Message ID | 20240102170408.21969-14-James.Bottomley@HansenPartnership.com (mailing list archive) |
---|---|
State | New, archived |
Headers | show |
Series | add integrity and security to TPM2 transactions | expand |
On Tue Jan 2, 2024 at 7:04 PM EET, James Bottomley wrote: > Add session based HMAC authentication plus parameter decryption and > response encryption using AES. The basic design is to segregate all > the nasty crypto, hash and hmac code into tpm2-sessions.c and export a > usable API. The API first of all starts off by gaining a session with > tpm2_start_auth_session() which initiates a session with the TPM and > allocates an opaque tpm2_auth structure to handle the session > parameters. The design is that session use will be single threaded > from start to finish under the ops lock, so the tpm2_auth structure is > stored in struct tpm2_chip to simpify the externally visible API. > > The session can be ended with tpm2_end_auth_session() which is > designed only to be used in error legs. Ordinarily the further > session API (future patches) will end or continue the session > appropriately without having to call this. > > Signed-off-by: James Bottomley <James.Bottomley@HansenPartnership.com> > Reviewed-by: Ard Biesheuvel <ard.biesheuvel@linaro.org> # crypto API parts > > --- > > v6: split into new patch, update config variable > --- > drivers/char/tpm/Kconfig | 3 + > drivers/char/tpm/tpm-buf.c | 1 + > drivers/char/tpm/tpm-chip.c | 3 + > drivers/char/tpm/tpm2-sessions.c | 383 +++++++++++++++++++++++++++++++ > include/linux/tpm.h | 34 +++ > 5 files changed, 424 insertions(+) > > diff --git a/drivers/char/tpm/Kconfig b/drivers/char/tpm/Kconfig > index e3c39a83171b..086cb8588493 100644 > --- a/drivers/char/tpm/Kconfig > +++ b/drivers/char/tpm/Kconfig > @@ -30,6 +30,9 @@ if TCG_TPM > config TCG_TPM2_HMAC > bool "Use encrypted and HMACd transactions on the TPM bus" > default y > + select CRYPTO_ECDH > + select CRYPTO_LIB_AESCFB > + select CRYPTO_LIB_SHA256 > help > Setting this causes us to deploy a scheme which uses request > and response HMACs in addition to encryption for > diff --git a/drivers/char/tpm/tpm-buf.c b/drivers/char/tpm/tpm-buf.c > index bb81180495d1..274130398569 100644 > --- a/drivers/char/tpm/tpm-buf.c > +++ b/drivers/char/tpm/tpm-buf.c > @@ -44,6 +44,7 @@ void tpm_buf_reset(struct tpm_buf *buf, u16 tag, u32 ordinal) > head->tag = cpu_to_be16(tag); > head->length = cpu_to_be32(sizeof(*head)); > head->ordinal = cpu_to_be32(ordinal); > + buf->handles = 0; > } > EXPORT_SYMBOL_GPL(tpm_buf_reset); > > diff --git a/drivers/char/tpm/tpm-chip.c b/drivers/char/tpm/tpm-chip.c > index 42b1062e33cd..d93937326b2e 100644 > --- a/drivers/char/tpm/tpm-chip.c > +++ b/drivers/char/tpm/tpm-chip.c > @@ -275,6 +275,9 @@ static void tpm_dev_release(struct device *dev) > kfree(chip->work_space.context_buf); > kfree(chip->work_space.session_buf); > kfree(chip->allocated_banks); > +#ifdef CONFIG_TCG_TPM2_HMAC > + kfree(chip->auth); > +#endif > kfree(chip); > } > > diff --git a/drivers/char/tpm/tpm2-sessions.c b/drivers/char/tpm/tpm2-sessions.c > index ef66c28bb332..bca6fe3ebb10 100644 > --- a/drivers/char/tpm/tpm2-sessions.c > +++ b/drivers/char/tpm/tpm2-sessions.c > @@ -3,18 +3,397 @@ > /* > * Copyright (C) 2018 James.Bottomley@HansenPartnership.com > * > + * Cryptographic helper routines for handling TPM2 sessions for > + * authorization HMAC and request response encryption. > + * > + * The idea is to ensure that every TPM command is HMAC protected by a > + * session, meaning in-flight tampering would be detected and in > + * addition all sensitive inputs and responses should be encrypted. > + * > + * The basic way this works is to use a TPM feature called salted > + * sessions where a random secret used in session construction is > + * encrypted to the public part of a known TPM key. The problem is we > + * have no known keys, so initially a primary Elliptic Curve key is > + * derived from the NULL seed (we use EC because most TPMs generate > + * these keys much faster than RSA ones). The curve used is NIST_P256 > + * because that's now mandated to be present in 'TCG TPM v2.0 > + * Provisioning Guidance' > + * > + * Threat problems: the initial TPM2_CreatePrimary is not (and cannot > + * be) session protected, so a clever Man in the Middle could return a > + * public key they control to this command and from there intercept > + * and decode all subsequent session based transactions. The kernel > + * cannot mitigate this threat but, after boot, userspace can get > + * proof this has not happened by asking the TPM to certify the NULL > + * key. This certification would chain back to the TPM Endorsement > + * Certificate and prove the NULL seed primary had not been tampered > + * with and thus all sessions must have been cryptographically secure. > + * To assist with this, the initial NULL seed public key name is made > + * available in a sysfs file. > + * > + * Use of these functions: > + * > + * The design is all the crypto, hash and hmac gunk is confined in this > + * file and never needs to be seen even by the kernel internal user. To > + * the user there's an init function tpm2_sessions_init() that needs to > + * be called once per TPM which generates the NULL seed primary key. > + * > + * These are the usage functions: > + * > + * tpm2_start_auth_session() which allocates the opaque auth structure > + * and gets a session from the TPM. This must be called before > + * any of the following functions. The session is protected by a > + * session_key which is derived from a random salt value > + * encrypted to the NULL seed. > + * tpm2_end_auth_session() kills the session and frees the resources. > + * Under normal operation this function is done by > + * tpm_buf_check_hmac_response(), so this is only to be used on > + * error legs where the latter is not executed. > */ > > #include "tpm.h" > > +#include <linux/random.h> > +#include <linux/scatterlist.h> > + > #include <asm/unaligned.h> > > #include <crypto/aes.h> > +#include <crypto/kpp.h> > +#include <crypto/ecdh.h> > +#include <crypto/hash.h> > +#include <crypto/hmac.h> > > /* if you change to AES256, you only need change this */ > #define AES_KEYBYTES AES_KEYSIZE_128 > > #define AES_KEYBITS (AES_KEYBYTES*8) > +#define AUTH_MAX_NAMES 3 > + > +/* > + * This is the structure that carries all the auth information (like > + * session handle, nonces, session key and auth) from use to use it is > + * designed to be opaque to anything outside. > + */ > +struct tpm2_auth { > + u32 handle; > + /* > + * This has two meanings: before tpm_buf_fill_hmac_session() > + * it marks the offset in the buffer of the start of the > + * sessions (i.e. after all the handles). Once the buffer has > + * been filled it markes the session number of our auth > + * session so we can find it again in the response buffer. > + * > + * The two cases are distinguished because the first offset > + * must always be greater than TPM_HEADER_SIZE and the second > + * must be less than or equal to 5. > + */ > + u32 session; > + /* > + * the size here is variable and set by the size of our_nonce > + * which must be between 16 and the name hash length. we set > + * the maximum sha256 size for the greatest protection > + */ > + u8 our_nonce[SHA256_DIGEST_SIZE]; > + u8 tpm_nonce[SHA256_DIGEST_SIZE]; > + /* > + * the salt is only used across the session command/response > + * after that it can be used as a scratch area > + */ > + union { > + u8 salt[EC_PT_SZ]; > + /* scratch for key + IV */ > + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; > + }; > + u8 session_key[SHA256_DIGEST_SIZE]; > +}; Could this contain also the fields added in the previous patch? Then obviously this data would be allocated together with chip but is there hard reason why this needs separate kzalloc and cannot be always allocated with chip blob? BR, Jarkko
On Wed, 2024-01-03 at 17:18 +0200, Jarkko Sakkinen wrote: > On Tue Jan 2, 2024 at 7:04 PM EET, James Bottomley wrote: > > Add session based HMAC authentication plus parameter decryption > > and > > response encryption using AES. The basic design is to segregate > > all > > the nasty crypto, hash and hmac code into tpm2-sessions.c and > > export a > > usable API. The API first of all starts off by gaining a session > > with > > tpm2_start_auth_session() which initiates a session with the TPM > > and > > allocates an opaque tpm2_auth structure to handle the > > session > > parameters. The design is that session use will be single > > threaded > > from start to finish under the ops lock, so the tpm2_auth structure > > is > > stored in struct tpm2_chip to simpify the externally visible API. > > > > The session can be ended with tpm2_end_auth_session() which is > > designed only to be used in error legs. Ordinarily the further > > session API (future patches) will end or continue the session > > appropriately without having to call this. > > > > Signed-off-by: James Bottomley > > <James.Bottomley@HansenPartnership.com> > > Reviewed-by: Ard Biesheuvel <ard.biesheuvel@linaro.org> # crypto > > API parts > > > > --- > > > > v6: split into new patch, update config variable > > --- > > drivers/char/tpm/Kconfig | 3 + > > drivers/char/tpm/tpm-buf.c | 1 + > > drivers/char/tpm/tpm-chip.c | 3 + > > drivers/char/tpm/tpm2-sessions.c | 383 > > +++++++++++++++++++++++++++++++ > > include/linux/tpm.h | 34 +++ > > 5 files changed, 424 insertions(+) > > > > diff --git a/drivers/char/tpm/Kconfig b/drivers/char/tpm/Kconfig > > index e3c39a83171b..086cb8588493 100644 > > --- a/drivers/char/tpm/Kconfig > > +++ b/drivers/char/tpm/Kconfig > > @@ -30,6 +30,9 @@ if TCG_TPM > > config TCG_TPM2_HMAC > > bool "Use encrypted and HMACd transactions on the TPM bus" > > default y > > + select CRYPTO_ECDH > > + select CRYPTO_LIB_AESCFB > > + select CRYPTO_LIB_SHA256 > > help > > Setting this causes us to deploy a scheme which uses > > request > > and response HMACs in addition to encryption for > > diff --git a/drivers/char/tpm/tpm-buf.c b/drivers/char/tpm/tpm- > > buf.c > > index bb81180495d1..274130398569 100644 > > --- a/drivers/char/tpm/tpm-buf.c > > +++ b/drivers/char/tpm/tpm-buf.c > > @@ -44,6 +44,7 @@ void tpm_buf_reset(struct tpm_buf *buf, u16 tag, > > u32 ordinal) > > head->tag = cpu_to_be16(tag); > > head->length = cpu_to_be32(sizeof(*head)); > > head->ordinal = cpu_to_be32(ordinal); > > + buf->handles = 0; > > } > > EXPORT_SYMBOL_GPL(tpm_buf_reset); > > > > diff --git a/drivers/char/tpm/tpm-chip.c b/drivers/char/tpm/tpm- > > chip.c > > index 42b1062e33cd..d93937326b2e 100644 > > --- a/drivers/char/tpm/tpm-chip.c > > +++ b/drivers/char/tpm/tpm-chip.c > > @@ -275,6 +275,9 @@ static void tpm_dev_release(struct device *dev) > > kfree(chip->work_space.context_buf); > > kfree(chip->work_space.session_buf); > > kfree(chip->allocated_banks); > > +#ifdef CONFIG_TCG_TPM2_HMAC > > + kfree(chip->auth); > > +#endif > > kfree(chip); > > } > > > > diff --git a/drivers/char/tpm/tpm2-sessions.c > > b/drivers/char/tpm/tpm2-sessions.c > > index ef66c28bb332..bca6fe3ebb10 100644 > > --- a/drivers/char/tpm/tpm2-sessions.c > > +++ b/drivers/char/tpm/tpm2-sessions.c > > @@ -3,18 +3,397 @@ > > /* > > * Copyright (C) 2018 James.Bottomley@HansenPartnership.com > > * > > + * Cryptographic helper routines for handling TPM2 sessions for > > + * authorization HMAC and request response encryption. > > + * > > + * The idea is to ensure that every TPM command is HMAC protected > > by a > > + * session, meaning in-flight tampering would be detected and in > > + * addition all sensitive inputs and responses should be > > encrypted. > > + * > > + * The basic way this works is to use a TPM feature called salted > > + * sessions where a random secret used in session construction is > > + * encrypted to the public part of a known TPM key. The problem > > is we > > + * have no known keys, so initially a primary Elliptic Curve key > > is > > + * derived from the NULL seed (we use EC because most TPMs > > generate > > + * these keys much faster than RSA ones). The curve used is > > NIST_P256 > > + * because that's now mandated to be present in 'TCG TPM v2.0 > > + * Provisioning Guidance' > > + * > > + * Threat problems: the initial TPM2_CreatePrimary is not (and > > cannot > > + * be) session protected, so a clever Man in the Middle could > > return a > > + * public key they control to this command and from there > > intercept > > + * and decode all subsequent session based transactions. The > > kernel > > + * cannot mitigate this threat but, after boot, userspace can get > > + * proof this has not happened by asking the TPM to certify the > > NULL > > + * key. This certification would chain back to the TPM > > Endorsement > > + * Certificate and prove the NULL seed primary had not been > > tampered > > + * with and thus all sessions must have been cryptographically > > secure. > > + * To assist with this, the initial NULL seed public key name is > > made > > + * available in a sysfs file. > > + * > > + * Use of these functions: > > + * > > + * The design is all the crypto, hash and hmac gunk is confined in > > this > > + * file and never needs to be seen even by the kernel internal > > user. To > > + * the user there's an init function tpm2_sessions_init() that > > needs to > > + * be called once per TPM which generates the NULL seed primary > > key. > > + * > > + * These are the usage functions: > > + * > > + * tpm2_start_auth_session() which allocates the opaque auth > > structure > > + * and gets a session from the TPM. This must be called > > before > > + * any of the following functions. The session is protected > > by a > > + * session_key which is derived from a random salt value > > + * encrypted to the NULL seed. > > + * tpm2_end_auth_session() kills the session and frees the > > resources. > > + * Under normal operation this function is done by > > + * tpm_buf_check_hmac_response(), so this is only to be used > > on > > + * error legs where the latter is not executed. > > */ > > > > #include "tpm.h" > > > > +#include <linux/random.h> > > +#include <linux/scatterlist.h> > > + > > #include <asm/unaligned.h> > > > > #include <crypto/aes.h> > > +#include <crypto/kpp.h> > > +#include <crypto/ecdh.h> > > +#include <crypto/hash.h> > > +#include <crypto/hmac.h> > > > > /* if you change to AES256, you only need change this */ > > #define AES_KEYBYTES AES_KEYSIZE_128 > > > > #define AES_KEYBITS (AES_KEYBYTES*8) > > +#define AUTH_MAX_NAMES 3 > > + > > +/* > > + * This is the structure that carries all the auth information > > (like > > + * session handle, nonces, session key and auth) from use to use > > it is > > + * designed to be opaque to anything outside. > > + */ > > +struct tpm2_auth { > > + u32 handle; > > + /* > > + * This has two meanings: before > > tpm_buf_fill_hmac_session() > > + * it marks the offset in the buffer of the start of the > > + * sessions (i.e. after all the handles). Once the buffer > > has > > + * been filled it markes the session number of our auth > > + * session so we can find it again in the response buffer. > > + * > > + * The two cases are distinguished because the first offset > > + * must always be greater than TPM_HEADER_SIZE and the > > second > > + * must be less than or equal to 5. > > + */ > > + u32 session; > > + /* > > + * the size here is variable and set by the size of > > our_nonce > > + * which must be between 16 and the name hash length. we > > set > > + * the maximum sha256 size for the greatest protection > > + */ > > + u8 our_nonce[SHA256_DIGEST_SIZE]; > > + u8 tpm_nonce[SHA256_DIGEST_SIZE]; > > + /* > > + * the salt is only used across the session > > command/response > > + * after that it can be used as a scratch area > > + */ > > + union { > > + u8 salt[EC_PT_SZ]; > > + /* scratch for key + IV */ > > + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; > > + }; > > + u8 session_key[SHA256_DIGEST_SIZE]; > > +}; > > Could this contain also the fields added in the previous patch? > > Then obviously this data would be allocated together with chip > but is there hard reason why this needs separate kzalloc and cannot > be always allocated with chip blob? It's session specific (and highly sensitive data), so it needs to be allocated and destroyed with each session. Our usage pattern under the ops mutex means that every session is single threaded, so effectively it has a 1:1 relationship with the chip, but part of the reason for all of this is to remove visibility of the contents of this area from anything other than the session code. Essentially it's stuff the chip doesn't need to know because it's always constructed when the session is created. I've also got a policy patch much later that requires two sessions, so needs a push and pop mechanism which a static allocation in the chip area won't work for. James
On Wed Jan 3, 2024 at 5:31 PM EET, James Bottomley wrote: > On Wed, 2024-01-03 at 17:18 +0200, Jarkko Sakkinen wrote: > > On Tue Jan 2, 2024 at 7:04 PM EET, James Bottomley wrote: > > > Add session based HMAC authentication plus parameter decryption > > > and > > > response encryption using AES. The basic design is to segregate > > > all > > > the nasty crypto, hash and hmac code into tpm2-sessions.c and > > > export a > > > usable API. The API first of all starts off by gaining a session > > > with > > > tpm2_start_auth_session() which initiates a session with the TPM > > > and > > > allocates an opaque tpm2_auth structure to handle the > > > session > > > parameters. The design is that session use will be single > > > threaded > > > from start to finish under the ops lock, so the tpm2_auth structure > > > is > > > stored in struct tpm2_chip to simpify the externally visible API. > > > > > > The session can be ended with tpm2_end_auth_session() which is > > > designed only to be used in error legs. Ordinarily the further > > > session API (future patches) will end or continue the session > > > appropriately without having to call this. > > > > > > Signed-off-by: James Bottomley > > > <James.Bottomley@HansenPartnership.com> > > > Reviewed-by: Ard Biesheuvel <ard.biesheuvel@linaro.org> # crypto > > > API parts > > > > > > --- > > > > > > v6: split into new patch, update config variable > > > --- > > > drivers/char/tpm/Kconfig | 3 + > > > drivers/char/tpm/tpm-buf.c | 1 + > > > drivers/char/tpm/tpm-chip.c | 3 + > > > drivers/char/tpm/tpm2-sessions.c | 383 > > > +++++++++++++++++++++++++++++++ > > > include/linux/tpm.h | 34 +++ > > > 5 files changed, 424 insertions(+) > > > > > > diff --git a/drivers/char/tpm/Kconfig b/drivers/char/tpm/Kconfig > > > index e3c39a83171b..086cb8588493 100644 > > > --- a/drivers/char/tpm/Kconfig > > > +++ b/drivers/char/tpm/Kconfig > > > @@ -30,6 +30,9 @@ if TCG_TPM > > > config TCG_TPM2_HMAC > > > bool "Use encrypted and HMACd transactions on the TPM bus" > > > default y > > > + select CRYPTO_ECDH > > > + select CRYPTO_LIB_AESCFB > > > + select CRYPTO_LIB_SHA256 > > > help > > > Setting this causes us to deploy a scheme which uses > > > request > > > and response HMACs in addition to encryption for > > > diff --git a/drivers/char/tpm/tpm-buf.c b/drivers/char/tpm/tpm- > > > buf.c > > > index bb81180495d1..274130398569 100644 > > > --- a/drivers/char/tpm/tpm-buf.c > > > +++ b/drivers/char/tpm/tpm-buf.c > > > @@ -44,6 +44,7 @@ void tpm_buf_reset(struct tpm_buf *buf, u16 tag, > > > u32 ordinal) > > > head->tag = cpu_to_be16(tag); > > > head->length = cpu_to_be32(sizeof(*head)); > > > head->ordinal = cpu_to_be32(ordinal); > > > + buf->handles = 0; > > > } > > > EXPORT_SYMBOL_GPL(tpm_buf_reset); > > > > > > diff --git a/drivers/char/tpm/tpm-chip.c b/drivers/char/tpm/tpm- > > > chip.c > > > index 42b1062e33cd..d93937326b2e 100644 > > > --- a/drivers/char/tpm/tpm-chip.c > > > +++ b/drivers/char/tpm/tpm-chip.c > > > @@ -275,6 +275,9 @@ static void tpm_dev_release(struct device *dev) > > > kfree(chip->work_space.context_buf); > > > kfree(chip->work_space.session_buf); > > > kfree(chip->allocated_banks); > > > +#ifdef CONFIG_TCG_TPM2_HMAC > > > + kfree(chip->auth); > > > +#endif > > > kfree(chip); > > > } > > > > > > diff --git a/drivers/char/tpm/tpm2-sessions.c > > > b/drivers/char/tpm/tpm2-sessions.c > > > index ef66c28bb332..bca6fe3ebb10 100644 > > > --- a/drivers/char/tpm/tpm2-sessions.c > > > +++ b/drivers/char/tpm/tpm2-sessions.c > > > @@ -3,18 +3,397 @@ > > > /* > > > * Copyright (C) 2018 James.Bottomley@HansenPartnership.com > > > * > > > + * Cryptographic helper routines for handling TPM2 sessions for > > > + * authorization HMAC and request response encryption. > > > + * > > > + * The idea is to ensure that every TPM command is HMAC protected > > > by a > > > + * session, meaning in-flight tampering would be detected and in > > > + * addition all sensitive inputs and responses should be > > > encrypted. > > > + * > > > + * The basic way this works is to use a TPM feature called salted > > > + * sessions where a random secret used in session construction is > > > + * encrypted to the public part of a known TPM key. The problem > > > is we > > > + * have no known keys, so initially a primary Elliptic Curve key > > > is > > > + * derived from the NULL seed (we use EC because most TPMs > > > generate > > > + * these keys much faster than RSA ones). The curve used is > > > NIST_P256 > > > + * because that's now mandated to be present in 'TCG TPM v2.0 > > > + * Provisioning Guidance' > > > + * > > > + * Threat problems: the initial TPM2_CreatePrimary is not (and > > > cannot > > > + * be) session protected, so a clever Man in the Middle could > > > return a > > > + * public key they control to this command and from there > > > intercept > > > + * and decode all subsequent session based transactions. The > > > kernel > > > + * cannot mitigate this threat but, after boot, userspace can get > > > + * proof this has not happened by asking the TPM to certify the > > > NULL > > > + * key. This certification would chain back to the TPM > > > Endorsement > > > + * Certificate and prove the NULL seed primary had not been > > > tampered > > > + * with and thus all sessions must have been cryptographically > > > secure. > > > + * To assist with this, the initial NULL seed public key name is > > > made > > > + * available in a sysfs file. > > > + * > > > + * Use of these functions: > > > + * > > > + * The design is all the crypto, hash and hmac gunk is confined in > > > this > > > + * file and never needs to be seen even by the kernel internal > > > user. To > > > + * the user there's an init function tpm2_sessions_init() that > > > needs to > > > + * be called once per TPM which generates the NULL seed primary > > > key. > > > + * > > > + * These are the usage functions: > > > + * > > > + * tpm2_start_auth_session() which allocates the opaque auth > > > structure > > > + * and gets a session from the TPM. This must be called > > > before > > > + * any of the following functions. The session is protected > > > by a > > > + * session_key which is derived from a random salt value > > > + * encrypted to the NULL seed. > > > + * tpm2_end_auth_session() kills the session and frees the > > > resources. > > > + * Under normal operation this function is done by > > > + * tpm_buf_check_hmac_response(), so this is only to be used > > > on > > > + * error legs where the latter is not executed. > > > */ > > > > > > #include "tpm.h" > > > > > > +#include <linux/random.h> > > > +#include <linux/scatterlist.h> > > > + > > > #include <asm/unaligned.h> > > > > > > #include <crypto/aes.h> > > > +#include <crypto/kpp.h> > > > +#include <crypto/ecdh.h> > > > +#include <crypto/hash.h> > > > +#include <crypto/hmac.h> > > > > > > /* if you change to AES256, you only need change this */ > > > #define AES_KEYBYTES AES_KEYSIZE_128 > > > > > > #define AES_KEYBITS (AES_KEYBYTES*8) > > > +#define AUTH_MAX_NAMES 3 > > > + > > > +/* > > > + * This is the structure that carries all the auth information > > > (like > > > + * session handle, nonces, session key and auth) from use to use > > > it is > > > + * designed to be opaque to anything outside. > > > + */ > > > +struct tpm2_auth { > > > + u32 handle; > > > + /* > > > + * This has two meanings: before > > > tpm_buf_fill_hmac_session() > > > + * it marks the offset in the buffer of the start of the > > > + * sessions (i.e. after all the handles). Once the buffer > > > has > > > + * been filled it markes the session number of our auth > > > + * session so we can find it again in the response buffer. > > > + * > > > + * The two cases are distinguished because the first offset > > > + * must always be greater than TPM_HEADER_SIZE and the > > > second > > > + * must be less than or equal to 5. > > > + */ > > > + u32 session; > > > + /* > > > + * the size here is variable and set by the size of > > > our_nonce > > > + * which must be between 16 and the name hash length. we > > > set > > > + * the maximum sha256 size for the greatest protection > > > + */ > > > + u8 our_nonce[SHA256_DIGEST_SIZE]; > > > + u8 tpm_nonce[SHA256_DIGEST_SIZE]; > > > + /* > > > + * the salt is only used across the session > > > command/response > > > + * after that it can be used as a scratch area > > > + */ > > > + union { > > > + u8 salt[EC_PT_SZ]; > > > + /* scratch for key + IV */ > > > + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; > > > + }; > > > + u8 session_key[SHA256_DIGEST_SIZE]; > > > +}; > > > > Could this contain also the fields added in the previous patch? > > > > Then obviously this data would be allocated together with chip > > but is there hard reason why this needs separate kzalloc and cannot > > be always allocated with chip blob? > > It's session specific (and highly sensitive data), so it needs to be > allocated and destroyed with each session. Our usage pattern under the > ops mutex means that every session is single threaded, so effectively > it has a 1:1 relationship with the chip, but part of the reason for all > of this is to remove visibility of the contents of this area from > anything other than the session code. Essentially it's stuff the chip > doesn't need to know because it's always constructed when the session > is created. > > I've also got a policy patch much later that requires two sessions, so > needs a push and pop mechanism which a static allocation in the chip > area won't work for. > > James Given the 1:1 relationship keeping the fields in tpm_chip has the benefit of not having to deal with allocation error. I guess having struct tpm2_auth (dunno, maybe tpm2_hmac_auth tho) does make sense because then it could be declared as static field and zeroed with memzero_explicit(). I don't see any point saving memory here at least... BR, Jarkko
On Thu, 2024-01-04 at 20:09 +0200, Jarkko Sakkinen wrote: > On Wed Jan 3, 2024 at 5:31 PM EET, James Bottomley wrote: > > On Wed, 2024-01-03 at 17:18 +0200, Jarkko Sakkinen wrote: > > > On Tue Jan 2, 2024 at 7:04 PM EET, James Bottomley wrote: [...] > > > > +struct tpm2_auth { > > > > + u32 handle; > > > > + /* > > > > + * This has two meanings: before > > > > tpm_buf_fill_hmac_session() > > > > + * it marks the offset in the buffer of the start of > > > > the > > > > + * sessions (i.e. after all the handles). Once the > > > > buffer > > > > has > > > > + * been filled it markes the session number of our auth > > > > + * session so we can find it again in the response > > > > buffer. > > > > + * > > > > + * The two cases are distinguished because the first > > > > offset > > > > + * must always be greater than TPM_HEADER_SIZE and the > > > > second > > > > + * must be less than or equal to 5. > > > > + */ > > > > + u32 session; > > > > + /* > > > > + * the size here is variable and set by the size of > > > > our_nonce > > > > + * which must be between 16 and the name hash length. > > > > we > > > > set > > > > + * the maximum sha256 size for the greatest protection > > > > + */ > > > > + u8 our_nonce[SHA256_DIGEST_SIZE]; > > > > + u8 tpm_nonce[SHA256_DIGEST_SIZE]; > > > > + /* > > > > + * the salt is only used across the session > > > > command/response > > > > + * after that it can be used as a scratch area > > > > + */ > > > > + union { > > > > + u8 salt[EC_PT_SZ]; > > > > + /* scratch for key + IV */ > > > > + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; > > > > + }; > > > > + u8 session_key[SHA256_DIGEST_SIZE]; > > > > +}; > > > > > > Could this contain also the fields added in the previous patch? > > > > > > Then obviously this data would be allocated together with chip > > > but is there hard reason why this needs separate kzalloc and > > > cannot be always allocated with chip blob? > > > > It's session specific (and highly sensitive data), so it needs to > > be allocated and destroyed with each session. Our usage pattern > > under the ops mutex means that every session is single threaded, so > > effectively it has a 1:1 relationship with the chip, but part of > > the reason for all of this is to remove visibility of the contents > > of this area from anything other than the session code. > > Essentially it's stuff the chip doesn't need to know because it's > > always constructed when the session is created. > > > > I've also got a policy patch much later that requires two sessions, > > so needs a push and pop mechanism which a static allocation in the > > chip area won't work for. > > > > James > > Given the 1:1 relationship keeping the fields in tpm_chip has the > benefit of not having to deal with allocation error. > > I guess having struct tpm2_auth (dunno, maybe tpm2_hmac_auth tho) > does make sense because then it could be declared as static field > and zeroed with memzero_explicit(). > > I don't see any point saving memory here at least... It's not about saving memory, it's about encapsulation: the inner details of session encryption would have to go into a global linux wide header file. Ideally they should stay local to the TPM code and not be splashed about the kernel, so as not to give anyone else the idea they can muck with the values. And, as I also said, a single allocation won't work with >1 sessions which are needed later on. James
On Fri Jan 5, 2024 at 12:25 AM EET, James Bottomley wrote: > On Thu, 2024-01-04 at 20:09 +0200, Jarkko Sakkinen wrote: > > On Wed Jan 3, 2024 at 5:31 PM EET, James Bottomley wrote: > > > On Wed, 2024-01-03 at 17:18 +0200, Jarkko Sakkinen wrote: > > > > On Tue Jan 2, 2024 at 7:04 PM EET, James Bottomley wrote: > [...] > > > > > +struct tpm2_auth { > > > > > + u32 handle; > > > > > + /* > > > > > + * This has two meanings: before > > > > > tpm_buf_fill_hmac_session() > > > > > + * it marks the offset in the buffer of the start of > > > > > the > > > > > + * sessions (i.e. after all the handles). Once the > > > > > buffer > > > > > has > > > > > + * been filled it markes the session number of our auth > > > > > + * session so we can find it again in the response > > > > > buffer. > > > > > + * > > > > > + * The two cases are distinguished because the first > > > > > offset > > > > > + * must always be greater than TPM_HEADER_SIZE and the > > > > > second > > > > > + * must be less than or equal to 5. > > > > > + */ > > > > > + u32 session; > > > > > + /* > > > > > + * the size here is variable and set by the size of > > > > > our_nonce > > > > > + * which must be between 16 and the name hash length. > > > > > we > > > > > set > > > > > + * the maximum sha256 size for the greatest protection > > > > > + */ > > > > > + u8 our_nonce[SHA256_DIGEST_SIZE]; > > > > > + u8 tpm_nonce[SHA256_DIGEST_SIZE]; > > > > > + /* > > > > > + * the salt is only used across the session > > > > > command/response > > > > > + * after that it can be used as a scratch area > > > > > + */ > > > > > + union { > > > > > + u8 salt[EC_PT_SZ]; > > > > > + /* scratch for key + IV */ > > > > > + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; > > > > > + }; > > > > > + u8 session_key[SHA256_DIGEST_SIZE]; > > > > > +}; > > > > > > > > Could this contain also the fields added in the previous patch? > > > > > > > > Then obviously this data would be allocated together with chip > > > > but is there hard reason why this needs separate kzalloc and > > > > cannot be always allocated with chip blob? > > > > > > It's session specific (and highly sensitive data), so it needs to > > > be allocated and destroyed with each session. Our usage pattern > > > under the ops mutex means that every session is single threaded, so > > > effectively it has a 1:1 relationship with the chip, but part of > > > the reason for all of this is to remove visibility of the contents > > > of this area from anything other than the session code. > > > Essentially it's stuff the chip doesn't need to know because it's > > > always constructed when the session is created. > > > > > > I've also got a policy patch much later that requires two sessions, > > > so needs a push and pop mechanism which a static allocation in the > > > chip area won't work for. > > > > > > James > > > > Given the 1:1 relationship keeping the fields in tpm_chip has the > > benefit of not having to deal with allocation error. > > > > I guess having struct tpm2_auth (dunno, maybe tpm2_hmac_auth tho) > > does make sense because then it could be declared as static field > > and zeroed with memzero_explicit(). > > > > I don't see any point saving memory here at least... > > It's not about saving memory, it's about encapsulation: the inner > details of session encryption would have to go into a global linux wide > header file. Ideally they should stay local to the TPM code and not be > splashed about the kernel, so as not to give anyone else the idea they > can muck with the values. And, as I also said, a single allocation > won't work with >1 sessions which are needed later on. Do not mean to be impolite but "later on" does not matter, unless it is within the scope of the same patch set. Clearly tpm2_auth is not required to implement the feature and should be postponed to a patch set which requires multiple instances of tpm2_auth. I don't simply want to commmit to futures, sorry. > James BR, Jarkko
diff --git a/drivers/char/tpm/Kconfig b/drivers/char/tpm/Kconfig index e3c39a83171b..086cb8588493 100644 --- a/drivers/char/tpm/Kconfig +++ b/drivers/char/tpm/Kconfig @@ -30,6 +30,9 @@ if TCG_TPM config TCG_TPM2_HMAC bool "Use encrypted and HMACd transactions on the TPM bus" default y + select CRYPTO_ECDH + select CRYPTO_LIB_AESCFB + select CRYPTO_LIB_SHA256 help Setting this causes us to deploy a scheme which uses request and response HMACs in addition to encryption for diff --git a/drivers/char/tpm/tpm-buf.c b/drivers/char/tpm/tpm-buf.c index bb81180495d1..274130398569 100644 --- a/drivers/char/tpm/tpm-buf.c +++ b/drivers/char/tpm/tpm-buf.c @@ -44,6 +44,7 @@ void tpm_buf_reset(struct tpm_buf *buf, u16 tag, u32 ordinal) head->tag = cpu_to_be16(tag); head->length = cpu_to_be32(sizeof(*head)); head->ordinal = cpu_to_be32(ordinal); + buf->handles = 0; } EXPORT_SYMBOL_GPL(tpm_buf_reset); diff --git a/drivers/char/tpm/tpm-chip.c b/drivers/char/tpm/tpm-chip.c index 42b1062e33cd..d93937326b2e 100644 --- a/drivers/char/tpm/tpm-chip.c +++ b/drivers/char/tpm/tpm-chip.c @@ -275,6 +275,9 @@ static void tpm_dev_release(struct device *dev) kfree(chip->work_space.context_buf); kfree(chip->work_space.session_buf); kfree(chip->allocated_banks); +#ifdef CONFIG_TCG_TPM2_HMAC + kfree(chip->auth); +#endif kfree(chip); } diff --git a/drivers/char/tpm/tpm2-sessions.c b/drivers/char/tpm/tpm2-sessions.c index ef66c28bb332..bca6fe3ebb10 100644 --- a/drivers/char/tpm/tpm2-sessions.c +++ b/drivers/char/tpm/tpm2-sessions.c @@ -3,18 +3,397 @@ /* * Copyright (C) 2018 James.Bottomley@HansenPartnership.com * + * Cryptographic helper routines for handling TPM2 sessions for + * authorization HMAC and request response encryption. + * + * The idea is to ensure that every TPM command is HMAC protected by a + * session, meaning in-flight tampering would be detected and in + * addition all sensitive inputs and responses should be encrypted. + * + * The basic way this works is to use a TPM feature called salted + * sessions where a random secret used in session construction is + * encrypted to the public part of a known TPM key. The problem is we + * have no known keys, so initially a primary Elliptic Curve key is + * derived from the NULL seed (we use EC because most TPMs generate + * these keys much faster than RSA ones). The curve used is NIST_P256 + * because that's now mandated to be present in 'TCG TPM v2.0 + * Provisioning Guidance' + * + * Threat problems: the initial TPM2_CreatePrimary is not (and cannot + * be) session protected, so a clever Man in the Middle could return a + * public key they control to this command and from there intercept + * and decode all subsequent session based transactions. The kernel + * cannot mitigate this threat but, after boot, userspace can get + * proof this has not happened by asking the TPM to certify the NULL + * key. This certification would chain back to the TPM Endorsement + * Certificate and prove the NULL seed primary had not been tampered + * with and thus all sessions must have been cryptographically secure. + * To assist with this, the initial NULL seed public key name is made + * available in a sysfs file. + * + * Use of these functions: + * + * The design is all the crypto, hash and hmac gunk is confined in this + * file and never needs to be seen even by the kernel internal user. To + * the user there's an init function tpm2_sessions_init() that needs to + * be called once per TPM which generates the NULL seed primary key. + * + * These are the usage functions: + * + * tpm2_start_auth_session() which allocates the opaque auth structure + * and gets a session from the TPM. This must be called before + * any of the following functions. The session is protected by a + * session_key which is derived from a random salt value + * encrypted to the NULL seed. + * tpm2_end_auth_session() kills the session and frees the resources. + * Under normal operation this function is done by + * tpm_buf_check_hmac_response(), so this is only to be used on + * error legs where the latter is not executed. */ #include "tpm.h" +#include <linux/random.h> +#include <linux/scatterlist.h> + #include <asm/unaligned.h> #include <crypto/aes.h> +#include <crypto/kpp.h> +#include <crypto/ecdh.h> +#include <crypto/hash.h> +#include <crypto/hmac.h> /* if you change to AES256, you only need change this */ #define AES_KEYBYTES AES_KEYSIZE_128 #define AES_KEYBITS (AES_KEYBYTES*8) +#define AUTH_MAX_NAMES 3 + +/* + * This is the structure that carries all the auth information (like + * session handle, nonces, session key and auth) from use to use it is + * designed to be opaque to anything outside. + */ +struct tpm2_auth { + u32 handle; + /* + * This has two meanings: before tpm_buf_fill_hmac_session() + * it marks the offset in the buffer of the start of the + * sessions (i.e. after all the handles). Once the buffer has + * been filled it markes the session number of our auth + * session so we can find it again in the response buffer. + * + * The two cases are distinguished because the first offset + * must always be greater than TPM_HEADER_SIZE and the second + * must be less than or equal to 5. + */ + u32 session; + /* + * the size here is variable and set by the size of our_nonce + * which must be between 16 and the name hash length. we set + * the maximum sha256 size for the greatest protection + */ + u8 our_nonce[SHA256_DIGEST_SIZE]; + u8 tpm_nonce[SHA256_DIGEST_SIZE]; + /* + * the salt is only used across the session command/response + * after that it can be used as a scratch area + */ + union { + u8 salt[EC_PT_SZ]; + /* scratch for key + IV */ + u8 scratch[AES_KEYBYTES + AES_BLOCK_SIZE]; + }; + u8 session_key[SHA256_DIGEST_SIZE]; +}; + +/* + * It turns out the crypto hmac(sha256) is hard for us to consume + * because it assumes a fixed key and the TPM seems to change the key + * on every operation, so we weld the hmac init and final functions in + * here to give it the same usage characteristics as a regular hash + */ +static void hmac_init(struct sha256_state *sctx, u8 *key, int keylen) +{ + u8 pad[SHA256_BLOCK_SIZE]; + int i; + + sha256_init(sctx); + for (i = 0; i < sizeof(pad); i++) { + if (i < keylen) + pad[i] = key[i]; + else + pad[i] = 0; + pad[i] ^= HMAC_IPAD_VALUE; + } + sha256_update(sctx, pad, sizeof(pad)); +} + +static void hmac_final(struct sha256_state *sctx, u8 *key, int keylen, u8 *out) +{ + u8 pad[SHA256_BLOCK_SIZE]; + int i; + + for (i = 0; i < sizeof(pad); i++) { + if (i < keylen) + pad[i] = key[i]; + else + pad[i] = 0; + pad[i] ^= HMAC_OPAD_VALUE; + } + + /* collect the final hash; use out as temporary storage */ + sha256_final(sctx, out); + + sha256_init(sctx); + sha256_update(sctx, pad, sizeof(pad)); + sha256_update(sctx, out, SHA256_DIGEST_SIZE); + sha256_final(sctx, out); +} + +/* + * assume hash sha256 and nonces u, v of size SHA256_DIGEST_SIZE but + * otherwise standard KDFa. Note output is in bytes not bits. + */ +static void KDFa(u8 *key, int keylen, const char *label, u8 *u, + u8 *v, int bytes, u8 *out) +{ + u32 counter; + const __be32 bits = cpu_to_be32(bytes * 8); + + for (counter = 1; bytes > 0; bytes -= SHA256_DIGEST_SIZE, counter++, + out += SHA256_DIGEST_SIZE) { + struct sha256_state sctx; + __be32 c = cpu_to_be32(counter); + + hmac_init(&sctx, key, keylen); + sha256_update(&sctx, (u8 *)&c, sizeof(c)); + sha256_update(&sctx, label, strlen(label)+1); + sha256_update(&sctx, u, SHA256_DIGEST_SIZE); + sha256_update(&sctx, v, SHA256_DIGEST_SIZE); + sha256_update(&sctx, (u8 *)&bits, sizeof(bits)); + hmac_final(&sctx, key, keylen, out); + } +} + +/* + * Somewhat of a bastardization of the real KDFe. We're assuming + * we're working with known point sizes for the input parameters and + * the hash algorithm is fixed at sha256. Because we know that the + * point size is 32 bytes like the hash size, there's no need to loop + * in this KDF. + */ +static void KDFe(u8 z[EC_PT_SZ], const char *str, u8 *pt_u, u8 *pt_v, + u8 *keyout) +{ + struct sha256_state sctx; + /* + * this should be an iterative counter, but because we know + * we're only taking 32 bytes for the point using a sha256 + * hash which is also 32 bytes, there's only one loop + */ + __be32 c = cpu_to_be32(1); + + sha256_init(&sctx); + /* counter (BE) */ + sha256_update(&sctx, (u8 *)&c, sizeof(c)); + /* secret value */ + sha256_update(&sctx, z, EC_PT_SZ); + /* string including trailing zero */ + sha256_update(&sctx, str, strlen(str)+1); + sha256_update(&sctx, pt_u, EC_PT_SZ); + sha256_update(&sctx, pt_v, EC_PT_SZ); + sha256_final(&sctx, keyout); +} + +static void tpm_buf_append_salt(struct tpm_buf *buf, struct tpm_chip *chip) +{ + struct crypto_kpp *kpp; + struct kpp_request *req; + struct scatterlist s[2], d[1]; + struct ecdh p = {0}; + u8 encoded_key[EC_PT_SZ], *x, *y; + unsigned int buf_len; + + /* secret is two sized points */ + tpm_buf_append_u16(buf, (EC_PT_SZ + 2)*2); + /* + * we cheat here and append uninitialized data to form + * the points. All we care about is getting the two + * co-ordinate pointers, which will be used to overwrite + * the uninitialized data + */ + tpm_buf_append_u16(buf, EC_PT_SZ); + x = &buf->data[tpm_buf_length(buf)]; + tpm_buf_append(buf, encoded_key, EC_PT_SZ); + tpm_buf_append_u16(buf, EC_PT_SZ); + y = &buf->data[tpm_buf_length(buf)]; + tpm_buf_append(buf, encoded_key, EC_PT_SZ); + sg_init_table(s, 2); + sg_set_buf(&s[0], x, EC_PT_SZ); + sg_set_buf(&s[1], y, EC_PT_SZ); + + kpp = crypto_alloc_kpp("ecdh-nist-p256", CRYPTO_ALG_INTERNAL, 0); + if (IS_ERR(kpp)) { + dev_err(&chip->dev, "crypto ecdh allocation failed\n"); + return; + } + + buf_len = crypto_ecdh_key_len(&p); + if (sizeof(encoded_key) < buf_len) { + dev_err(&chip->dev, "salt buffer too small needs %d\n", + buf_len); + goto out; + } + crypto_ecdh_encode_key(encoded_key, buf_len, &p); + /* this generates a random private key */ + crypto_kpp_set_secret(kpp, encoded_key, buf_len); + + /* salt is now the public point of this private key */ + req = kpp_request_alloc(kpp, GFP_KERNEL); + if (!req) + goto out; + kpp_request_set_input(req, NULL, 0); + kpp_request_set_output(req, s, EC_PT_SZ*2); + crypto_kpp_generate_public_key(req); + /* + * we're not done: now we have to compute the shared secret + * which is our private key multiplied by the tpm_key public + * point, we actually only take the x point and discard the y + * point and feed it through KDFe to get the final secret salt + */ + sg_set_buf(&s[0], chip->ec_point_x, EC_PT_SZ); + sg_set_buf(&s[1], chip->ec_point_y, EC_PT_SZ); + kpp_request_set_input(req, s, EC_PT_SZ*2); + sg_init_one(d, chip->auth->salt, EC_PT_SZ); + kpp_request_set_output(req, d, EC_PT_SZ); + crypto_kpp_compute_shared_secret(req); + kpp_request_free(req); + + /* + * pass the shared secret through KDFe for salt. Note salt + * area is used both for input shared secret and output salt. + * This works because KDFe fully consumes the secret before it + * writes the salt + */ + KDFe(chip->auth->salt, "SECRET", x, chip->ec_point_x, chip->auth->salt); + out: + crypto_free_kpp(kpp); +} +/** + * tpm2_end_auth_session() - kill the allocated auth session + * @chip: the TPM chip structure + * + * ends the session started by tpm2_start_auth_session and frees all + * the resources. Under normal conditions, + * tpm_buf_check_hmac_response() will correctly end the session if + * required, so this function is only for use in error legs that will + * bypass the normal invocation of tpm_buf_check_hmac_respons(). + */ +void tpm2_end_auth_session(struct tpm_chip *chip) +{ + tpm2_flush_context(chip, chip->auth->handle); + chip->auth->session = TPM_HEADER_SIZE; +} +EXPORT_SYMBOL(tpm2_end_auth_session); + +static int parse_start_auth_session(struct tpm2_auth *auth, struct tpm_buf *buf) +{ + struct tpm_header *head = (struct tpm_header *)buf->data; + u32 tot_len = be32_to_cpu(head->length); + off_t offset = TPM_HEADER_SIZE; + u32 val; + + /* we're starting after the header so adjust the length */ + tot_len -= TPM_HEADER_SIZE; + + /* should have handle plus nonce */ + if (tot_len != 4 + 2 + sizeof(auth->tpm_nonce)) + return -EINVAL; + + auth->handle = tpm_buf_read_u32(buf, &offset); + val = tpm_buf_read_u16(buf, &offset); + if (val != sizeof(auth->tpm_nonce)) + return -EINVAL; + memcpy(auth->tpm_nonce, &buf->data[offset], sizeof(auth->tpm_nonce)); + /* now compute the session key from the nonces */ + KDFa(auth->salt, sizeof(auth->salt), "ATH", auth->tpm_nonce, + auth->our_nonce, sizeof(auth->session_key), auth->session_key); + + return 0; +} + +/** + * tpm2_start_auth_session() - create a HMAC authentication session with the TPM + * @chip: the TPM chip structure to create the session with + * + * This function loads the NULL seed from its saved context and starts + * an authentication session on the null seed, fills in the + * @chip->auth structure to contain all the session details necessary + * for performing the HMAC, encrypt and decrypt operations and + * returns. The NULL seed is flushed before this function returns. + * + * Return: zero on success or actual error encountered. + */ +int tpm2_start_auth_session(struct tpm_chip *chip) +{ + struct tpm_buf buf; + struct tpm2_auth *auth = chip->auth; + int rc; + unsigned int offset = 0; /* dummy offset for null seed context */ + u32 nullkey; + + rc = tpm2_load_context(chip, chip->tpmkeycontext, &offset, + &nullkey); + if (rc) + goto out; + + auth->session = TPM_HEADER_SIZE; + + rc = tpm_buf_init(&buf, TPM2_ST_NO_SESSIONS, TPM2_CC_START_AUTH_SESS); + if (rc) + goto out; + + /* salt key handle */ + tpm_buf_append_u32(&buf, nullkey); + /* bind key handle */ + tpm_buf_append_u32(&buf, TPM2_RH_NULL); + /* nonce caller */ + get_random_bytes(auth->our_nonce, sizeof(auth->our_nonce)); + tpm_buf_append_u16(&buf, sizeof(auth->our_nonce)); + tpm_buf_append(&buf, auth->our_nonce, sizeof(auth->our_nonce)); + + /* append encrypted salt and squirrel away unencrypted in auth */ + tpm_buf_append_salt(&buf, chip); + /* session type (HMAC, audit or policy) */ + tpm_buf_append_u8(&buf, TPM2_SE_HMAC); + + /* symmetric encryption parameters */ + /* symmetric algorithm */ + tpm_buf_append_u16(&buf, TPM_ALG_AES); + /* bits for symmetric algorithm */ + tpm_buf_append_u16(&buf, AES_KEYBITS); + /* symmetric algorithm mode (must be CFB) */ + tpm_buf_append_u16(&buf, TPM_ALG_CFB); + /* hash algorithm for session */ + tpm_buf_append_u16(&buf, TPM_ALG_SHA256); + + rc = tpm_transmit_cmd(chip, &buf, 0, "start auth session"); + tpm2_flush_context(chip, nullkey); + + if (rc == TPM2_RC_SUCCESS) + rc = parse_start_auth_session(auth, &buf); + + tpm_buf_destroy(&buf); + + if (rc) + goto out; + + out: + return rc; +} +EXPORT_SYMBOL(tpm2_start_auth_session); static int parse_create_primary(struct tpm_chip *chip, struct tpm_buf *buf, u32 *nullkey) @@ -271,6 +650,10 @@ int tpm2_sessions_init(struct tpm_chip *chip) if (rc) dev_err(&chip->dev, "TPM: security failed (NULL seed derivation): %d\n", rc); + chip->auth = kmalloc(sizeof(*chip->auth), GFP_KERNEL); + if (!chip->auth) + return -ENOMEM; + return rc; } EXPORT_SYMBOL(tpm2_sessions_init); diff --git a/include/linux/tpm.h b/include/linux/tpm.h index bdb03c093914..b83269bd851c 100644 --- a/include/linux/tpm.h +++ b/include/linux/tpm.h @@ -30,6 +30,14 @@ struct tpm_chip; struct trusted_key_payload; struct trusted_key_options; +/* opaque structure, holds auth session parameters like the session key */ +struct tpm2_auth; + +enum tpm2_session_types { + TPM2_SE_HMAC = 0x00, + TPM2_SE_POLICY = 0x01, + TPM2_SE_TRIAL = 0x02, +}; /* if you add a new hash to this, increment TPM_MAX_HASHES below */ enum tpm_algorithms { @@ -199,6 +207,7 @@ struct tpm_chip { u8 tpmkeyname[TPM2_NAME_SIZE]; /* name of NULL seed */ u8 ec_point_x[EC_PT_SZ]; u8 ec_point_y[EC_PT_SZ]; + struct tpm2_auth *auth; #endif }; @@ -262,6 +271,7 @@ enum tpm2_command_codes { TPM2_CC_CONTEXT_LOAD = 0x0161, TPM2_CC_CONTEXT_SAVE = 0x0162, TPM2_CC_FLUSH_CONTEXT = 0x0165, + TPM2_CC_START_AUTH_SESS = 0x0176, TPM2_CC_VERIFY_SIGNATURE = 0x0177, TPM2_CC_GET_CAPABILITY = 0x017A, TPM2_CC_GET_RANDOM = 0x017B, @@ -345,20 +355,30 @@ struct tpm_buf { u32 flags; u32 length; u8 *data; + u8 handles; }; enum tpm2_object_attributes { TPM2_OA_FIXED_TPM = BIT(1), + TPM2_OA_ST_CLEAR = BIT(2), TPM2_OA_FIXED_PARENT = BIT(4), TPM2_OA_SENSITIVE_DATA_ORIGIN = BIT(5), TPM2_OA_USER_WITH_AUTH = BIT(6), + TPM2_OA_ADMIN_WITH_POLICY = BIT(7), TPM2_OA_NO_DA = BIT(10), + TPM2_OA_ENCRYPTED_DUPLICATION = BIT(11), TPM2_OA_RESTRICTED = BIT(16), TPM2_OA_DECRYPT = BIT(17), + TPM2_OA_SIGN = BIT(18), }; enum tpm2_session_attributes { TPM2_SA_CONTINUE_SESSION = BIT(0), + TPM2_SA_AUDIT_EXCLUSIVE = BIT(1), + TPM2_SA_AUDIT_RESET = BIT(3), + TPM2_SA_DECRYPT = BIT(5), + TPM2_SA_ENCRYPT = BIT(6), + TPM2_SA_AUDIT = BIT(7), }; struct tpm2_hash { @@ -449,4 +469,18 @@ static inline void tpm_buf_append_empty_auth(struct tpm_buf *buf, u32 handle) { } #endif +#ifdef CONFIG_TCG_TPM2_HMAC + +int tpm2_start_auth_session(struct tpm_chip *chip); +void tpm2_end_auth_session(struct tpm_chip *chip); +#else +static inline int tpm2_start_auth_session(struct tpm_chip *chip) +{ + return 0; +} +static inline void tpm2_end_auth_session(struct tpm_chip *chip) +{ +} +#endif /* CONFIG_TCG_TPM2_HMAC */ + #endif