After change 5995, zone transfers were using a small
compression context that only had space for the first
few dozen names in each message. They now use a large
compression context with enough space for every name.
The dns_cache API contained a cache cleaning mechanism that would be
disabled for 'rbt' based cache. As named doesn't have any other cache
implementations, remove the cache cleaning mechanism from dns_cache API.
the 'nupdates' field was originally used to track whether a client
was ready to shut down, along with other similar counters nreads,
nrecvs, naccepts and nsends. this is now tracked differently, but
nupdates was overlooked when the other counters were removed.
Remove code that triggers key and denial of existence management
operations. Dynamic update should no longer be used to do DNSSEC
maintenance (other than that of course signatures need to be
created for the new zone contents).
The small/large tuning has been completely removed from the code with
last remnant of the dead code in ns_interfacemgr. Remove the dead code
and the configure option.
RPZ rewrites called dns_db_findext() without passing through the
client database options; as as result, if the client set CD=1,
DNS_DBFIND_PENDINGOK was not used as it should have been, and
cache lookups failed, resulting in failure of the rewrite.
Mostly generated automatically with the following semantic patch,
except where coccinelle was confused by #ifdef in lib/isc/net.c
@@ expression list args; @@
- UNEXPECTED_ERROR(__FILE__, __LINE__, args)
+ UNEXPECTED_ERROR(args)
@@ expression list args; @@
- FATAL_ERROR(__FILE__, __LINE__, args)
+ FATAL_ERROR(args)
All we need for compression is a very small hash set of compression
offsets, because most of the information we need (the previously added
names) can be found in the message using the compression offsets.
This change combines dns_compress_find() and dns_compress_add() into
one function dns_compress_name() that both finds any existing suffix,
and adds any new prefix to the table. The old split led to performance
problems caused by duplicate names in the compression context.
Compression contexts are now either small or large, which the caller
chooses depending on the expected size of the message. There is no
dynamic resizing.
There is a behaviour change: compression now acts on all the labels in
each name, instead of just the last few.
A small benchmark suggests this is about 2x faster.
sizeof(dns_name_t) did not change but the boolean attributes are now
separated as one-bit structure members. This allows debuggers to
pretty-print dns_name_t attributes without any special hacks, plus we
got rid of manual bit manipulation code.
Getting the recorded value of 'edns-udp-size' from the resolver requires
strong attach to the dns_view because we are accessing `view->resolver`.
This is not the case in places (f.e. dns_zone unit) where `.udpsize` is
accessed. By moving the .udpsize field from `struct dns_resolver` to
`struct dns_view`, we can access the value directly even with weakly
attached dns_view without the need to lock the view because `.udpsize`
can be accessed after the dns_view object has been shut down.
In several places, the structures were cleaned with memset(...)) and
thus the semantic patch converted the isc_mem_get(...) to
isc_mem_getx(..., ISC_MEM_ZERO). Use the designated initializer to
initialized the structures instead of zeroing the memory with
ISC_MEM_ZERO flag as this better matches the intended purpose.
Add new semantic patch to replace the straightfoward uses of:
ptr = isc_mem_{get,allocate}(..., size);
memset(ptr, 0, size);
with the new API call:
ptr = isc_mem_{get,allocate}x(..., size, ISC_MEM_ZERO);
The previous commit failed some tests because we expect that if a
fetch fails and we have stale candidates in cache, the
stale-refresh-time window is started. This means that if we hit a stale
entry in cache and answering stale data is allowed, we don't bother
resolving it again for as long we are within the stale-refresh-time
window.
This is useful for two reasons:
- If we failed to fetch the RRset that we are looking for, we are not
hammering the authoritative servers.
- Successor clients don't need to wait for stale-answer-client-timeout
to get their DNS response, only the first one to query will take
the latency penalty.
The latter is not useful when stale-answer-client-timeout is 0 though.
So this exception code only to make sure we don't try to refresh the
RRset again if it failed to do so recently.
Refreshing a stale RRset is similar to prefetching an RRset, so
reuse the existing code. When refreshing an RRset we need to clear
all db options related to serve-stale so that stale RRsets in cache
are ignored during the refresh.
We no longer need to set the "nodetach" flag, because the refresh
fetch is now a "fetch and forget". So we can detach from the client
in the query_send().
This code will break some serve-stale test cases, this will be fixed
in the successor commit.
TODO: add explanation why the serve-stale test cases fail.
Formerly, the isc_hash32() would have to change the key in a local copy
to make it case insensitive. Change the isc_siphash24() and
isc_halfsiphash24() functions to lowercase the input directly when
reading it from the memory and converting the uint8_t * array to
64-bit (respectively 32-bit numbers).
Don't attempt to resolve DNS responses for intermediate results. This
may create multiple refreshes and can cause a crash.
One scenario is where for the query there is a CNAME and canonical
answer in cache that are both stale. This will trigger a refresh of
the RRsets because we encountered stale data and we prioritized it over
the lookup. It will trigger a refresh of both RRsets. When we start
recursing, it will detect a recursion loop because the recursion
parameters will eventually be the same. In 'dns_resolver_destroyfetch'
the sanity check fails, one of the callers did not get its event back
before trying to destroy the fetch.
Move the call to 'query_refresh_rrset' to 'ns_query_done', so that it
is only called once per client request.
Another scenario is where for the query there is a stale CNAME in the
cache that points to a record that is also in cache but not stale. This
will trigger a refresh of the RRset (because we encountered stale data
and we prioritized it over the lookup).
We mark RRsets that we add to the message with
DNS_RDATASETATTR_STALE_ADDED to prevent adding a duplicate RRset when
a stale lookup and a normal lookup conflict with each other. However,
the other non-stale RRset when following a CNAME chain will be added to
the message without setting that attribute, because it is not stale.
This is a variant of the bug in #2594. The fix covered the same crash
but for stale-answer-client-timeout > 0.
Fix this by clearing all RRsets from the message before refreshing.
This requires the refresh to happen after the query is send back to
the client.
It is possible to bypass Response Rate Limiting (RRL)
`responses-per-second` limitation using specially crafted wildcard
names, because the current implementation, when encountering a found
DNS name generated from a wildcard record, just strips the leftmost
label of the name before making a key for the bucket.
While that technique helps with limiting random requests like
<random>.example.com (because all those requests will be accounted
as belonging to a bucket constructed from "example.com" name), it does
not help with random names like subdomain.<random>.example.com.
The best solution would have been to strip not just the leftmost
label, but as many labels as necessary until reaching the suffix part
of the wildcard record from which the found name is generated, however,
we do not have that information readily available in the context of RRL
processing code.
Fix the issue by interpreting all valid wildcard domain names as
the zone's origin name concatenated to the "*" name, so they all will
be put into the same bucket.
Previously:
* applications were using isc_app as the base unit for running the
application and signal handling.
* networking was handled in the netmgr layer, which would start a
number of threads, each with a uv_loop event loop.
* task/event handling was done in the isc_task unit, which used
netmgr event loops to run the isc_event calls.
In this refactoring:
* the network manager now uses isc_loop instead of maintaining its
own worker threads and event loops.
* the taskmgr that manages isc_task instances now also uses isc_loopmgr,
and every isc_task runs on a specific isc_loop bound to the specific
thread.
* applications have been updated as necessary to use the new API.
* new ISC_LOOP_TEST macros have been added to enable unit tests to
run isc_loop event loops. unit tests have been updated to use this
where needed.
* isc_timer was rewritten using the uv_timer, and isc_timermgr_t was
completely removed; isc_timer objects are now directly created on the
isc_loop event loops.
* the isc_timer API has been simplified. the "inactive" timer type has
been removed; timers are now stopped by calling isc_timer_stop()
instead of resetting to inactive.
* isc_manager now creates a loop manager rather than a timer manager.
* modules and applications using isc_timer have been updated to use the
new API.
When doing a dnssec-policy reconfiguration from a zone with NSEC only
keys to a zone that uses NSEC3, figure out to wait with building the
NSEC3 chain.
Previously, BIND 9 would attempt to sign such a zone, but failed to
do so because the NSEC3 chain conflicted with existing DNSKEY records
in the zone that were not compatible with NSEC3.
There exists logic for detecting such a case in the functions
dnskey_sane() (in lib/dns/zone.c) and check_dnssec() (in
lib/ns/update.c). Both functions look very similar so refactor them
to use the same code and call the new function (called
dns_zone_check_dnskey_nsec3()).
Also update the dns_nsec_nseconly() function to take an additional
parameter 'diff' that, if provided, will be checked whether an
offending NSEC only DNSKEY will be deleted from the zone. If so,
this key will not be considered when checking the zone for NSEC only
DNSKEYs. This is needed to allow a transition from an NSEC zone with
NSEC only DNSKEYs to an NSEC3 zone.
Clean up dns_rdatalist_tordataset() and dns_rdatalist_fromrdataset()
functions by making them return void, because they cannot fail.
Clean up other functions that subsequently cannot fail.
When checking if we should enable serve-stale, add an early out case
when the result is an error signalling a duplicate query or a query
that would be dropped.
The BUFSIZ value varies between platforms, it could be 8K on Linux and
512 bytes on mingw. Make sure the buffers are always big enough for the
output data to prevent truncation of the output by appropriately
enlarging or sizing the buffers.
messages indicating the reason for a fallback to AXFR (i.e, because
the requested serial number is not present in the journal, or because
the size of the IXFR response would exceeed "max-ixfr-ratio") are now
logged at level info instead of debug(4).
Call dns_view_sfd_find to find the namespace to be used to verify
the covering NSEC records returned for the given QNAME. Check that
the NSEC owner names are within that namespace.
The "glue-cache" option was marked as deprecated by commit
5ae33351f2 (first released in BIND 9.17.6,
back in October 2020), so now obsolete that option, removing all code
and documentation related to it.
Note: this causes the glue cache feature to be permanently enabled, not
disabled.
This commit ensures that on reconfiguration a proper value for HTTP
connections limit is picked up.
The commit also refactors how listeners settings are updated so that
there is less code duplication.
This way only quota size is passed to the interface/listener
management code instead of a quota object. Thus, we can implement
updating the quota object size instead of recreating the object.
The current logic for determining the address of the socket to which a
client sent its query is:
1. Get the address:port tuple from the netmgr handle using
isc_nmhandle_localaddr().
2. Convert the address:port tuple from step 1 into an isc_netaddr_t
using isc_netaddr_fromsockaddr().
3. Convert the address from step 2 back into a socket address with the
port set to 0 using isc_sockaddr_fromnetaddr().
Note that the port number (readily available in the netmgr handle) is
needlessly lost in the process, preventing it from being recorded in
dnstap captures of client traffic produced by named.
Fix by first storing the address:port tuple returned by
isc_nmhandle_localaddr() in client->destsockaddr and then creating an
isc_netaddr_t from that structure. This allows the port number to be
retained in client->destsockaddr, which is what subsequently gets passed
to dns_dt_send().
When shutting down, the interface manager can be destroyed
before the `route_connected()` callback is called, which is
unexpected for the latter and can cause a crash.
Move the interface manager attachment code from the callback
to the place before the callback is registered using
`isc_nm_routeconnect()` function, which will make sure that
the interface manager will live at least until the callback
is called.
Make sure to detach the interface manager if the
`isc_nm_routeconnect()` function is not implemented, or when
the callback is called with a result value which differs from
`ISC_R_SUCCESS`.
The `ns_interfacemgr_create()` function, when calling
`isc_nm_routeconnect()`, uses the newly created `ns_interfacemgr_t`
instance before initializing its reference count and the magic value.
Defer the `isc_nm_routeconnect()` call until the initializations
are complete.
