I know TCP is able to guarantee the delivery of messages from sender to receiver, without corruption (thanks to checksums), in order and without duplication (thanks to sequence numbers).TCP is only one of the lower levels of the protocol stack.
So I'm confused when I read something about MQTT QoS. For example, QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with packet ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged by the receiver, the sender automatically resends the packets not acked. This
is performed by TCP/IP stack or kernel, without the application knows anything about this.
It seems to me it's impossible that a MQTT client needs to resend a MQTT message because it wasn't received by the broker. If this happens, TCP should signal the error to the application that should close and try to reopen the connection.
On 2023-05-19, pozz <pozzugno@gmail.com> wrote:
It seems to me it's impossible that a MQTT client needs to resend
a MQTT message because it wasn't received by the broker. If this
happens, TCP should signal the error to the application that
should close and try to reopen the connection.
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from sender to
receiver, without corruption (thanks to checksums), in order and without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For example, QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with packet ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged by the
receiver, the sender automatically resends the packets not acked. This
is performed by TCP/IP stack or kernel, without the application knows
anything about this.
It seems to me it's impossible that a MQTT client needs to resend a MQTT
message because it wasn't received by the broker. If this happens, TCP
should signal the error to the application that should close and try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
Secondly, there is the issue of resend timeouts. If TCP fails to deliver
the message past the MQTT retry time limit, then MQTT will resend the message.
Il 19/05/2023 17:14, Ed Prochak ha scritto:
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from sender to
receiver, without corruption (thanks to checksums), in order and without >>> duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For example, QoS 1 >>> (at least once) uses ack (PUBACK) and retransmissions (with packet ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged by the >>> receiver, the sender automatically resends the packets not acked. This
is performed by TCP/IP stack or kernel, without the application knows
anything about this.
It seems to me it's impossible that a MQTT client needs to resend a MQTT >>> message because it wasn't received by the broker. If this happens, TCP
should signal the error to the application that should close and try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT application.
How an application running on a machine could lost something? Network
links aren't reliable, but applicaions running on a processor are reliable. Do you think about application crash or an entire machine crash that
needs a reboot? In this case, after the reboot, the MQTT application
usually doesn't know anything about the previous connection, timeout and lost messages... except it saved something on a non volatile memory.
Secondly, there is the issue of resend timeouts. If TCP fails to deliver
the message past the MQTT retry time limit, then MQTT will resend the
message.
What happens in this case? Suppose one TCP fragment with a single MQTT message (just for simplicity) sent by a client to the server (the
broker) was lost. After a TCP timeout, the network stack autonomously
resend the fragment until an ACK is received. Even if the MQTT
application resend the MQTT message *before* TCP timeout, it will not be sent by TCP layer until the previous fragment is acked.
Maybe, more exactly, on the receiver machine, the TCP layer will not
pass the resent message to the application (the MQTT broker) before the
lost TCP segment is received as well. When the lost TCP fragment is received, the broker will receive two MQTT messages: the "original" and
the resent ones. I think it's impossible for the broker to receive the second transmission without receiving the first.
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here.
On 22/05/2023 09:11, pozz wrote:
Il 19/05/2023 17:14, Ed Prochak ha scritto:
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from sender to >>>> receiver, without corruption (thanks to checksums), in order and
without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For example,
QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with packet ids) >>>> to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses the >>>> same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged by >>>> the
receiver, the sender automatically resends the packets not acked. This >>>> is performed by TCP/IP stack or kernel, without the application knows
anything about this.
It seems to me it's impossible that a MQTT client needs to resend a
MQTT
message because it wasn't received by the broker. If this happens, TCP >>>> should signal the error to the application that should close and try to >>>> reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT application.
How an application running on a machine could lost something? Network
links aren't reliable, but applicaions running on a processor are
reliable.
Do you think about application crash or an entire machine crash that
needs a reboot? In this case, after the reboot, the MQTT application
usually doesn't know anything about the previous connection, timeout
and lost messages... except it saved something on a non volatile memory.
Secondly, there is the issue of resend timeouts. If TCP fails to deliver >>> the message past the MQTT retry time limit, then MQTT will resend the
message.
What happens in this case? Suppose one TCP fragment with a single MQTT
message (just for simplicity) sent by a client to the server (the
broker) was lost. After a TCP timeout, the network stack autonomously
resend the fragment until an ACK is received. Even if the MQTT
application resend the MQTT message *before* TCP timeout, it will not
be sent by TCP layer until the previous fragment is acked.
Maybe, more exactly, on the receiver machine, the TCP layer will not
pass the resent message to the application (the MQTT broker) before
the lost TCP segment is received as well. When the lost TCP fragment
is received, the broker will receive two MQTT messages: the "original"
and the resent ones. I think it's impossible for the broker to receive
the second transmission without receiving the first.
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here.
I haven't used MQTT much, but generally if an application gets a timeout
and wants to retry, it will close the TCP/IP connection and open a new one. (Or rather, open a new one while the old one is closing - closing
a failing TCP/IP connection can be slow.)
I would actually have thought that UDP was a more natural choice for
MQTT, rather than TCP - although older versions of MQTT did not have QoS
and were therefore reliant on TCP's acknowledges and retries.
(I always think its a shame that SCTP never caught on - among its many benefits, you don't have this head-of-line blocking issue.)
Il 22/05/2023 10:09, David Brown ha scritto:
On 22/05/2023 09:11, pozz wrote:
Il 19/05/2023 17:14, Ed Prochak ha scritto:
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from
sender to
receiver, without corruption (thanks to checksums), in order and
without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For example,
QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with packet
ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses the >>>>> same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged
by the
receiver, the sender automatically resends the packets not acked. This >>>>> is performed by TCP/IP stack or kernel, without the application knows >>>>> anything about this.
It seems to me it's impossible that a MQTT client needs to resend a >>>>> MQTT
message because it wasn't received by the broker. If this happens, TCP >>>>> should signal the error to the application that should close and
try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT
application. How an application running on a machine could lost
something? Network links aren't reliable, but applicaions running on
a processor are reliable.
Do you think about application crash or an entire machine crash that
needs a reboot? In this case, after the reboot, the MQTT application
usually doesn't know anything about the previous connection, timeout
and lost messages... except it saved something on a non volatile memory. >>>
Secondly, there is the issue of resend timeouts. If TCP fails to
deliver
the message past the MQTT retry time limit, then MQTT will resend the
message.
What happens in this case? Suppose one TCP fragment with a single
MQTT message (just for simplicity) sent by a client to the server
(the broker) was lost. After a TCP timeout, the network stack
autonomously resend the fragment until an ACK is received. Even if
the MQTT application resend the MQTT message *before* TCP timeout, it
will not be sent by TCP layer until the previous fragment is acked.
Maybe, more exactly, on the receiver machine, the TCP layer will not
pass the resent message to the application (the MQTT broker) before
the lost TCP segment is received as well. When the lost TCP fragment
is received, the broker will receive two MQTT messages: the
"original" and the resent ones. I think it's impossible for the
broker to receive the second transmission without receiving the first.
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here.
I haven't used MQTT much, but generally if an application gets a
timeout and wants to retry, it will close the TCP/IP connection and
open a new one. (Or rather, open a new one while the old one is
closing - closing a failing TCP/IP connection can be slow.)
I'm quite sure that MQTT retransmission mechanism is *not* based on a
new TCP connection. In MQTT, the TCP connection is persistent. It can
stay open for days without exchanging any real data. In this case, the keepalive facility is there to detect a broken link.
I would actually have thought that UDP was a more natural choice for
MQTT, rather than TCP - although older versions of MQTT did not have
QoS and were therefore reliant on TCP's acknowledges and retries.
(I always think its a shame that SCTP never caught on - among its many
benefits, you don't have this head-of-line blocking issue.)
On 22/05/2023 11:08, pozz wrote:
Il 22/05/2023 10:09, David Brown ha scritto:
On 22/05/2023 09:11, pozz wrote:
Il 19/05/2023 17:14, Ed Prochak ha scritto:
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from
sender to
receiver, without corruption (thanks to checksums), in order and
without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For example, >>>>>> QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with packet >>>>>> ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that uses >>>>>> the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged >>>>>> by the
receiver, the sender automatically resends the packets not acked. >>>>>> This
is performed by TCP/IP stack or kernel, without the application knows >>>>>> anything about this.
It seems to me it's impossible that a MQTT client needs to resend >>>>>> a MQTT
message because it wasn't received by the broker. If this happens, >>>>>> TCP
should signal the error to the application that should close and
try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT
application. How an application running on a machine could lost
something? Network links aren't reliable, but applicaions running on
a processor are reliable.
Do you think about application crash or an entire machine crash that
needs a reboot? In this case, after the reboot, the MQTT application
usually doesn't know anything about the previous connection, timeout
and lost messages... except it saved something on a non volatile
memory.
Secondly, there is the issue of resend timeouts. If TCP fails to
deliver
the message past the MQTT retry time limit, then MQTT will resend the >>>>> message.
What happens in this case? Suppose one TCP fragment with a single
MQTT message (just for simplicity) sent by a client to the server
(the broker) was lost. After a TCP timeout, the network stack
autonomously resend the fragment until an ACK is received. Even if
the MQTT application resend the MQTT message *before* TCP timeout,
it will not be sent by TCP layer until the previous fragment is acked. >>>> Maybe, more exactly, on the receiver machine, the TCP layer will not
pass the resent message to the application (the MQTT broker) before
the lost TCP segment is received as well. When the lost TCP fragment
is received, the broker will receive two MQTT messages: the
"original" and the resent ones. I think it's impossible for the
broker to receive the second transmission without receiving the first. >>>>
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here.
I haven't used MQTT much, but generally if an application gets a
timeout and wants to retry, it will close the TCP/IP connection and
open a new one. (Or rather, open a new one while the old one is
closing - closing a failing TCP/IP connection can be slow.)
I'm quite sure that MQTT retransmission mechanism is *not* based on a
new TCP connection. In MQTT, the TCP connection is persistent. It can
stay open for days without exchanging any real data. In this case, the
keepalive facility is there to detect a broken link.
If the TCP/IP connection is working correctly, messages will be
transmitted correctly to the broker. If a QoS message fails to be transmitted - the MQTT client or server does not receive an acknowledge
in time - then there are two possible issues. One is that the server/broker application is in trouble. The other is that there is an issue with the network. In most cases, I would suspect the network first. TCP/IP already has acknowledges and timeouts, so if it is a temporary problem then it is likely to be handled there. By the time it reaches the attention of the application protocol's QoS handling, you
are definitely at the point where a new TCP/IP connection is the right
way to go - perhaps targeting a different IP address or via a different route.
The MQTT application already has to handle dropping and making new
TCP/IP connections - even if the norm is for the connection to last for weeks at a time or more. So creating a new TCP/IP link has a lot to
gain, and very little to lose, and it is the standard way to handle such issues.
I would actually have thought that UDP was a more natural choice for
MQTT, rather than TCP - although older versions of MQTT did not have
QoS and were therefore reliant on TCP's acknowledges and retries.
(I always think its a shame that SCTP never caught on - among its
many benefits, you don't have this head-of-line blocking issue.)
Il 22/05/2023 12:54, David Brown ha scritto:
On 22/05/2023 11:08, pozz wrote:
Il 22/05/2023 10:09, David Brown ha scritto:
On 22/05/2023 09:11, pozz wrote:
Il 19/05/2023 17:14, Ed Prochak ha scritto:
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from
sender to
receiver, without corruption (thanks to checksums), in order and >>>>>>> without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For
example, QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with
packet ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that
uses the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well acknowledged >>>>>>> by the
receiver, the sender automatically resends the packets not acked. >>>>>>> This
is performed by TCP/IP stack or kernel, without the application >>>>>>> knows
anything about this.
It seems to me it's impossible that a MQTT client needs to resend >>>>>>> a MQTT
message because it wasn't received by the broker. If this
happens, TCP
should signal the error to the application that should close and >>>>>>> try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT
application. How an application running on a machine could lost
something? Network links aren't reliable, but applicaions running
on a processor are reliable.
Do you think about application crash or an entire machine crash
that needs a reboot? In this case, after the reboot, the MQTT
application usually doesn't know anything about the previous
connection, timeout and lost messages... except it saved something
on a non volatile memory.
Secondly, there is the issue of resend timeouts. If TCP fails to
deliver
the message past the MQTT retry time limit, then MQTT will resend the >>>>>> message.
What happens in this case? Suppose one TCP fragment with a single
MQTT message (just for simplicity) sent by a client to the server
(the broker) was lost. After a TCP timeout, the network stack
autonomously resend the fragment until an ACK is received. Even if
the MQTT application resend the MQTT message *before* TCP timeout,
it will not be sent by TCP layer until the previous fragment is acked. >>>>> Maybe, more exactly, on the receiver machine, the TCP layer will
not pass the resent message to the application (the MQTT broker)
before the lost TCP segment is received as well. When the lost TCP
fragment is received, the broker will receive two MQTT messages:
the "original" and the resent ones. I think it's impossible for the >>>>> broker to receive the second transmission without receiving the first. >>>>>
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here.
I haven't used MQTT much, but generally if an application gets a
timeout and wants to retry, it will close the TCP/IP connection and
open a new one. (Or rather, open a new one while the old one is
closing - closing a failing TCP/IP connection can be slow.)
I'm quite sure that MQTT retransmission mechanism is *not* based on a
new TCP connection. In MQTT, the TCP connection is persistent. It can
stay open for days without exchanging any real data. In this case,
the keepalive facility is there to detect a broken link.
If the TCP/IP connection is working correctly, messages will be
transmitted correctly to the broker. If a QoS message fails to be
transmitted - the MQTT client or server does not receive an
acknowledge in time - then there are two possible issues. One is that
the server/broker application is in trouble. The other is that there
is an issue with the network. In most cases, I would suspect the
network first. TCP/IP already has acknowledges and timeouts, so if it
is a temporary problem then it is likely to be handled there. By the
time it reaches the attention of the application protocol's QoS
handling, you are definitely at the point where a new TCP/IP
connection is the right way to go - perhaps targeting a different IP
address or via a different route.
Yes, this is the only solution for me too. Anyway, I don't know if this behaviour (closing and reopening TCP connection) is described in the
MQTT specifications.
The MQTT application already has to handle dropping and making new
TCP/IP connections - even if the norm is for the connection to last
for weeks at a time or more. So creating a new TCP/IP link has a lot
to gain, and very little to lose, and it is the standard way to handle
such issues.
Here[1] the MQTT client implementation of lwip, a popular TCP/IP stack
for embedded systems.
When the timeout for the ACK is expired, this client only calls an application callback with ERR_TIMEOUT. Maybe the decision to close and reopen a new TCP connection is passed to the application.
I don't know if other MQTT clients implement an embedded mechanism that automatically tries to solve the issue of lost ACKs by reopening a TCP connection.
I would actually have thought that UDP was a more natural choice for
MQTT, rather than TCP - although older versions of MQTT did not have
QoS and were therefore reliant on TCP's acknowledges and retries.
(I always think its a shame that SCTP never caught on - among its
many benefits, you don't have this head-of-line blocking issue.)
[1] https://github.com/lwip-tcpip/lwip/blob/master/src/apps/mqtt/mqtt.c
On 23/05/2023 08:53, pozz wrote:
Il 22/05/2023 12:54, David Brown ha scritto:
On 22/05/2023 11:08, pozz wrote:
Il 22/05/2023 10:09, David Brown ha scritto:
On 22/05/2023 09:11, pozz wrote:
Il 19/05/2023 17:14, Ed Prochak ha scritto:I haven't used MQTT much, but generally if an application gets a
On Friday, May 19, 2023 at 5:42:14 AM UTC-4, pozz wrote:
I know TCP is able to guarantee the delivery of messages from >>>>>>>> sender to
receiver, without corruption (thanks to checksums), in order and >>>>>>>> without
duplication (thanks to sequence numbers).
So I'm confused when I read something about MQTT QoS. For
example, QoS 1
(at least once) uses ack (PUBACK) and retransmissions (with
packet ids)
to guarantee that the message is delivered at least one time.
I'm wondering how this is possible over a TCP connection that >>>>>>>> uses the
same technique of ack and sequence numbers.
From what I know about TCP, if some data isn't well
acknowledged by the
receiver, the sender automatically resends the packets not
acked. This
is performed by TCP/IP stack or kernel, without the application >>>>>>>> knows
anything about this.
It seems to me it's impossible that a MQTT client needs to
resend a MQTT
message because it wasn't received by the broker. If this
happens, TCP
should signal the error to the application that should close and >>>>>>>> try to
reopen the connection.
TCP is only one of the lower levels of the protocol stack.
Data can sometimes be lost in the higher levels.
In this case, there's only one higher level, that is MQTT
application. How an application running on a machine could lost
something? Network links aren't reliable, but applicaions running >>>>>> on a processor are reliable.
Do you think about application crash or an entire machine crash
that needs a reboot? In this case, after the reboot, the MQTT
application usually doesn't know anything about the previous
connection, timeout and lost messages... except it saved something >>>>>> on a non volatile memory.
Secondly, there is the issue of resend timeouts. If TCP fails to >>>>>>> deliver
the message past the MQTT retry time limit, then MQTT will resend >>>>>>> the
message.
What happens in this case? Suppose one TCP fragment with a single >>>>>> MQTT message (just for simplicity) sent by a client to the server >>>>>> (the broker) was lost. After a TCP timeout, the network stack
autonomously resend the fragment until an ACK is received. Even if >>>>>> the MQTT application resend the MQTT message *before* TCP timeout, >>>>>> it will not be sent by TCP layer until the previous fragment is
acked.
Maybe, more exactly, on the receiver machine, the TCP layer will
not pass the resent message to the application (the MQTT broker)
before the lost TCP segment is received as well. When the lost TCP >>>>>> fragment is received, the broker will receive two MQTT messages:
the "original" and the resent ones. I think it's impossible for
the broker to receive the second transmission without receiving
the first.
So it seems to me the retransmission made at the MQTT level is
completely useless... but I think I didn't get the real point here. >>>>>
timeout and wants to retry, it will close the TCP/IP connection and >>>>> open a new one. (Or rather, open a new one while the old one is
closing - closing a failing TCP/IP connection can be slow.)
I'm quite sure that MQTT retransmission mechanism is *not* based on
a new TCP connection. In MQTT, the TCP connection is persistent. It
can stay open for days without exchanging any real data. In this
case, the keepalive facility is there to detect a broken link.
If the TCP/IP connection is working correctly, messages will be
transmitted correctly to the broker. If a QoS message fails to be
transmitted - the MQTT client or server does not receive an
acknowledge in time - then there are two possible issues. One is
that the server/broker application is in trouble. The other is that
there is an issue with the network. In most cases, I would suspect
the network first. TCP/IP already has acknowledges and timeouts, so
if it is a temporary problem then it is likely to be handled there.
By the time it reaches the attention of the application protocol's
QoS handling, you are definitely at the point where a new TCP/IP
connection is the right way to go - perhaps targeting a different IP
address or via a different route.
Yes, this is the only solution for me too. Anyway, I don't know if
this behaviour (closing and reopening TCP connection) is described in
the MQTT specifications.
I haven't read the MQTT specifications - I don't even know what documentation exists for the protocol. But implementation details like this are not always covered in such documents, as it is really at a
level below the protocol itself. (The specifications for HTTP, for example, don't say how many simultaneous connections a browser should
have to a web server, or when it should give up and retry.) So don't be surprised if this is /not/ in the specs - that does not mean a client
cannot or should not make new TCP/IP connections.
The MQTT application already has to handle dropping and making new
TCP/IP connections - even if the norm is for the connection to last
for weeks at a time or more. So creating a new TCP/IP link has a lot
to gain, and very little to lose, and it is the standard way to
handle such issues.
Here[1] the MQTT client implementation of lwip, a popular TCP/IP stack
for embedded systems.
This is a bit muddled. I am familiar with LWIP, but I don't know
whether you are talking about an MQTT client that you wrote yourself, or which comes as part of newer LWIP, or which someone else contributed as
a sample.
When the timeout for the ACK is expired, this client only calls an
application callback with ERR_TIMEOUT. Maybe the decision to close and
reopen a new TCP connection is passed to the application.
Yes, that would be the normal behaviour.
I don't know if other MQTT clients implement an embedded mechanism
that automatically tries to solve the issue of lost ACKs by reopening
a TCP connection.
I don't know either. I can only tell you that if you are failing to communicate on a TCP/IP connection, then making a new one (possibly
after a delay) is the normal way to handle things if you want automatic recovery.
I would actually have thought that UDP was a more natural choice
for MQTT, rather than TCP - although older versions of MQTT did not >>>>> have QoS and were therefore reliant on TCP's acknowledges and retries. >>>>>
(I always think its a shame that SCTP never caught on - among its
many benefits, you don't have this head-of-line blocking issue.)
[1] https://github.com/lwip-tcpip/lwip/blob/master/src/apps/mqtt/mqtt.c
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