open(credpath, 'rb') as credf:
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credb = credf.read()
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credblob, _ = TPM2B_ID_OBJECT.Unmarshal(credb)
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with open(secretpath, 'rb') as secretf:
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secretb = secretf.read()
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secret, _ = TPM2B_ENCRYPTED_SECRET.Unmarshal(secretb)
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# Well, now there is nothing left but calling ActivateCredential and getting our secret on the remove system!
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oursecret = ectx.ActivateCredential(handle, ekhandle, credblob, secret, session2=session)
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print(f"we got the secret: {bytes(oursecret)}")
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if __name__ == '__main__':
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if len(sys.argv) < 6:
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sys.stderr.write(f"usage: {sys.argv[0]} ek-ctx temp-public temp-sensitive credblob secret\n")
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exit(1)
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main(sys.argv[1], sys.argv[2], sys.argv[3], sys.argv[4], sys.argv[5])
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```
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Generate the EK context with `tpm2_createek -c ek.ctx`
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The arguments are:
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ek-ctx: the context generated by tpm2_createek
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temp-public: the temp-public output from the local system script
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temp-sensitive: the temp-sensitive output from the local system script
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credblob: the credblob output from the local system script
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secret: the secret output from the local system script
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## Issues
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there is no TPM based protection against replay attacks in this example
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