On 01/04/2016 12:44, Varga Viktor wrote:
Hi,
My replies are inline marked with ***
regards, Viktor Varga / Netlock
-----Original Message-----
From: dev-security-policy
[mailto:dev-security-policy-bounces+varga.viktor=netlock...@lists.mozilla.org]
On Behalf Of Jeremy Rowley
Sent: Wednesday, March 30, 2016 10:54 PM
To: Jakob Bohm <[email protected]>;
[email protected]
Subject: RE: SHA-1 S/MIME certificates
I think a required move away from SHA1 client certs requires a bit more
planning.
1) There hasn't been a formal deprecation of all SHA-1 certificates in any root
store policy. There has been a formal deprecation by the CAB Forum of SHA1
server certificates. Considering many of the client cert issuance is governed
by various national schemes (FBCA in the US and the Qualified Cert program in
the EU), care is necessary in enacting policies that impact the use of client
certificates. Although I recognize the need for Mozilla to ensure a safe onine
experience for all its users, I'm sure they don't want to undermine entire
trust frameworks built on these certificates. (Yes, I know FBCA requires SHA2
now).
*** Dont forget, that the roots doesn't needs to be deprecated because their
signing algorithm.
*** The roots are not trusted because their algorithms, they are trusted
because CAs are enrolled in root programs, and the root certificates are
physically in your browser.
*** So for the roots, the algorithm on itself doesnot counts on deprecation,
but the key length should large enough.
*** Also dont forget, that the Microsoft is also removing the old roots, and
the Apple does the same, but they are asking CAs about the remove, not
publishing anyone.
Microsoft has deprecated SHA-1 in the root store policy for roots with
the "code signing" trust bit, but only for the root stores on Windows 7
or later, and with special exceptions for roots that are in both Vista
and Windows 7 stores. In fact Microsoft has phrased their entire SHA-1
deprecation policy as a change in their root store policy, even the
parts that describe changes in the acceptance of end certificates on a
context specific basis.
2) The browsers are already deploying code to reject SHA1 certificates
encountered. If this is true, what is the harm in continued SHA1 client
certificate issuance until the national schemes have all updated their
requirements? Mozilla is protected but the national bodies (and financial
institutions) can continue using their software for client authentication. I do
think we should move to SHA2, but I don't think the prior notice has occurred
with respect to SHA1 client certs.
*** In Hungary, we had legislation to use sha256 only, so we completely moved
to sha256.
*** I think ist much bigger problem for the usage of certs is the same origin
policy.
*** The remove of NPAPI, Java support and the windows.crypto gives the real
problem for web applications here in Hungary, especcially for the governmental
applications, because the are using one of the technologies i mentioned, and
the need to move on quickly.
Fortunately, there are Mozilla forks which maintain at least NPAPI.
On 30/03/2016 18:49, Kathleen Wilson wrote:
All,
In response to the 'March 2016 CA Communication' I received the
following question from a CA. I think we should discuss it here,
because I suspect there will be other CAs in this same situation.
> We have a problem since we still issue SHA-1 S/MIME >
certificates. Do we really have to stop issue after 2017?
I will appreciate your thoughtful and constructive input into setting
reasonable expectations for CAs in regards to SHA-1 S/MIME certificates.
Thanks,
Kathleen
I would suggest the following minimum requirements:
1. Any 3rd party certificates using outdated certificate signing
algorithms (such as certificates signed using SHA-1) must be issued
under dedicated subCAs with as many technical constraints in the
subCA's certificate validity as possible, such as restrictions in key
usage, extended key usage, subCA validity period and distinguished
name ("path name restrictions"). Mozilla will allow the issuing and
reissuing of a reasonably low number of such SubCAs, provided they
chain only through and to certificates that use the same or older
outdated signing algorithm. (For example SHA-1 certificates should
be issued by a technically restricted SHA-1 SubCA that chains to an
old SHA-1 (or older) root cert).
*** just one suggestion: define a minimum key length also.
Indeed, hence why I keep saying "outdated certificate signing
algorithms" with SHA-1 as just a current example.
2. Any 3rd party certificates using outdated certificate signing
algorithms (such as certificates signed using SHA-1) must include CA
generated random values that are not known by the 3rd party prior to
issuance (and thus prior to request generation). Any such random
values must contain the same number of bits as the signing hash (e.g.
20 bytes/160 bits for SHA-1 signed certificates). Any such random
values must occur before most (preferably all) 3rd party supplied
fields to protect against prefix collision based attacks. In
practice, placing the first 160 random bits in the certificate serial
number, adding the next 12 random bits to the "NotBefore time" as a
count of seconds, the next 12 random bits to the "NotAfter time" as a
count of seconds and inserting any remaining bits as an early element
in the subject distinguished name would be the closest allowed by
X.509v3 and older.
3. Document, for each such external usage the exact technical reason
why subscribers are presumed unable to use certificates using modern
algorithms. For example: "These certificates are for US medical
persons needing access to the US FDA server at foo.bar.gov, which
does not accept better algorithms" . Or "These certificates are
exclusively for users communicating with users of the Microsoft
Office 2007 Outlook MUA, which does not support better algorithms"
4. Any CA internal certificates using outdated certificate signing
algorithms (such as certificates signed using SHA-1) must be issued
in a very minimal count and with short validity periods (1 to 16
months), even though this would imply more frequent reissuing. Any
such internal CA certificates must serve a specific purpose in
servicing existing or acceptable certificates using such algorithms,
such as OCSP signing, online timestamping or the restricted subCAs
specified by rule 1 above). Additional administrative procedures
must be used to prevent the internal requests for such certificates
from being generated with malicious content, for example they might
be generated only by specially trusted hardware with private keys
securely transported to the point of usage after issuance.
5. Any other CA usage of outdated signing algorithms in signatures
traceable to Mozilla trusted roots must be done in the minimal count
possible and only to serve a specific purpose in servicing existing
or acceptable certificates using such algorithms, such as CRL signing
or OCSP signing where a documented technical reason must be given for
not making such signatures using dedicated certificates (for example,
a specific named client implementation might fail to accept OCSP
responses and/or CRL signatures not signed directly by the CA).
As an example of reducing the frequency of such signatures, CRLs
might be issued with longer than usual refresh intervals for older
CAs that have few remaining valid certificates and are mostly
reissuing CRLs to provide trusted lists of historic revocation dates.
6. Any other CA usage of outdated signing algorithms in signatures
traceable to Mozilla trusted roots must include CA generated random
values that are not known by the 3rd party prior to issuance (and
thus prior to request generation). Any such random values must
contain the same number of bits as the signing hash (e.g. 20
bytes/160 bits for SHA-1 signed certificates). Any such random
values must occur before most (preferably all) 3rd party supplied
data elements to protect against prefix collision based attacks. For
example CRLs could include revocation of one or more never-issued
certificates with random serial numbers at both ends of the CRL.
Similarly, OCSP responses for actually issued certificates should be
pre-generated independent of incoming OCSP requests and include the
random values as close to the beginning of the response as
technically possible. Dynamically generated OCSP responses (for
multiple certicates, never-issued certificates etc.) should include a
random value before any request-supplied values totaling more than
half the number of bits in the signing hash.
7. Mozilla would prefer if issuers of such certificates with outdated
signing algorithms stand up a new root certificate, which is
self-signed with a modern signing algorithm and will not be used to
sign (directly or indirectly) certificates with lesser algorithms.
The CA should also publish a date after which the old root cert used
for issuing certificates with lesser signing algorithms will no
longer be the root of still-valid certificates with modern signing
algorithms. Mozilla will remove most trust bits from the old root
certificate on or before that date, but will include (in its master
list, but not necessarily in its software releases) an indication of
the extent to which the old root certificate is valid for
(re)checking old data provably from before the cut-off date, such as
externally time stamped documents and/or recipient time-stamped
e-mails.
8. When standing up such a replacement root CA, Mozilla will understand
that the switch to using the new root CA for issuing certificates
with modern signing algorithms will be delayed by the time it takes
to deploy the new root in all relevant software releases and updates,
not just those of Mozilla. For example use of a new root CA for
signing S/MIME e-mail certificates would await its inclusion in both
Mozilla Thunderbird, the vast majority of 3rd party e-mail clients
and the OS level root CA list of most operating systems releases,
such as Microsoft Windows and the various Linux distributions.
9. All procedures performed to comply with the above rules must be
documented in the relevant CPS and verified by the annual audit.
Enjoy
Jakob
--
Jakob Bohm, CIO, Partner, WiseMo A/S. https://www.wisemo.com
Transformervej 29, 2860 Søborg, Denmark. Direct +45 31 13 16 10
This public discussion message is non-binding and may contain errors.
WiseMo - Remote Service Management for PCs, Phones and Embedded
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