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A few parsing problems remaining, mostly with objects large enough
that PKCS #8 may have pushed them over some buffer size or another.
These are all with RSA, where the Python code (PyCrypto) already
supported PKCS #8, so most likely it's a problem in the new C code.
Python ECDSA PKCS #8 shim code is nasty and could use some cleanup.
If practical, we might want to sub-class ecdsa.keys.SigningKey; we
might also want to flesh this out into something we can send upstream
to the author of the Python ecdsa library.
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Compiles, not yet tested. Existing tests need conversion to PKCS #8
before we can do anything useful with this.
Once everything uses PKCS #8 instead of algorithm-specific formats, we
can revisit API issues like whether hal_rpc_pkey_load() should still
be taking `type` and `curve` arguments.
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This will almost certainly merge into test scripts or libhal.py at
some later date, right now just get it into git for archive.
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Support for the core/pkey/ecdsa{256,384} cores is cooked before the
branch on which it was based. Oops. Time to backport.
See pymux branch for original commit history. git should do the right
thing when the pymux branch is cooked enough to merge back to the ksng
or master branches.
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Support for core/pkey/ecdsa256 and core/pkey/ecdsa384.
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Exporting CFLAGS as an environment variable turns out to interact
badly with certain other settings here. I *think* this only happens
when we use one of the shorthand targets which re-runs make in the
same directory with non-default settings, but this is complicated
enough without having to remember which voodoo triggers it. So
instead of exporting CFLAGS as an environment variable we just pass it
on the command line in the handful of cases where it's needed.
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The stock assert() implementation turns out to be problematic in the
stm32 environment, due to the lack of an output device, which makes
"assert(foo)" equivalent to "if (!foo) abort()", leading to silent
hangs.
We probably ought to reimplement assert() to do something more useful,
but, for now, avoid using it for "impossible" conditions which we do
seem to be triggering anyway, like the occasional point-not-on-curve
errors we get for points we ourselves have picked when testing
multiple ECDSA clients in parallel. This should never happen, and we
need to figure out what's causing it, but hanging the HSM when it
happens does not help very much.
assert() is somewhat problematic in an embedded environment in any
case, since anything that can go wrong really should have some kind of
recovery action, but in some of the low-probability cases it's far
from obvious what sane recovery action we could possibly take.
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libhal and PKCS #11 have slightly different models of private keys: in
libhal, a "private key" object is really a keypair, while in PKCS #11
a private key really is a naked private key. This was a deliberate
design decision in libhal, both for simplicity and to better support
user interfaces other than PKCS #11, so we'd rather not change it.
This difference doesn't matter very much for RSA keys in PKCS #11,
where the private key components are a superset of the public key
components anyway, but the PKCS #11 template for ECDSA private keys
doesn't allow setting public key components with C_CreateObject().
Fortunately, computing the public components of an ECDSA key pair from
the private key is straightforward, so we just do that when needed.
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Merge Paul's review comments.
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Log exceptions immediately when failing a test; doesn't replace
backtrace at end of test run, but since a full test run can take a
while it's useful to know what failed closer to when it happened.
More conditionals to skip tests which require external Python crypto
packages when those packages aren't installed.
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Attempts to use Pavel's ecdsa256 base point multiplier instead of
software point multiplier when selecting new random points (that is,
when generating P-256 keys or P-256 signatures). Resulting points
pass the point validation test (point_is_on_curve()) but the resulting
signatures are invalid. Don't know why yet. Seems like an odd
combination, as one would expect random garbage to fail validation.
In any case: this commit is intended to archive progress so far, and
perhaps see if somebody else can spot what's wrong. As presently
coded, this wouldn't be suitable for production use even if it worked.
NB: As I understand it, the ecdsa256 core is *not* a general purpose
point multiplier even just for the P-256 curve. Rather, it is
strictly a base point multiplier: it takes a single scalar as input,
and returns the X,Y affine coordinates of the curve's base point
multiplied by that scalar. This is essentially the eliptic curve
portion of the computation involved in picking a random point for key
or signature generation, but is not useful for signature validation.
See the README.md in Pavel's source repository for further details.
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Probably reached the point of diminishing returns for trying to get
probing to work better. Best option, where practical, is to avoid
probing completely; when necessary, best run it once then avoid
repeating it. cryptech_muxd will probe if requested, but probing is
never going to be reliable. Dedicated VID:PID would be much better.
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Internal probe code mostly works, probably about as well as
cryptech_probe ever did, but almost certainly needs timeouts around
its I/O calls, and perhaps additional error handling. At the moment,
it works except when it doesn't, just like cryptech_probe.
Some day we'll get away from this kludge, but not today.
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Renamed multiplexer to cryptech_muxd, since it now handles both RPC and CTY.
Added new program cryptech_console to act as client for CTY multiplexer.
Might want to add console logging capability eventually, not today.
Probably want to incorporate UART probing (what cryptech_probe does
now) eventually, also not today.
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This is a work in progress, so far it only works with libhal.py
client, haven't adapted libhal C client code for this yet.
General idea is to let PySerial and Tornado handle all the pesky work
of dealing with Unix serial ports, PF_LOCAL connection management,
select() vs epoll() vs kqueue() vs ... I/O management, etcetera.
We could do this with just PySerial and the Python standard libraries,
but using Tornado allows us to do it in a single process, without
threading, and also leaves the door open for consolidating other HSM
management functions (eg, console access) into the same single daemon
process.
For the moment we're using SLIP framing over a SOCK_STREAM connection,
which is a bit silly but avoids the problem of OSX not supporting
SOCK_SEQPACKET. In the long run we're going to want a real channel
security protocol here, so don't sweat this too much right now.
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Fixed handling of deletion actions: code was still using the
zero-length attribute convention instead of HAL_PKEY_ATTRIBUTE_NIL.
Track existing attributes more closely while copying data from old
chunks to new ones in the slow path: the old algorithm had a few
dangerous corner cases which could have resulted in the wrong values
being written to the new chunks.
Single-block-update fast path now under compile-time conditional; in
the long run, we probably want this enabled, but it's disabled for now
in order to force use and testing of the slow path.
This function probably needs to be broken up into a collection of
smaller inline functions for readability.
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PKCS #11 supports zero-length attributes (eg, CKA_LABEL) so hack of
using zero length attribute as NIL value won't work, instead we use a
slightly more portable version of the hack PKCS #11 uses (PKCS #11
stuffs -1 into a CK_ULONG, we stuff 0xFFFFFFFF into a uint32_t).
ks_attribute.c code was trying too hard and tripping over its own
socks. Instead of trying to maintain attributes[] in place during
modification, we now perform the minimum necessary change then re-scan
the block. This is (very slightly) slower but more robust, both
because the scan code has better error checking and because it's the
scan code that we want to be sure is happy before committing a change.
Rename hal_rpc_pkey_attribute_t to hal_pkey_attribute_t.
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