The msCertificateTypeExtension OID (1.3.6.1.4.1.311.20.2) can
be used in a PKCS#10 certificate request to define a certificate
profile. It consists of an UTF8 string.
pki: profile option
The "ipsec scepclient" tool has been removed and replaced by the
pki subcommands "pki --scep" and "pki --scepca" which implement the
new SCEP RFC 8894 standard that was released in September 2020 and
which supports trusted "certificate renewal" based on the existing
client certificate.
Rename `encrypt` methods to avoid the following build failure when wolfSSL
is built with --enable-opensslextra:
In file included from ../../../../src/libstrongswan/utils/utils.h:59,
from ../../../../src/libstrongswan/library.h:101,
from wolfssl_common.h:29,
from wolfssl_aead.c:23:
wolfssl_aead.c:90:16: error: conflicting types for 'encrypt'; have '_Bool(union <anonymous>, chunk_t, chunk_t, chunk_t, chunk_t *)'
90 | METHOD(aead_t, encrypt, bool,
| ^~~~~~~
../../../../src/libstrongswan/utils/utils/object.h:99:20: note: in definition of macro 'METHOD'
99 | static ret name(union {iface *_public; this;} \
| ^~~~
In file included from /home/autobuild/autobuild/instance-5/output-1/host/powerpc64le-buildroot-linux-musl/sysroot/usr/include/wolfssl/wolfcrypt/wc_port.h:573,
from /home/autobuild/autobuild/instance-5/output-1/host/powerpc64le-buildroot-linux-musl/sysroot/usr/include/wolfssl/wolfcrypt/types.h:35,
from /home/autobuild/autobuild/instance-5/output-1/host/powerpc64le-buildroot-linux-musl/sysroot/usr/include/wolfssl/wolfcrypt/logging.h:33,
from /home/autobuild/autobuild/instance-5/output-1/host/powerpc64le-buildroot-linux-musl/sysroot/usr/include/wolfssl/ssl.h:35,
from wolfssl_common.h:64,
from wolfssl_aead.c:23:
/home/autobuild/autobuild/instance-5/output-1/host/powerpc64le-buildroot-linux-musl/sysroot/usr/include/unistd.h:149:6: note: previous declaration of 'encrypt' with type 'void(char *, int)'
149 | void encrypt(char *, int);
| ^~~~~~~
Closesstrongswan/strongswan#1201
Since the allocated data was smaller than sizeof(eap_mschapv2_header_t),
the following compile error was triggered (with newer GCC versions):
eap_mschapv2.c: In function 'process_peer_success':
eap_mschapv2.c:945:12: error: array subscript 'eap_mschapv2_header_t[0]' is partly outside array bounds of 'unsigned char[6]' [-Werror=array-bounds]
945 | eap->code = EAP_RESPONSE;
| ^~
In file included from /usr/include/stdlib.h:587,
from ../../../../src/libstrongswan/utils/printf_hook/printf_hook.h:26,
from ../../../../src/libstrongswan/library.h:101,
from ../../../../src/libcharon/sa/eap/eap_method.h:28,
from eap_mschapv2.h:27,
from eap_mschapv2.c:18:
eap_mschapv2.c:944:15: note: object of size 6 allocated by '__builtin_alloca'
944 | eap = alloca(len);
| ^~~~~~
Closesstrongswan/strongswan#1188Closesstrongswan/strongswan#1215
The content field of type OCTET STRING of a ContentInfo object
with ContentType Data
ContentInfo ::= SEQUENCE {
contentType ContentType,
content
[0] EXPLICIT OCTET STRING OPTIONAL
is optional and can be missing if no data is available
The previous code did not ensure that there was a delay of at least
`try` seconds after each sent request. Instead, whenever the condvar was
signaled, which could be due to retransmitted responses or messages for
unrelated transactions (there could even be spurious wakeups), the counter
was increased and a retransmit sent. So instead of actually waiting for
15 seconds for a response (and sending 4 retransmits over that timespan),
it could happen that all five messages were sent within a second without
enough time to actually receive a response.
Using an absolute timeout that we reuse as long as there was no timeout
and the condvar was signaled for something unrelated, should ensure we
wait at least the intended delay after each sent message.
Closesstrongswan/strongswan#1154
This allows using the upper parts of the marks for other purposes. For
instance, with `mark_in=mark_out=%unique/0x0000ffff` mark values in the
upper two bytes would not get reset by the rules installed by this plugin.
However, note that in this example the daemon would have to get restarted
after 65'535 CHILD_SAs to reset the counter for unique marks, which is a
global 32-bit counter that's unaware of any masks.
Closesstrongswan/strongswan#1087
get_traffic_selectors() is called the same way also as responder when
selecting child configs via peer_cfg_t::select_child_cfg(). Replacing
TS for all child configs could lead to selecting one that later fails
to actually narrow the traffic selectors. Ignoring non-matching TS also
helps if we have a trap config with multiple remote subnets (otherwise,
we'd have to filter duplicates afterwards).
When installing traps, the hosts might be %any, in which case we allow
the configured (technically non-matching) TS for the wildcard use case.
Fixes: da82786b2d8c ("child-cfg: Always apply hosts to traffic selectors if proposing transport mode")
Closesstrongswan/strongswan#1143
Setting -Werror in CFLAGS passed to configure is not ideal as that affects
all the checks performed by the script.
This caused an issue with newer versions of Autoconf and the AC_PROG_LEX
macro that insisted on finding a lexer library. But due to warnings from
the generated test lexer (misleading indentation) that got turned into
errors no library was found (none would have been necessary), so LEX was
not set and no lexers were built.
With this option enabled, we add -Werror to CFLAGS after all tests ran.
It also enables additional warnings via -Wextra.
The option is auto-enabled when building from the repository.
Making the variable volatile avoids a "variable ‘failure’ might be
clobbered by ‘longjmp’" warning (or error when compiling with
-Werror) that's triggered via -Wextra.
The 5.4.0 update changed the default bignum implementation to what
could explicitly be enabled via `--enable-sp-math-all`. Since this uses
fixed-sized buffers sufficient for key sizes of SP_INT_BITS, with a default
of 4096, modp6144 and modp8192 didn't work anymore (wc_DhGenerateKeyPair()
returned MP_EXPTMOD_E). So we have to adapt the feature checks for this.
To support the larger DH groups we can either increase the buffer size
via `--with-max-rsa-bits` or add `--enable-heapmath` so buffers get
(re-)allocated as needed. We go with the latter for now.
This collection of Internet standards and drafts hadn't been
updated for a long time and the documents are readily available
on the Internet anyway. The strongSwan documentation page
https://docs.strongswan.org/docs/5.9/features/ietf.html
specifies which standards are currently supported.
This merge includes changes that were created for the upcoming IKEv2
extension for multiple key exchanges over the last four years, but which
are not directly related to the actual protocol changes.
Changes include renaming diffie_hellman_t to the more generic
key_exchange_t (also renamed are some of the interface's methods),
making utility functions that deal with DH groups more generic, and let
tasks handle the first IKE_AUTH message more reliably by not depending
on e.g. specific message IDs.
One significant change is delaying the IKEv2 key derivation until
the keys are actually needed to process or send the next message. So
instead of deriving the keys directly while processing an IKE_SA_INIT
request (which could come from a spoofed address), this is delayed until
the corresponding IKE_AUTH request is received. Implementations of the
key_exchange_t interface are now expected to do the key derivation and
any costly public key validation in get_shared_secret() and not
set_public_key().
Sent IKE_SA_INIT messages are now also not pre-generated anymore to collect
their encoding for the authentication. Instead, a new post_build() hook
allows the ike-auth task to do so after the actual message has been built,
which allows later tasks and plugins (via message() hook) to modify the
message (e.g. add notifies) after the ike-auth task's build() method
already ran.
Also changed is how inbound requests are processed and retransmits are
detected. Instead of parsing all inbound messages right away (which
might trigger a key derivation or require keys we don't have anymore in
the multi-KE use case), we now first check a request's message ID and
compare its hash to that of the previous request to decide if it's a
valid retransmit. For fragmented messages, we only keep track of the
first fragment so we can send the corresponding response immediately if
a retransmit of it is received, instead of waiting for all fragments
and reconstructing the message, which we did before.
This way we avoid having to pre-generate the message when it could
theoretically still get modified by a task that follows or from a plugin
via message() hook.
