When we create a connection, if we have to defer the conn_stream and the
mux creation until we can decide it (ie until the SSL handshake is done, and
the ALPN is decided), store the connection in the stream_interface, so that
we're sure we can destroy it if needed.
If an ALPN (or a NPN) was chosen for a server, defer choosing the mux until
after the SSL handshake is done, and the ALPN/NPN has been negociated, so
that we know which mux to pick.
Right now we measure for each task the cumulated time spent waiting for
the CPU and using it. The timestamp uses a 64-bit integer to report a
nanosecond-level date. This is only enabled when "profiling.tasks" is
enabled, and consumes less than 1% extra CPU on x86_64 when enabled.
The cumulated processing time and wait time are reported in "show sess".
The task's counters are also reset when an HTTP transaction is reset
since the HTTP part pretends to restart on a fresh new stream. This
will make sure we always report correct numbers for each request in
the logs.
This is a new global setting which enables or disables CPU profiling
per task. For now it only sets/resets the variable based on the global
option "profiling.tasks" and supports showing it as well as setting it
from the CLI using "show profiling" and "set profiling". The option will
be used by a future commit. It was done in a way which should ease future
addition of profiling options.
Since we know the time it takes to process everything between two poll()
calls, we can use this as the max latency measurement any task will
experience and average it.
This code does this, and reports in "show activity" the average of this
loop time over the last 1024 poll() loops, for each thread. It will vary
quickly at high loads and slowly under low to moderate loads, depending
on the rate at which poll() is called. The latency a task experiences
is expected to be half of this on average.
At the moment the situation with activity measurement is quite tricky
because the struct activity is defined in global.h and declared in
haproxy.c, with operations made in time.h and relying on freq_ctr
which are defined in freq_ctr.h which itself includes time.h. It's
barely possible to touch any of these files without breaking all the
circular dependency.
Let's move all this stuff to activity.{c,h} and be done with it. The
measurement of active and stolen time is now done in a dedicated
function called just after tv_before_poll() instead of mixing the two,
which used to be a lazy (but convenient) decision.
No code was changed, stuff was just moved around.
Just found that proto/cli.h doesn't build if types/cli.h is not also
included by the caller, as it uses cli_kw_list is used in arguments.
But it's also true for a few other ones like mworker_proc, stream,
and channel, so let's fix this.
The new function signal_unregister() removes every handlers assigned to
a signal. Once the handler list of the signal is empty, the signal is
ignored with SIG_IGN.
This was the largest function of the whole file, taking a rough second
to build alone. Let's move it to a distinct file along with a few
dependencies. Doing so saved about 2 seconds on the total build time.
It does the same than smp_prefetch_http but for HTX messages. It can be called
from an HTTP proxy or a TCP proxy. For HTTP proxies, the parsing is handled by
the mux, so it does nothing but wait. For TCP proxies, it tries to parse an HTTP
message and to convert it in a temporary HTX message. Sample fetches will use
this temporary variable to do their job.
It is more or less the same than legacy version but adapted to be called from
HTX analyzers. In the legacy version of this function, we switch on the HTX code
when applicable.
It is more or less the same than legacy version but adapted to be called from
HTX analyzers. In the legacy version of this function, we switch on the HTX code
when applicable.
It is more or less the same than legacy versions but adapted to be called from
HTX analyzers. In the legacy versions of these functions, we switch on the HTX
code when applicable.
It is more or less the same than legacy versions but adapted to be called from
HTX analyzers. In the legacy versions of these functions, we switch on the HTX
code when applicable.
This file will host all functions to manipulate HTTP messages using the HTX
representation. Functions in this file will be able to be called from anywhere
and are mainly related to the HTTP semantics.
The internal representation of an HTTP message, called HTX, is a structured
representation, unlike the old one which is a raw representation of
messages. Idea is to have a version-agnostic representation of the HTTP
messages, which can be easily used by to handle HTTP/1, HTTP/2 and hopefully
QUIC messages, and communication from one of them to another.
In this patch, we add types to define the internal representation itself and the
main functions to manipulate them.
Now, the connection mode is detected in the mux and not in HTX analyzers
anymore. Keep-alive connections are now managed by the mux. A new stream is
created for each transaction. This removes the most important part of the
synchronization between channels and the HTTP transaction cleanup. These changes
only affect the HTX part (proto_htx.c). Legacy HTTP analyzers remain untouched
for now.
On the client-side, the mux is responsible to create new streams when a new
request starts. It is also responsible to parse and update the "Connection:"
header of the response. On the server-side, the mux is responsible to parse and
update the "Connection:" header of the request. Muxes on each side are
independent. For now, there is no connection pool on the server-side, so it
always close the server connection.
For now, these analyzers are just copies of the legacy HTTP analyzers. But,
during the HTTP refactoring, it will be the main place where it will be
visible. And in legacy analyzers, the macro IS_HTX_STRM is used to know if the
HTX version should be called or not.
Note: the following commits were applied to proto_http.c after this patch
was developed and need to be studied to see if an adaptation to htx
is required :
fd9b68c BUG/MINOR: only mark connections private if NTLM is detected
To prepare the refactoring of the code handling HTTP messages, these macros will
help to use HTX functions instead of legacy ones when the new HTX internal
representation is in use. To do so, for a given stream, we will check if its
frontend has the option PR_O2_USE_HTX. It is useless to test backend options
because it is not possible to mix the HTX representation and the legacy one
(i.e, having an HTX frontend and a legacy backend or vice versa).
Do not destroy the connection when we're about to destroy a stream. This
prevents us from doing keepalive on server connections when the client is
using HTTP/2, as a new stream is created for each request.
Instead, the session is now responsible for destroying connections.
When reusing connections, the attach() mux method is now used to create a new
conn_stream.
Introduce a new field in session, "srv_conn", and a linked list of sessions
in the connection. It will be used later when we'll switch connections
from being managed by the stream, to being managed by the session.
Remaining calls to si_cant_put() were all for lack of room and were
turned to si_rx_room_blk(). A few places where SI_FL_RXBLK_ROOM was
cleared by hand were converted to si_rx_room_rdy().
The now unused si_cant_put() function was removed.
The channel can disable reading from the stream-interface using various
methods, such as :
- CF_DONT_READ
- !channel_may_recv()
- and possibly others
Till now this was done by mangling SI_FL_RX_WAIT_EP which is not
appropriate at all since it's not the stream interface which decides
whether it wants to deliver data or not. Some places were also wrongly
relying on SI_FL_RXBLK_ROOM since it was the only other alternative,
but it's not suitable for CF_DONT_READ.
Let's use the SI_FL_RXBLK_CHAN flag for this instead. It will properly
prevent the stream interface from being woken up and reads from
subscribing to more receipt without being accidently removed. It is
automatically reset if CF_DONT_READ is not set in stream_int_notify().
The code is not trivial because it splits the logic between everything
related to buffer contents (channel_is_empty(), CF_WRITE_PARTIAL, etc)
and buffer policy (CF_DONT_READ). Also it now needs to decide timeouts
based on any blocking flag and not just SI_FL_RXBLK_ROOM anymore.
It looks like this patch has caused a minor performance degradation on
connection rate, which possibly deserves being investigated deeper as
the test conditions are uncertain (e.g. slightly more subscribe calls?).
Till now we were using si_done_put() upon shutr, but these flags could
be reset upon next activity. Now let's switch to SI_FL_RXBLK_SHUT which
doesn't go away. It's also set in stream_int_update() in case a shutr
condition is detected.
The now unused si_done_put() was removed.
Instead of checking complex conditions to call si_cs_recv() upon first
call, let's simply use si_rx_endp_ready() now that si_cs_recv() reports
it accurately, and add si_rx_blocked() to cover any blocking situation.
The stream interface used to conflate a missing buffer and lack of
buffer space into SI_FL_WAIT_ROOM but this causes difficulties as
these cannot be checked at the same moment and are not resolved at
the same moment either. Now we instead mark the buffer as presumably
available using si_rx_buff_rdy() and mark it as unavailable+requested
using si_rx_buff_blk().
The call to si_alloc_buf() was moved after si_stop_put(). This makes
sure that the SI_FL_RX_WAIT_EP flag is cleared on allocation failure so
that the function is called again if the callee fails to do its work.
The SI_FL_WANT_PUT flag is used in an awkward way, sometimes it's
set by the stream-interface to mean "I have something to deliver",
sometimes it's cleared by the channel to say "I don't want you to
send what you have", and it has to be set back once CF_DONT_READ
is cleared. This will have to be split between SI_FL_RX_WAIT_EP
and SI_FL_RXBLK_CHAN. This patch only replaces all uses of the
flag with its natural (but negated) replacement SI_FL_RX_WAIT_EP.
The code is expected to be strictly equivalent. The now unused flag
was completely removed.
The first ones are used to figure if a direction is blocked on the
stream interface for anything but the end point. The second ones are
used to detect if the end point is ready to receive/transmit. They
should be used instead of directly fiddling with the existing bits.
This flag is not enough to describe all blocking situations, as can be
seen in each case we remove it. The muxes has taught us that using multiple
blocking flags in parallel will be much easier, so let's start to do this
now. This patch only renames this flags in order to make next changes more
readable.
This method is used to retrieve the first known good conn_stream from
the mux. It will be used to find the other end of a connection when
dealing with the proxy protocol for example.
There are still some unwelcome synchronous calls to si_cs_recv() in
process_stream(). Let's have a new function si_sync_recv() to perform
a synchronous receive call on a stream interface regardless of the type
of its endpoint, and move these calls there. For now it only implements
conn_streams since it doesn't seem useful to support applets there. The
function implements an extra check for the stream interface to be in an
established state before attempting anything.
It's easy to detect when logs on some paths are lost as sendmsg() will
return EAGAIN. This is particularly true when sending to /dev/log, which
often doesn't support a big logging capacity. Let's keep track of these
and report the total number of dropped messages in "show info".
We exclusively use stream_int_update() now, the lower layers are not
called anymore so let's remove them, as well as si_update() which used
to be their wrapper.
The function used to be called in turn for each side of the stream, but
since it's called exclusively from process_stream(), it prevents us from
making use of the knowledge we have of the operations in progress for
each side, resulting in having to go all the way through functions like
stream_int_notify() which are not appropriate there.
That patch creates a new function, si_update_both() which takes two
stream interfaces expected to belong to the same stream, and processes
their flags in a more suitable order, but for now doesn't change the
logic at all.
The next step will consist in trying to reinsert the rest of the socket
layer-specific update code to ultimately update the flags correctly at
the end of the operation.
After careful inspection, it now seems OK to call si_chk_rcv() only when
SI_FL_WAIT_ROOM is cleared and SI_FL_WANT_PUT is set, since all identified
call places have already taken care of this.
Instead of clearing the SI_FL_WAIT_ROOM flag and losing the information
about the need from the producer to be woken up, we now call si_chk_rcv()
immediately. This is cheap to do and it could possibly be further improved
by only doing it when SI_FL_WAIT_ROOM was still set, though this will
require some extra auditing of the code paths.
The only remaining place where the flag was cleared without a call to
si_chk_rcv() is si_alloc_ibuf(), but since this one is called from a
receive path woken up from si_chk_rcv() or not having failed, the
clearing was not necessary anymore either.
And there was one place in stream_int_notify() where si_chk_rcv() was
called with SI_FL_WAIT_ROOM still explicitly set so this place was
adjusted in order to clear the flag prior to calling si_chk_rcv().
Now we don't have any situation where we randomly clear SI_FL_WAIT_ROOM
without trying to wake the other side up, nor where we call si_chk_rcv()
with the flag set, so this flag should accurately represent a failed
attempt at putting data into the buffer.
When CF_DONT_READ is set, till now we used to set SI_FL_WAIT_ROOM, which
is not appropriate since it would lose the subscribe status. Instead let's
clear SI_FL_WANT_PUT (just like applets do), and set the flag only when
CF_DONT_READ is cleared.
We have to do this in stream_int_update(), and in si_cs_io_cb() after
returning from si_cs_recv() since it would be a bit invasive to hack
this one for now. It must not be done in stream_int_notify() otherwise
it would re-enable blocked applets.
Last, when si_chk_rcv() is called, it immediately clears the flag before
calling ->chk_rcv() so that we are not tempted to uselessly loop on the
same call until the receive function is called. This is the same principle
as what is done with the applet scheduler.
This flag should already be cleared before calling the *chk_rcv() functions.
Before adapting all call places, let's first make sure si_chk_rcv() clears
it before calling them so that these functions do not have to check it again
and so that they do not adjust it. This function will only call the lower
layers if the SI_FL_WANT_PUT flag is present so that the endpoint can decide
not to be called (as done with applets).
