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gnupg/tpm2d/tpm2.c

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/* tpm2.c - Supporting TPM routines for the IBM TSS
* Copyright (C) 2021 James Bottomley <James.Bottomley@HansenPartnership.com>
*
* This file is part of GnuPG.
*
* GnuPG is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* GnuPG is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <https://www.gnu.org/licenses/>.
* SPDX-License-Identifier: GPL-3.0-or-later
*/
tpm2d: Add tpm2daemon code * tpm2d: New directory. * Makefile.am (SUBDIRS): Add directory. * configure.ac: Detect libtss and decide whether to build tpm2d. * am/cmacros.am: Add a define. * util.h (GNUPG_MODULE_NAME_TPM2DAEMON): New. * common/homedir.c (gnupg_module_name): Add tpm2d. * common/mapstrings.c (macros): Add "TPM2DAEMON". * tools/gpgconf.h (GC_COMPONENT_TPM2DAEMON): New. * tools/gpgconf-comp.c (known_options_tpm2daemon): New. (gc_component): Add TPM2. (tpm2daemon_runtime_change): New. * tpm2d/Makefile.am: New. * tpm2d/command.c: New. * tpm2d/ibm-tss.h: New. * tpm2d/tpm2.c: New. * tpm2d/tpm2.h: New. * tpm2d/tpm2daemon.c: New. * tpm2d/tpm2daemon.h: New. --- This commit adds and plumbs in a tpm2daemon to the build to mirror the operation of scdaemon. The architecture of the code is that tpm2daemon.c itself is pretty much a clone of scd/scdaemon.c just with updated function prefixes (this argues there could be some further consolidation of the daemon handling code). Note that although this commit causes the daemon to be built and installed, nothing actually starts it or uses it yet. Command handling ---------------- command.c is copied from the command handler in scd.c except that the command implementation is now done in terms of tpm2 commands and the wire protocol is far simpler. The tpm2daemon only responds to 4 commands IMPORT: import a standard s-expression private key and export it to TPM2 format. This conversion cannot be undone and the private key now can *only* be used by the TPM2. To anyone who gets hold of the private key now, it's just an encrypted binary blob. PKSIGN: create a signature from the tpm2 key. The TPM2 form private key is retrieved by KEYDATA and the hash to be signed by EXTRA. Note there is no hash specifier because the tpm2 tss deduces the hash type from the length of the EXTRA data. This is actually a limitation of the tpm2 command API and it will be interesting to see how this fares if the tpm2 ever supports say sha3-256 hashes. PKDECRYPT: decrypt (RSA case) or derive (ECC case) a symmetric key. The tpm2 for private key is retrieved by KEYDATA and the information used to create the symmetric key by EXTRA. KILLTPM2D: stop the daemon All the tpm2 primitives used by command.c are in tpm2.h and all the tpm2 specific gunk is confined to tpm2.c, which is the only piece of this that actually does calls into the tss library. Signed-off-by: James Bottomley <James.Bottomley@HansenPartnership.com> Changes from James' patch: - gpgconf: The displayed name is "TPM" and not "TPM2". That string is used by GUIs and should be something the user understands. For example we also use "network" instead of "Dirmngr". - Removed some commented includes. - Use 16 as emulation of GPG_ERR_SOURCE_TPM2. - Silenced a C90 compiler warning and flags unused parameters. - Removed "if HAVE_LIBS" from tpm2/Makefile.am and add missing files so that make distcheck works. Signed-off-by: Werner Koch <wk@gnupg.org>
2021-03-09 22:50:28 +01:00
#include <config.h>
#include <errno.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
#include <assert.h>
#include <unistd.h>
#include <sys/stat.h>
#include <arpa/inet.h>
#include "tpm2.h"
#include "../common/i18n.h"
#include "../common/sexp-parse.h"
int
tpm2_start (TSS_CONTEXT **tssc)
{
return TSS_start(tssc);
}
void
tpm2_end (TSS_CONTEXT *tssc)
{
TSS_Delete (tssc);
}
static TPM_HANDLE
tpm2_get_parent (TSS_CONTEXT *tssc, TPM_HANDLE p)
{
TPM_RC rc;
TPM2B_SENSITIVE_CREATE inSensitive;
TPM2B_PUBLIC inPublic;
TPM_HANDLE objectHandle;
p = tpm2_handle_int(tssc, p);
if (tpm2_handle_mso(tssc, p, TPM_HT_PERSISTENT))
return p; /* should only be permanent */
/* assume no hierarchy auth */
VAL_2B (inSensitive.sensitive.userAuth, size) = 0;
/* no sensitive date for storage keys */
VAL_2B (inSensitive.sensitive.data, size) = 0;
/* public parameters for a P-256 EC key */
inPublic.publicArea.type = TPM_ALG_ECC;
inPublic.publicArea.nameAlg = TPM_ALG_SHA256;
VAL (inPublic.publicArea.objectAttributes) =
TPMA_OBJECT_NODA |
TPMA_OBJECT_SENSITIVEDATAORIGIN |
TPMA_OBJECT_USERWITHAUTH |
TPMA_OBJECT_DECRYPT |
TPMA_OBJECT_RESTRICTED |
TPMA_OBJECT_FIXEDPARENT |
TPMA_OBJECT_FIXEDTPM;
inPublic.publicArea.parameters.eccDetail.symmetric.algorithm = TPM_ALG_AES;
inPublic.publicArea.parameters.eccDetail.symmetric.keyBits.aes = 128;
inPublic.publicArea.parameters.eccDetail.symmetric.mode.aes = TPM_ALG_CFB;
inPublic.publicArea.parameters.eccDetail.scheme.scheme = TPM_ALG_NULL;
inPublic.publicArea.parameters.eccDetail.curveID = TPM_ECC_NIST_P256;
inPublic.publicArea.parameters.eccDetail.kdf.scheme = TPM_ALG_NULL;
VAL_2B (inPublic.publicArea.unique.ecc.x, size) = 0;
VAL_2B (inPublic.publicArea.unique.ecc.y, size) = 0;
VAL_2B (inPublic.publicArea.authPolicy, size) = 0;
rc = tpm2_CreatePrimary (tssc, p, &inSensitive, &inPublic, &objectHandle);
if (rc)
{
tpm2_error (rc, "TSS_CreatePrimary");
return 0;
}
return objectHandle;
}
void
tpm2_flush_handle (TSS_CONTEXT *tssc, TPM_HANDLE h)
{
/* only flush volatile handles */
if (tpm2_handle_mso(tssc, h, TPM_HT_PERSISTENT))
return;
tpm2_FlushContext(tssc, h);
}
static int
tpm2_get_hmac_handle (TSS_CONTEXT *tssc, TPM_HANDLE *handle,
TPM_HANDLE salt_key)
{
TPM_RC rc;
TPMT_SYM_DEF symmetric;
symmetric.algorithm = TPM_ALG_AES;
symmetric.keyBits.aes = 128;
symmetric.mode.aes = TPM_ALG_CFB;
rc = tpm2_StartAuthSession(tssc, salt_key, TPM_RH_NULL, TPM_SE_HMAC,
&symmetric, TPM_ALG_SHA256, handle, NULL);
if (rc)
{
tpm2_error (rc, "TPM2_StartAuthSession");
return GPG_ERR_CARD;
}
return 0;
}
static int
tpm2_pre_auth (ctrl_t ctrl, TSS_CONTEXT *tssc,
gpg_error_t (*pin_cb)(ctrl_t ctrl, const char *info,
char **retstr),
TPM_HANDLE *ah, char **auth)
{
TPM_RC rc;
int len;
rc = pin_cb (ctrl, _("TPM Key Passphrase"), auth);
if (rc)
return rc;
len = strlen(*auth);
/*
* TPMs can't accept a longer passphrase than the name algorithm.
* We hard code the name algorithm to SHA256 so the max passphrase
* length is 32
*/
if (len > 32)
{
log_error ("Truncating Passphrase to TPM allowed 32\n");
(*auth)[32] = '\0';
}
rc = tpm2_get_hmac_handle (tssc, ah, TPM_RH_NULL);
return rc;
}
static int
tpm2_post_auth (TSS_CONTEXT *tssc, TPM_RC rc, TPM_HANDLE ah,
char **auth, const char *cmd_str)
{
gcry_free (*auth);
*auth = NULL;
if (rc)
{
tpm2_error (rc, cmd_str);
tpm2_flush_handle (tssc, ah);
switch (rc & 0xFF)
{
case TPM_RC_BAD_AUTH:
case TPM_RC_AUTH_FAIL:
return GPG_ERR_BAD_PASSPHRASE;
default:
return GPG_ERR_CARD;
}
}
return 0;
}
static unsigned char *
make_tpm2_shadow_info (uint32_t parent, const char *pub, int pub_len,
const char *priv, int priv_len, size_t *len)
{
gcry_sexp_t s_exp;
char *info;
gcry_sexp_build (&s_exp, NULL, "(%u%b%b)", parent, pub_len, pub,
priv_len, priv);
*len = gcry_sexp_sprint (s_exp, GCRYSEXP_FMT_CANON, NULL, 0);
info = xtrymalloc (*len);
if (!info)
goto out;
gcry_sexp_sprint (s_exp, GCRYSEXP_FMT_CANON, info, *len);
out:
gcry_sexp_release (s_exp);
return (unsigned char *)info;
}
static gpg_error_t
parse_tpm2_shadow_info (const unsigned char *shadow_info,
uint32_t *parent,
const char **pub, int *pub_len,
const char **priv, int *priv_len)
{
const unsigned char *s;
size_t n;
int i;
s = shadow_info;
if (*s != '(')
return gpg_error (GPG_ERR_INV_SEXP);
s++;
n = snext (&s);
if (!n)
return gpg_error (GPG_ERR_INV_SEXP);
*parent = 0;
for (i = 0; i < n; i++)
{
*parent *= 10;
*parent += atoi_1(s+i);
}
s += n;
n = snext (&s);
if (!n)
return gpg_error (GPG_ERR_INV_SEXP);
*pub_len = n;
*pub = s;
s += n;
n = snext (&s);
if (!n)
return gpg_error (GPG_ERR_INV_SEXP);
*priv_len = n;
*priv = s;
return 0;
}
int
tpm2_load_key (TSS_CONTEXT *tssc, const unsigned char *shadow_info,
TPM_HANDLE *key, TPMI_ALG_PUBLIC *type)
{
uint32_t parent;
TPM_HANDLE parentHandle;
PRIVATE_2B inPrivate;
TPM2B_PUBLIC inPublic;
const char *pub, *priv;
int ret, pub_len, priv_len;
TPM_RC rc;
BYTE *buf;
uint32_t size;
ret = parse_tpm2_shadow_info (shadow_info, &parent, &pub, &pub_len,
&priv, &priv_len);
if (ret)
return ret;
parentHandle = tpm2_get_parent (tssc, parent);
buf = (BYTE *)priv;
size = priv_len;
TPM2B_PRIVATE_Unmarshal ((TPM2B_PRIVATE *)&inPrivate, &buf, &size);
buf = (BYTE *)pub;
size = pub_len;
TPM2B_PUBLIC_Unmarshal (&inPublic, &buf, &size, FALSE);
*type = inPublic.publicArea.type;
rc = tpm2_Load (tssc, parentHandle, &inPrivate, &inPublic, key,
TPM_RS_PW, NULL);
tpm2_flush_handle (tssc, parentHandle);
if (rc != TPM_RC_SUCCESS)
{
tpm2_error (rc, "TPM2_Load");
return GPG_ERR_CARD;
}
return 0;
}
int
tpm2_sign (ctrl_t ctrl, TSS_CONTEXT *tssc, TPM_HANDLE key,
gpg_error_t (*pin_cb)(ctrl_t ctrl, const char *info,
char **retstr),
TPMI_ALG_PUBLIC type,
const unsigned char *digest, size_t digestlen,
unsigned char **r_sig, size_t *r_siglen)
{
int ret;
DIGEST_2B digest2b;
TPMT_SIG_SCHEME inScheme;
TPMT_SIGNATURE signature;
TPM_HANDLE ah;
char *auth;
/* The TPM insists on knowing the digest type, so
* calculate that from the size */
switch (digestlen)
{
case 20:
inScheme.details.rsassa.hashAlg = TPM_ALG_SHA1;
break;
case 32:
inScheme.details.rsassa.hashAlg = TPM_ALG_SHA256;
break;
case 48:
inScheme.details.rsassa.hashAlg = TPM_ALG_SHA384;
break;
#ifdef TPM_ALG_SHA512
case 64:
inScheme.details.rsassa.hashAlg = TPM_ALG_SHA512;
break;
#endif
default:
log_error ("Unknown signature digest length, cannot deduce hash type for TPM\n");
return GPG_ERR_NO_SIGNATURE_SCHEME;
}
digest2b.size = digestlen;
memcpy (digest2b.buffer, digest, digestlen);
if (type == TPM_ALG_RSA)
inScheme.scheme = TPM_ALG_RSASSA;
else if (type == TPM_ALG_ECC)
inScheme.scheme = TPM_ALG_ECDSA;
else
return GPG_ERR_PUBKEY_ALGO;
ret = tpm2_pre_auth (ctrl, tssc, pin_cb, &ah, &auth);
if (ret)
return ret;
ret = tpm2_Sign (tssc, key, &digest2b, &inScheme, &signature, ah, auth);
ret = tpm2_post_auth (tssc, ret, ah, &auth, "TPM2_Sign");
if (ret)
return ret;
if (type == TPM_ALG_RSA)
*r_siglen = VAL_2B (signature.signature.rsassa.sig, size);
else if (type == TPM_ALG_ECC)
*r_siglen = VAL_2B (signature.signature.ecdsa.signatureR, size)
+ VAL_2B (signature.signature.ecdsa.signatureS, size);
*r_sig = xtrymalloc (*r_siglen);
if (!r_sig)
return GPG_ERR_ENOMEM;
if (type == TPM_ALG_RSA)
{
memcpy (*r_sig, VAL_2B (signature.signature.rsassa.sig, buffer),
*r_siglen);
}
else if (type == TPM_ALG_ECC)
{
memcpy (*r_sig, VAL_2B (signature.signature.ecdsa.signatureR, buffer),
VAL_2B (signature.signature.ecdsa.signatureR, size));
memcpy (*r_sig + VAL_2B (signature.signature.ecdsa.signatureR, size),
VAL_2B (signature.signature.ecdsa.signatureS, buffer),
VAL_2B (signature.signature.ecdsa.signatureS, size));
}
return 0;
}
static int
sexp_to_tpm2_sensitive_ecc (TPMT_SENSITIVE *s, gcry_sexp_t key)
{
gcry_mpi_t d;
gcry_sexp_t l;
int rc = -1;
size_t len;
s->sensitiveType = TPM_ALG_ECC;
VAL_2B (s->seedValue, size) = 0;
l = gcry_sexp_find_token (key, "d", 0);
if (!l)
return rc;
d = gcry_sexp_nth_mpi (l, 1, GCRYMPI_FMT_USG);
gcry_sexp_release (l);
len = sizeof (VAL_2B (s->sensitive.ecc, buffer));
rc = gcry_mpi_print (GCRYMPI_FMT_USG, VAL_2B (s->sensitive.ecc, buffer),
len, &len, d);
VAL_2B (s->sensitive.ecc, size) = len;
gcry_mpi_release (d);
return rc;
}
/* try to match the libgcrypt curve names to known TPM parameters.
*
* As of 2018 the TCG defined curves are only NIST
* (192,224,256,384,521) Barreto-Naehring (256,638) and the Chinese
* SM2 (256), which means only the NIST ones overlap with libgcrypt */
static struct {
const char *name;
TPMI_ECC_CURVE c;
} tpm2_curves[] = {
{ "NIST P-192", TPM_ECC_NIST_P192 },
{ "prime192v1", TPM_ECC_NIST_P192 },
{ "secp192r1", TPM_ECC_NIST_P192 },
{ "nistp192", TPM_ECC_NIST_P192 },
{ "NIST P-224", TPM_ECC_NIST_P224 },
{ "secp224r1", TPM_ECC_NIST_P224 },
{ "nistp224", TPM_ECC_NIST_P224 },
{ "NIST P-256", TPM_ECC_NIST_P256 },
{ "prime256v1", TPM_ECC_NIST_P256 },
{ "secp256r1", TPM_ECC_NIST_P256 },
{ "nistp256", TPM_ECC_NIST_P256 },
{ "NIST P-384", TPM_ECC_NIST_P384 },
{ "secp384r1", TPM_ECC_NIST_P384 },
{ "nistp384", TPM_ECC_NIST_P384 },
{ "NIST P-521", TPM_ECC_NIST_P521 },
{ "secp521r1", TPM_ECC_NIST_P521 },
{ "nistp521", TPM_ECC_NIST_P521 },
};
static int
tpm2_ecc_curve (const char *curve_name, TPMI_ECC_CURVE *c)
{
int i;
for (i = 0; i < DIM (tpm2_curves); i++)
if (strcmp (tpm2_curves[i].name, curve_name) == 0)
break;
if (i == DIM (tpm2_curves))
{
log_error ("curve %s does not match any available TPM curves\n", curve_name);
return GPG_ERR_UNKNOWN_CURVE;
}
*c = tpm2_curves[i].c;
return 0;
}
static int
sexp_to_tpm2_public_ecc (TPMT_PUBLIC *p, gcry_sexp_t key)
{
const char *q;
gcry_sexp_t l;
int rc = GPG_ERR_BAD_PUBKEY;
size_t len;
TPMI_ECC_CURVE curve;
char *curve_name;
l = gcry_sexp_find_token (key, "curve", 0);
if (!l)
return rc;
curve_name = gcry_sexp_nth_string (l, 1);
if (!curve_name)
goto out;
rc = tpm2_ecc_curve (curve_name, &curve);
gcry_free (curve_name);
if (rc)
goto out;
gcry_sexp_release (l);
l = gcry_sexp_find_token (key, "q", 0);
if (!l)
return rc;
q = gcry_sexp_nth_data (l, 1, &len);
/* This is a point representation, the first byte tells you what
* type. The only format we understand is uncompressed (0x04)
* which has layout 0x04 | x | y */
if (q[0] != 0x04)
{
log_error ("Point format for q is not uncompressed\n");
goto out;
}
q++;
len--;
/* now should have to equal sized big endian point numbers */
if ((len & 0x01) == 1)
{
log_error ("Point format for q has incorrect length\n");
goto out;
}
len >>= 1;
p->type = TPM_ALG_ECC;
p->nameAlg = TPM_ALG_SHA256;
VAL (p->objectAttributes) = TPMA_OBJECT_NODA |
TPMA_OBJECT_SIGN |
TPMA_OBJECT_DECRYPT |
TPMA_OBJECT_USERWITHAUTH;
VAL_2B (p->authPolicy, size) = 0;
p->parameters.eccDetail.symmetric.algorithm = TPM_ALG_NULL;
p->parameters.eccDetail.scheme.scheme = TPM_ALG_NULL;
p->parameters.eccDetail.curveID = curve;
p->parameters.eccDetail.kdf.scheme = TPM_ALG_NULL;
memcpy (VAL_2B (p->unique.ecc.x, buffer), q, len);
VAL_2B (p->unique.ecc.x, size) = len;
memcpy (VAL_2B (p->unique.ecc.y, buffer), q + len, len);
VAL_2B (p->unique.ecc.y, size) = len;
out:
gcry_sexp_release (l);
return rc;
}
static int
sexp_to_tpm2_sensitive_rsa (TPMT_SENSITIVE *s, gcry_sexp_t key)
{
gcry_mpi_t p;
gcry_sexp_t l;
int rc = -1;
size_t len;
s->sensitiveType = TPM_ALG_RSA;
VAL_2B (s->seedValue, size) = 0;
l = gcry_sexp_find_token (key, "p", 0);
if (!l)
return rc;
p = gcry_sexp_nth_mpi (l, 1, GCRYMPI_FMT_USG);
gcry_sexp_release (l);
len = sizeof (VAL_2B (s->sensitive.rsa, buffer));
rc = gcry_mpi_print (GCRYMPI_FMT_USG, VAL_2B (s->sensitive.rsa, buffer),
len, &len, p);
VAL_2B (s->sensitive.rsa, size) = len;
gcry_mpi_release (p);
return rc;
}
static int
sexp_to_tpm2_public_rsa (TPMT_PUBLIC *p, gcry_sexp_t key)
{
gcry_mpi_t n, e;
gcry_sexp_t l;
int rc = -1, i;
size_t len;
/* longer than an int */
unsigned char ebuf[5];
uint32_t exp = 0;
p->type = TPM_ALG_RSA;
p->nameAlg = TPM_ALG_SHA256;
VAL (p->objectAttributes) = TPMA_OBJECT_NODA |
TPMA_OBJECT_DECRYPT |
TPMA_OBJECT_SIGN |
TPMA_OBJECT_USERWITHAUTH;
VAL_2B (p->authPolicy, size) = 0;
p->parameters.rsaDetail.symmetric.algorithm = TPM_ALG_NULL;
p->parameters.rsaDetail.scheme.scheme = TPM_ALG_NULL;
l = gcry_sexp_find_token (key, "n", 0);
if (!l)
return rc;
n = gcry_sexp_nth_mpi (l, 1, GCRYMPI_FMT_USG);
gcry_sexp_release (l);
len = sizeof (VAL_2B (p->unique.rsa, buffer));
p->parameters.rsaDetail.keyBits = gcry_mpi_get_nbits (n);
rc = gcry_mpi_print (GCRYMPI_FMT_USG, VAL_2B (p->unique.rsa, buffer),
len, &len, n);
VAL_2B (p->unique.rsa, size) = len;
gcry_mpi_release (n);
if (rc)
return rc;
rc = -1;
l = gcry_sexp_find_token (key, "e", 0);
if (!l)
return rc;
e = gcry_sexp_nth_mpi (l, 1, GCRYMPI_FMT_USG);
gcry_sexp_release (l);
len = sizeof (ebuf);
rc = gcry_mpi_print (GCRYMPI_FMT_USG, ebuf, len, &len, e);
gcry_mpi_release (e);
if (rc)
return rc;
if (len > 4)
return -1;
/* MPI are simply big endian integers, so convert to uint32 */
for (i = 0; i < len; i++)
{
exp <<= 8;
exp += ebuf[i];
}
if (exp == 0x10001)
p->parameters.rsaDetail.exponent = 0;
else
p->parameters.rsaDetail.exponent = exp;
return 0;
}
static int
sexp_to_tpm2(TPMT_PUBLIC *p, TPMT_SENSITIVE *s, gcry_sexp_t s_skey)
{
gcry_sexp_t l1, l2;
int rc = -1;
/* find the value of (private-key */
l1 = gcry_sexp_nth (s_skey, 1);
if (!l1)
return rc;
l2 = gcry_sexp_find_token (l1, "rsa", 0);
if (l2)
{
rc = sexp_to_tpm2_public_rsa (p, l2);
if (!rc)
rc = sexp_to_tpm2_sensitive_rsa (s, l2);
}
else
{
l2 = gcry_sexp_find_token (l1, "ecc", 0);
if (!l2)
goto out;
rc = sexp_to_tpm2_public_ecc (p, l2);
if (!rc)
rc = sexp_to_tpm2_sensitive_ecc (s, l2);
}
gcry_sexp_release (l2);
out:
gcry_sexp_release (l1);
return rc;
}
/* copied from TPM implementation code */
static TPM_RC
tpm2_ObjectPublic_GetName (NAME_2B *name,
TPMT_PUBLIC *tpmtPublic)
{
TPM_RC rc = 0;
uint16_t written = 0;
TPMT_HA digest;
uint32_t sizeInBytes;
uint8_t buffer[MAX_RESPONSE_SIZE];
/* marshal the TPMT_PUBLIC */
if (rc == 0)
{
INT32 size = MAX_RESPONSE_SIZE;
uint8_t *buffer1 = buffer;
rc = TSS_TPMT_PUBLIC_Marshal (tpmtPublic, &written, &buffer1, &size);
}
/* hash the public area */
if (rc == 0)
{
sizeInBytes = TSS_GetDigestSize (tpmtPublic->nameAlg);
digest.hashAlg = tpmtPublic->nameAlg; /* Name digest algorithm */
/* generate the TPMT_HA */
rc = TSS_Hash_Generate (&digest, written, buffer, 0, NULL);
}
if (rc == 0)
{
TPMI_ALG_HASH nameAlgNbo;
/* copy the digest */
memcpy (name->name + sizeof (TPMI_ALG_HASH),
(uint8_t *)&digest.digest, sizeInBytes);
/* copy the hash algorithm */
nameAlgNbo = htons (tpmtPublic->nameAlg);
memcpy (name->name, (uint8_t *)&nameAlgNbo, sizeof (TPMI_ALG_HASH));
/* set the size */
name->size = sizeInBytes + sizeof (TPMI_ALG_HASH);
}
return rc;
}
/*
* Cut down version of Part 4 Supporting Routines 7.6.3.10
*
* Hard coded to symmetrically encrypt with aes128 as the inner
* wrapper and no outer wrapper but with a prototype that allows
* drop in replacement with a tss equivalent
*/
TPM_RC tpm2_SensitiveToDuplicate (TPMT_SENSITIVE *s,
NAME_2B *name,
TPM_ALG_ID nalg,
TPMT_SYM_DEF_OBJECT *symdef,
DATA_2B *innerkey,
PRIVATE_2B *p)
{
BYTE *buf = p->buffer;
p->size = 0;
memset (p, 0, sizeof (*p));
/* hard code AES CFB */
if (symdef->algorithm == TPM_ALG_AES
&& symdef->mode.aes == TPM_ALG_CFB)
{
TPMT_HA hash;
const int hlen = TSS_GetDigestSize (nalg);
TPM2B *digest = (TPM2B *)buf;
TPM2B *s2b;
int32_t size;
unsigned char null_iv[AES_128_BLOCK_SIZE_BYTES];
UINT16 bsize, written = 0;
gcry_cipher_hd_t hd;
/* WARNING: don't use the static null_iv trick here:
* the AES routines alter the passed in iv */
memset (null_iv, 0, sizeof (null_iv));
/* reserve space for hash before the encrypted sensitive */
bsize = sizeof (digest->size) + hlen;
buf += bsize;
p->size += bsize;
s2b = (TPM2B *)buf;
/* marshal the digest size */
buf = (BYTE *)&digest->size;
bsize = hlen;
size = 2;
TSS_UINT16_Marshal (&bsize, &written, &buf, &size);
/* marshal the unencrypted sensitive in place */
size = sizeof (*s);
bsize = 0;
buf = s2b->buffer;
TSS_TPMT_SENSITIVE_Marshal (s, &bsize, &buf, &size);
buf = (BYTE *)&s2b->size;
size = 2;
TSS_UINT16_Marshal (&bsize, &written, &buf, &size);
bsize = bsize + sizeof (s2b->size);
p->size += bsize;
/* compute hash of unencrypted marshalled sensitive and
* write to the digest buffer */
hash.hashAlg = nalg;
TSS_Hash_Generate (&hash, bsize, s2b,
name->size, name->name,
0, NULL);
memcpy (digest->buffer, &hash.digest, hlen);
gcry_cipher_open (&hd, GCRY_CIPHER_AES128,
GCRY_CIPHER_MODE_CFB, GCRY_CIPHER_SECURE);
gcry_cipher_setiv (hd, null_iv, sizeof (null_iv));
gcry_cipher_setkey (hd, innerkey->buffer, innerkey->size);
/* encrypt the hash and sensitive in-place */
gcry_cipher_encrypt (hd, p->buffer, p->size, NULL, 0);
gcry_cipher_close (hd);
}
else if (symdef->algorithm == TPM_ALG_NULL)
{
/* Code is for debugging only, should never be used in production */
TPM2B *s2b = (TPM2B *)buf;
int32_t size = sizeof (*s);
UINT16 bsize = 0, written = 0;
log_error ("Secret key sent to TPM unencrypted\n");
buf = s2b->buffer;
/* marshal the unencrypted sensitive in place */
TSS_TPMT_SENSITIVE_Marshal (s, &bsize, &buf, &size);
buf = (BYTE *)&s2b->size;
size = 2;
TSS_UINT16_Marshal (&bsize, &written, &buf, &size);
p->size += bsize + sizeof (s2b->size);
}
else
{
log_error ("Unknown symmetric algorithm\n");
return TPM_RC_SYMMETRIC;
}
return TPM_RC_SUCCESS;
}
int
tpm2_import_key (ctrl_t ctrl, TSS_CONTEXT *tssc,
gpg_error_t (*pin_cb)(ctrl_t ctrl, const char *info,
char **retstr),
unsigned char **shadow_info, size_t *shadow_len,
gcry_sexp_t s_skey, unsigned long parent)
{
TPM_HANDLE parentHandle;
DATA_2B encryptionKey;
TPM2B_PUBLIC objectPublic;
PRIVATE_2B duplicate;
ENCRYPTED_SECRET_2B inSymSeed;
TPMT_SYM_DEF_OBJECT symmetricAlg;
PRIVATE_2B outPrivate;
NAME_2B name;
const int aes_key_bits = 128;
const int aes_key_bytes = aes_key_bits/8;
TPMT_SENSITIVE s;
TPM_HANDLE ah;
TPM_RC rc;
uint32_t size;
uint16_t len;
BYTE *buffer;
int ret;
char *passphrase;
char pub[sizeof (TPM2B_PUBLIC)];
int pub_len;
char priv[sizeof (TPM2B_PRIVATE)];
int priv_len;
if (parent == 0)
parent = EXT_TPM_RH_OWNER;
ret = sexp_to_tpm2 (&objectPublic.publicArea, &s, s_skey);
if (ret)
{
log_error ("Failed to parse Key s-expression: key corrupt?\n");
return ret;
}
/* add an authorization password to the key which the TPM will check */
ret = pin_cb (ctrl, _("Please enter the TPM Authorization passphrase for the key."), &passphrase);
if (ret)
return ret;
len = strlen(passphrase);
if (len > TSS_GetDigestSize(objectPublic.publicArea.nameAlg))
{
len = TSS_GetDigestSize(objectPublic.publicArea.nameAlg);
log_error ("Truncating Passphrase to TPM allowed %d\n", len);
}
VAL_2B (s.authValue, size) = len;
memcpy (VAL_2B (s.authValue, buffer), passphrase, len);
/* We're responsible for securing the data in transmission to the
* TPM here. The TPM provides parameter encryption via a session,
* but only for the first parameter. For TPM2_Import, the first
* parameter is a symmetric key used to encrypt the sensitive data,
* so we must populate this key with random value and encrypt the
* sensitive data with it */
parentHandle = tpm2_get_parent (tssc, parent);
tpm2_ObjectPublic_GetName (&name, &objectPublic.publicArea);
gcry_randomize (encryptionKey.buffer,
aes_key_bytes, GCRY_STRONG_RANDOM);
encryptionKey.size = aes_key_bytes;
/* set random symSeed */
inSymSeed.size = 0;
symmetricAlg.algorithm = TPM_ALG_AES;
symmetricAlg.keyBits.aes = aes_key_bits;
symmetricAlg.mode.aes = TPM_ALG_CFB;
tpm2_SensitiveToDuplicate (&s, &name, objectPublic.publicArea.nameAlg,
&symmetricAlg, &encryptionKey, &duplicate);
/* use salted parameter encryption to hide the key. First we read
* the public parameters of the parent key and use them to agree an
* encryption for the first parameter */
rc = tpm2_get_hmac_handle (tssc, &ah, parentHandle);
if (rc)
{
tpm2_flush_handle (tssc, parentHandle);
return GPG_ERR_CARD;
}
rc = tpm2_Import (tssc, parentHandle, &encryptionKey, &objectPublic,
&duplicate, &inSymSeed, &symmetricAlg, &outPrivate,
ah, NULL);
tpm2_flush_handle (tssc, parentHandle);
if (rc)
{
tpm2_error (rc, "TPM2_Import");
/* failure means auth handle is not flushed */
tpm2_flush_handle (tssc, ah);
if ((rc & 0xbf) == TPM_RC_VALUE)
{
log_error ("TPM cannot import RSA key: wrong size");
return GPG_ERR_UNSUPPORTED_ALGORITHM;
}
else if ((rc & 0xbf) == TPM_RC_CURVE)
{
log_error ("TPM cannot import requested curve");
return GPG_ERR_UNKNOWN_CURVE;
}
return GPG_ERR_CARD;
}
size = sizeof (pub);
buffer = pub;
len = 0;
TSS_TPM2B_PUBLIC_Marshal (&objectPublic,
&len, &buffer, &size);
pub_len = len;
size = sizeof (priv);
buffer = priv;
len = 0;
TSS_TPM2B_PRIVATE_Marshal ((TPM2B_PRIVATE *)&outPrivate,
&len, &buffer, &size);
priv_len = len;
*shadow_info = make_tpm2_shadow_info (parent, pub, pub_len,
priv, priv_len, shadow_len);
return rc;
}
int
tpm2_ecc_decrypt (ctrl_t ctrl, TSS_CONTEXT *tssc, TPM_HANDLE key,
gpg_error_t (*pin_cb)(ctrl_t ctrl, const char *info,
char **retstr),
const char *ciphertext, int ciphertext_len,
char **decrypt, size_t *decrypt_len)
{
TPM2B_ECC_POINT inPoint;
TPM2B_ECC_POINT outPoint;
TPM_HANDLE ah;
char *auth;
size_t len;
int ret;
/* This isn't really a decryption per se. The ciphertext actually
* contains an EC Point which we must multiply by the private key number.
*
* The reason is to generate a diffe helman agreement on a shared
* point. This shared point is then used to generate the per
* session encryption key.
*/
if (ciphertext[0] != 0x04)
{
log_error ("Decryption Shared Point format is not uncompressed\n");
return GPG_ERR_ENCODING_PROBLEM;
}
if ((ciphertext_len & 0x01) != 1)
{
log_error ("Decryption Shared Point has incorrect length\n");
return GPG_ERR_ENCODING_PROBLEM;
}
len = ciphertext_len >> 1;
memcpy (VAL_2B (inPoint.point.x, buffer), ciphertext + 1, len);
VAL_2B (inPoint.point.x, size) = len;
memcpy (VAL_2B (inPoint.point.y, buffer), ciphertext + 1 + len, len);
VAL_2B (inPoint.point.y, size) = len;
ret = tpm2_pre_auth (ctrl, tssc, pin_cb, &ah, &auth);
if (ret)
return ret;
ret = tpm2_ECDH_ZGen (tssc, key, &inPoint, &outPoint, ah, auth);
ret = tpm2_post_auth (tssc, ret, ah, &auth, "TPM2_ECDH_ZGen");
if (ret)
return ret;
*decrypt_len = VAL_2B (outPoint.point.x, size) +
VAL_2B (outPoint.point.y, size) + 1;
*decrypt = xtrymalloc (*decrypt_len);
(*decrypt)[0] = 0x04;
memcpy (*decrypt + 1, VAL_2B (outPoint.point.x, buffer),
VAL_2B (outPoint.point.x, size));
memcpy (*decrypt + 1 + VAL_2B (outPoint.point.x, size),
VAL_2B (outPoint.point.y, buffer),
VAL_2B (outPoint.point.y, size));
return 0;
}
int
tpm2_rsa_decrypt (ctrl_t ctrl, TSS_CONTEXT *tssc, TPM_HANDLE key,
gpg_error_t (*pin_cb)(ctrl_t ctrl, const char *info,
char **retstr),
const char *ciphertext, int ciphertext_len,
char **decrypt, size_t *decrypt_len)
{
int ret;
PUBLIC_KEY_RSA_2B cipherText;
TPMT_RSA_DECRYPT inScheme;
PUBLIC_KEY_RSA_2B message;
TPM_HANDLE ah;
char *auth;
inScheme.scheme = TPM_ALG_RSAES;
/*
* apparent gcrypt error: occasionally rsa ciphertext will
* be one byte too long and have a leading zero
*/
if ((ciphertext_len & 1) == 1 && ciphertext[0] == 0)
{
log_info ("Fixing Wrong Ciphertext size %d\n", ciphertext_len);
ciphertext_len--;
ciphertext++;
}
cipherText.size = ciphertext_len;
memcpy (cipherText.buffer, ciphertext, ciphertext_len);
ret = tpm2_pre_auth (ctrl, tssc, pin_cb, &ah, &auth);
if (ret)
return ret;
ret = tpm2_RSA_Decrypt (tssc, key, &cipherText, &inScheme, &message,
ah, auth, TPMA_SESSION_ENCRYPT);
ret = tpm2_post_auth (tssc, ret, ah, &auth, "TPM2_RSA_Decrypt");
if (ret)
return ret;
*decrypt_len = message.size;
*decrypt = xtrymalloc (message.size);
memcpy (*decrypt, message.buffer, message.size);
return 0;
}