uint16_t instead of u_int16_t
None ISO fields of struct tm are not present, but
by zeroyfing it, on GNU and BSD systems tm_gmtoff
field will be set.
[wt: moved the memset into each of the date functions]
Recent commit 93b227d ("MINOR: listener: add the "accept-netscaler-cip"
option to the "bind" keyword") introduced an include of netinet/ip.h
which requires in_systm.h on OpenBSD. No backport is needed.
Originally, tcphdr's source and dest from Linux were used to get the
source and port which led to a build issue on BSD oses.
To avoid side problems related to network then we just use an internal
struct as we need only those two fields.
When NetScaler application switch is used as L3+ switch, informations
regarding the original IP and TCP headers are lost as a new TCP
connection is created between the NetScaler and the backend server.
NetScaler provides a feature to insert in the TCP data the original data
that can then be consumed by the backend server.
Specifications and documentations from NetScaler:
https://support.citrix.com/article/CTX205670https://www.citrix.com/blogs/2016/04/25/how-to-enable-client-ip-in-tcpip-option-of-netscaler/
When CIP is enabled on the NetScaler, then a TCP packet is inserted just after
the TCP handshake. This is composed as:
- CIP magic number : 4 bytes
Both sender and receiver have to agree on a magic number so that
they both handle the incoming data as a NetScaler Client IP insertion
packet.
- Header length : 4 bytes
Defines the length on the remaining data.
- IP header : >= 20 bytes if IPv4, 40 bytes if IPv6
Contains the header of the last IP packet sent by the client during TCP
handshake.
- TCP header : >= 20 bytes
Contains the header of the last TCP packet sent by the client during TCP
handshake.
This was the first transparent proxy technology supported by haproxy
circa 2005 but it was obsoleted in 2007 by Tproxy 4.0 which removed a
lot of the earlier versions' shortcomings and was finally merged into
the kernel. Since nobody has been using cttproxy for many years now
and nobody has even just tried to compile the files, it's time to
remove it. The doc was updated as well.
This flag is set on an outgoing connection when this connection gets
some properties that must not be shared with other connections, such
as dynamic transparent source binding, SNI or a proxy protocol header,
or an authentication challenge from the server. This will be needed
later to implement connection reuse.
This list member will be used to attach a connection to a list of
idle, reusable or queued connections. It's unused for now. Given
that it's not expected to be used more than a few times per session,
the member was put after the target, in the area starting at the
second cache line of the structure.
This patch makes it possible to create binds and servers in separate
namespaces. This can be used to proxy between multiple completely independent
virtual networks (with possibly overlapping IP addresses) and a
non-namespace-aware proxy implementation that supports the proxy protocol (v2).
The setup is something like this:
net1 on VLAN 1 (namespace 1) -\
net2 on VLAN 2 (namespace 2) -- haproxy ==== proxy (namespace 0)
net3 on VLAN 3 (namespace 3) -/
The proxy is configured to make server connections through haproxy and sending
the expected source/target addresses to haproxy using the proxy protocol.
The network namespace setup on the haproxy node is something like this:
= 8< =
$ cat setup.sh
ip netns add 1
ip link add link eth1 type vlan id 1
ip link set eth1.1 netns 1
ip netns exec 1 ip addr add 192.168.91.2/24 dev eth1.1
ip netns exec 1 ip link set eth1.$id up
...
= 8< =
= 8< =
$ cat haproxy.cfg
frontend clients
bind 127.0.0.1:50022 namespace 1 transparent
default_backend scb
backend server
mode tcp
server server1 192.168.122.4:2222 namespace 2 send-proxy-v2
= 8< =
A bind line creates the listener in the specified namespace, and connections
originating from that listener also have their network namespace set to
that of the listener.
A server line either forces the connection to be made in a specified
namespace or may use the namespace from the client-side connection if that
was set.
For more documentation please read the documentation included in the patch
itself.
Signed-off-by: KOVACS Tamas <ktamas@balabit.com>
Signed-off-by: Sarkozi Laszlo <laszlo.sarkozi@balabit.com>
Signed-off-by: KOVACS Krisztian <hidden@balabit.com>
There are two sample commands to get information about the presence of a
client certificate.
ssl_fc_has_crt is true if there is a certificate present in the current
connection
ssl_c_used is true if there is a certificate present in the session.
If a session has stopped and resumed, then ssl_c_used could be true, while
ssl_fc_has_crt is false.
In the client byte of the TLS TLV of Proxy Protocol V2, there is only one
bit to indicate whether a certificate is present on the connection. The
attached patch adds a second bit to indicate the presence for the session.
This maintains backward compatibility.
[wt: this should be backported to 1.5 to help maintain compatibility
between versions]
This is in order to simplify the PPv2 header parsing code to look more
like the one provided as an example in the spec. No code change was
performed beyond just merging the proxy_addr union into the proxy_hdr_v2
struct.
This commit modifies the PROXY protocol V2 specification to support headers
longer than 255 bytes allowing for optional extensions. It implements the
PROXY protocol V2 which is a binary representation of V1. This will make
parsing more efficient for clients who will know in advance exactly how
many bytes to read. Also, it defines and implements some optional PROXY
protocol V2 extensions to send information about downstream SSL/TLS
connections. Support for PROXY protocol V1 remains unchanged.
Using the previous callback, it's trivial to block the heartbeat attack,
first we control the message length, then we emit an SSL error if it is
out of bounds. A special log is emitted, indicating that a heartbleed
attack was stopped so that they are not confused with other failures.
That way, haproxy can protect itself even when running on an unpatched
SSL stack. Tests performed with openssl-1.0.1c indicate a total success.
Users have seen a huge increase in the rate of SSL handshake failures
starting from 2014/04/08 with the release of the Heartbleed OpenSSL
vulnerability (CVE-2014-0160). Haproxy can detect that a heartbeat
was received in the incoming handshake, and such heartbeats are not
supposed to be common, so let's log a different message when a
handshake error happens after a heartbeat is detected.
This patch only adds the new message and the new code.
By having the stream interface pass the CF_STREAMER flag to the
snd_buf() primitive, we're able to tell the send layer whether
we're sending large chunks or small ones.
We use this information in SSL to adjust the max record dynamically.
This results in small chunks respecting tune.ssl.maxrecord at the
beginning of a transfer or for small transfers, with an automatic
switch to full records if the exchanges last long. This allows the
receiver to parse HTML contents on the fly without having to retrieve
16kB of data, which is even more important with small initcwnd since
the receiver does not need to wait for round trips to start fetching
new objects. However, sending large files still produces large chunks.
For example, with tune.ssl.maxrecord = 2859, we see 5 write(2885)
sent in two segments each and 6 write(16421).
This idea was first proposed on the haproxy mailing list by Ilya Grigorik.
This prevents us from passing other useful info and requires the
upper levels to know these flags. Let's use a new flags category
instead : CO_SFL_*. For now, only MSG_MORE has been remapped.
These flags were used to report the readiness of the file descriptor.
Now this readiness is directly checked at the file descriptor itself.
This removes the need for constantly synchronizing updates between the
file descriptor and the connection and ensures that all layers share
the same level of information.
For now, the readiness is updated in conn_{sock,data}_poll_* by directly
touching the file descriptor. This must move to the lower layers instead
so that these functions can disappear as well. In this state, the change
works but is incomplete. It's sensible enough to avoid making it more
complex.
Now the sock/data updates become much simpler because they just have to
enable/disable access to a file descriptor and not to care anymore about
its readiness.
It is quite often that an connection error only reports "socket error" with
no more information. This is especially problematic with health checks where
many causes are possible, including resource exhaustion which do not lead to
a valid errno code. So let's add explicit codes to cover these cases.
By moving the error code to 8 bits the send_proxy_ofs to 16 bits, and
moving them just after the obj_type, we can save 8 bytes in the struct
connection, down from 328 to 320.
We used to have two very similar functions for sending a PROXY protocol
line header. The reason is that the default one relies on the stream
interface to retrieve the other end's address, while the "local" one
performs a local address lookup and sends that instead (used by health
checks).
Now that the send_proxy_ofs is stored in the connection and not the
stream interface, we can make the local_send_proxy rely on it and
support partial sends. This also simplifies the code by removing the
local_send_proxy function, making health checks use send_proxy_ofs,
resulting in the removal of the CO_FL_LOCAL_SPROXY flag, and the
associated test in the connection handler. The other flag,
CO_FL_SI_SEND_PROXY was renamed without the "SI" part so that it
is clear that it is not dedicated anymore to a usage with a stream
interface.
Till now the send_proxy_ofs field remained in the stream interface,
but since the dynamic allocation of the connection, it makes a lot
of sense to move that into the connection instead of the stream
interface, since it will not be statically allocated for each
session.
Also, it turns out that moving it to the connection fils an alignment
hole on 64 bit architectures so it does not consume more memory, and
removing it from the stream interface was an opportunity to correctly
reorder fields and reduce the stream interface's size from 160 to 144
bytes (-10%). This is 32 bytes saved per session.
Currently the control and transport layers of a connection are supposed
to be initialized when their respective pointers are not NULL. This will
not work anymore when we plan to reuse connections, because there is an
asymmetry between the accept() side and the connect() side :
- on accept() side, the fd is set first, then the ctrl layer then the
transport layer ; upon error, they must be undone in the reverse order,
then the FD must be closed. The FD must not be deleted if the control
layer was not yet initialized ;
- on the connect() side, the fd is set last and there is no reliable way
to know if it has been initialized or not. In practice it's initialized
to -1 first but this is hackish and supposes that local FDs only will
be used forever. Also, there are even less solutions for keeping trace
of the transport layer's state.
Also it is possible to support delayed close() when something (eg: logs)
tracks some information requiring the transport and/or control layers,
making it even more difficult to clean them.
So the proposed solution is to add two flags to the connection :
- CO_FL_CTRL_READY is set when the control layer is initialized (fd_insert)
and cleared after it's released (fd_delete).
- CO_FL_XPRT_READY is set when the control layer is initialized (xprt->init)
and cleared after it's released (xprt->close).
The functions have been adapted to rely on this and not on the pointers
anymore. conn_xprt_close() was unused and dangerous : it did not close
the control layer (eg: the socket itself) but still marks the transport
layer as closed, preventing any future call to conn_full_close() from
finishing the job.
The problem comes from conn_full_close() in fact. It needs to close the
xprt and ctrl layers independantly. After that we're still having an issue :
we don't know based on ->ctrl alone whether the fd was registered or not.
For this we use the two new flags CO_FL_XPRT_READY and CO_FL_CTRL_READY. We
now rely on this and not on conn->xprt nor conn->ctrl anymore to decide what
remains to be done on the connection.
In order not to miss some flag assignments, we introduce conn_ctrl_init()
to initialize the control layer, register the fd using fd_insert() and set
the flag, and conn_ctrl_close() which unregisters the fd and removes the
flag, but only if the transport layer was closed.
Similarly, at the transport layer, conn_xprt_init() calls ->init and sets
the flag, while conn_xprt_close() checks the flag, calls ->close and clears
the flag, regardless xprt_ctx or xprt_st. This also ensures that the ->init
and the ->close functions are called only once each and in the correct order.
Note that conn_xprt_close() does nothing if the transport layer is still
tracked.
conn_full_close() now simply calls conn_xprt_close() then conn_full_close()
in turn, which do nothing if CO_FL_XPRT_TRACKED is set.
In order to handle the error path, we also provide conn_force_close() which
ignores CO_FL_XPRT_TRACKED and closes the transport and the control layers
in turns. All relevant instances of fd_delete() have been replaced with
conn_force_close(). Now we always know what state the connection is in and
we can expect to split its initialization.
This patch does not change the logic of the code, it only changes the
way OS-specific defines are tested.
At the moment the transparent proxy code heavily depends on Linux-specific
defines. This first patch introduces a new define "CONFIG_HAP_TRANSPARENT"
which is set every time the defines used by transparent proxy are present.
This also means that with an up-to-date libc, it should not be necessary
anymore to force CONFIG_HAP_LINUX_TPROXY during the build, as the flags
will automatically be detected.
The CTTPROXY flags still remain separate because this older API doesn't
work the same way.
A new line has been added in the version output for haproxy -vv to indicate
what transparent proxy support is available.
Both servers and proxies share a common set of parameters for outgoing
connections, and since they're not stored in a similar structure, a lot
of code is duplicated in the connection setup, which is one sensible
area.
Let's first define a common struct for these settings and make use of it.
Next patches will de-duplicate code.
This change also fixes a build breakage that happens when USE_LINUX_TPROXY
is not set but USE_CTTPROXY is set, which seem to be very unlikely
considering that the issue was introduced almost 2 years ago an never
reported.
When the PROXY protocol header is expected and fails, leading to an
abort of the incoming connection, we now emit a log message. If option
dontlognull is set and it was just a port probe, then nothing is logged.
Since the introduction of SSL, it became quite annoying not to get any useful
info in logs about handshake failures. Let's improve reporting for embryonic
sessions by checking a per-connection error code and reporting it into the logs
if an error happens before the session is completely instanciated.
The "dontlognull" option is supported in that if a connection does not talk
before being aborted, nothing will be emitted.
At the moment, only timeouts are considered for SSL and the PROXY protocol,
but next patches will handle more errors.
Instead of storing a couple of (int, ptr) in the struct connection
and the struct session, we use a different method : we only store a
pointer to an integer which is stored inside the target object and
which contains a unique type identifier. That way, the pointer allows
us to retrieve the object type (by dereferencing it) and the object's
address (by computing the displacement in the target structure). The
NULL pointer always corresponds to OBJ_TYPE_NONE.
This reduces the size of the connection and session structs. It also
simplifies target assignment and compare.
In order to improve the generated code, we try to put the obj_type
element at the beginning of all the structs (listener, server, proxy,
si_applet), so that the original and target pointers are always equal.
A lot of code was touched by massive replaces, but the changes are not
that important.
Before connections were introduced, it was possible to connect an
external task to a stream interface. However it was left as an
exercise for the brave implementer to find how that ought to be
done.
The feature was broken since the introduction of connections and
was never fixed since due to lack of users. Better remove this dead
code now.
This is the first step of a series of changes aiming at making the
polling totally event-driven. This first change consists in only
remembering at the connection level whether an FD was enabled or not,
regardless of the fact it was being polled or cached. From now on, an
EAGAIN will always be considered as a change so that the pollers are
able to manage a cache and to flush it based on such events. One of
the noticeable effect is that conn_fd_handler() is called once more
per session (6 instead of 5 min) but other update functions are less
called.
Note that the performance loss caused by this change at the moment is
quite significant, around 2.5%, but the change is needed to have SSL
working correctly in all situations, even when data were read from the
socket and stored in the invisible cache, waiting for some room in the
channel's buffer.
The struct target contains one int and one pointer, causing it to be
64-bit aligned on 64-bit platforms. By marking it "packed", we can
save 8 bytes in struct connection and as many in struct session on
such platforms.
When we start logging SSL information, we need the SSL struct to be
present even past the conn_xprt_close() call. In order to achieve this,
we should use refcounting on the connection and the transport layer. At
the moment it's not worth using plain refcounting as only the logs require
this, so instead of real refcounting we just use a flag which will be set
by the log subsystem when SSL data need to be logged.
What happens then is that the xprt->close() call is ignored and the
transport layer is closed again during session_free(), after the log
line is emitted.
This callback sends a PROXY protocol line on the outgoing connection,
with the local and remote endpoint information. This is used for local
connections (eg: health checks) where the other end needs to have a
valid address and no connection is relayed.
Just like ->init(), ->wake() may now be used to return an error and
abort the connection. Currently this is not used but will be with
embryonic sessions.
We now check the connection flags for changes in order not to call the
data->wake callback when there is no activity. Activity means a change
on any of the CO_FL_*_SH, CO_FL_ERROR, CO_FL_CONNECTED, CO_FL_WAIT_CONN*
flags, as well as a call to data->recv or data->send.
The connection flags have progressively been added one after the other
and were not very well organized. Some of them are often used together
and a number of operations are performed on the DATA/SOCK ENA/POL flags.
Thus, they have been reorganized so that flags that work together are
close to each other (allows immediate operands on ARM) and that polling
changes can be detected with fewer operations using a simple shift and
xor. The handshakes are now the last ones so that it will be easier to
add new ones after without risking a collision. All activity-related
flags are also grouped together.
The generic data-layer init callback is now used after the transport
layer is complete and before calling the data layer recv/send callbacks.
This allows the session to switch from the embryonic session data layer
to the complete stream interface data layer, by making conn_session_complete()
the data layer's init callback.
It sill looks awkwards that the init() callback must be used opon error,
but except by adding yet another one, it does not seem to be mergeable
into another function (eg: it should probably not be merged with ->wake
to avoid unneeded calls during the handshake, though semantically that
would make sense).
Instead of calling conn_notify_si() from the connection handler, we
now call data->wake(), which will allow us to use a different callback
with health checks.
Note that we still rely on a flag in order to decide whether or not
to call this function. The reason is that with embryonic sessions,
the callback is already initialized to si_conn_cb without the flag,
and we can't call the SI notify function in the leave path before
the stream interface is initialized.
This issue should be addressed by involving a different data_cb for
embryonic sessions and for stream interfaces, that would be changed
during session_complete() for the final data_cb.
Now conn->data will designate the data layer which is the client for
the transport layer. In practice it's the stream interface and will
soon also be the health checks.
While working on the changes required to make the health checks use the
new connections, it started to become obvious that some naming was not
logical at all in the connections. Specifically, it is not logical to
call the "data layer" the layer which is in charge for all the handshake
and which does not yet provide a data layer once established until a
session has allocated all the required buffers.
In fact, it's more a transport layer, which makes much more sense. The
transport layer offers a medium on which data can transit, and it offers
the functions to move these data when the upper layer requests this. And
it is the upper layer which iterates over the transport layer's functions
to move data which should be called the data layer.
The use case where it's obvious is with embryonic sessions : an incoming
SSL connection is accepted. Only the connection is allocated, not the
buffers nor stream interface, etc... The connection handles the SSL
handshake by itself. Once this handshake is complete, we can't use the
data functions because the buffers and stream interface are not there
yet. Hence we have to first call a specific function to complete the
session initialization, after which we'll be able to use the data
functions. This clearly proves that SSL here is only a transport layer
and that the stream interface constitutes the data layer.
A similar change will be performed to rename app_cb => data, but the
two could not be in the same commit for obvious reasons.
This will be needed to find the stream interface from the connection
once they're detached, but in the more immediate term, we'll need this
for health checks since they don't use a stream interface.
Polling flags were set for data and sock layer, but while this does make
sense for the ENA flag, it does not for the POL flag which translates the
detection of an EAGAIN condition. So now we remove the {DATA,SOCK}_POL*
flags and instead introduce two new layer-independant flags (WANT_RD and
WANT_WR). These flags are only set when an EAGAIN is encountered so that
polling can be enabled.
In order for these flags to have any meaning they are not persistent and
have to be cleared by the connection handler before calling the I/O and
data callbacks. For this reason, changes detection has been slightly
improved. Instead of comparing the WANT_* flags with CURR_*_POL, we only
check if the ENA status changes, or if the polling appears, since we don't
want to detect the useless poll to ena transition. Tests show that this
has eliminated one useless call to __fd_clr().
Finally the conn_set_polling() function which was becoming complex and
required complex operations from the caller was split in two and replaced
its two only callers (conn_update_data_polling and conn_update_sock_polling).
The two functions are now much smaller due to the less complex conditions.
Note that it would be possible to re-merge them and only pass a mask but
this does not appear much interesting.
The PROXY protocol is now decoded in the connection before other
handshakes. This means that it may be extracted from a TCP stream
before SSL is decoded from this stream.
