doc/design-thoughts/http2.txt - haproxy - Gitiles

 2014/10/23 - design thoughts for HTTP/2

 - connections : HTTP/2 depends a lot more on a connection than HTTP/1 because a
   connection holds a compression context (headers table, etc...). We probably
   need to have an h2_conn struct.

 - multiple transactions will be handled in parallel for a given h2_conn. They
   are called streams in HTTP/2 terminology.

 - multiplexing : for a given client-side h2 connection, we can have multiple
   server-side h2 connections. And for a server-side h2 connection, we can have
   multiple client-side h2 connections. Streams circulate in N-to-N fashion.

 - flow control : flow control will be applied between multiple streams. Special
   care must be taken so that an H2 client cannot block some H2 servers by
   sending requests spread over multiple servers to the point where one server
   response is blocked and prevents other responses from the same server from
   reaching their clients. H2 connection buffers must always be empty or nearly
   empty. The per-stream flow control needs to be respected as well as the
   connection's buffers. It is important to implement some fairness between all
   the streams so that it's not always the same which gets the bandwidth when
   the connection is congested.

 - some clients can be H1 with an H2 server (is this really needed ?). Most of
   the initial use case will be H2 clients to H1 servers. It is important to keep
   in mind that H1 servers do not do flow control and that we don't want them to
   block transfers (eg: post upload).

 - internal tasks : some H2 clients will be internal tasks (eg: health checks).
   Some H2 servers will be internal tasks (eg: stats, cache). The model must be
   compatible with this use case.

 - header indexing : headers are transported compressed, with a reference to a
   static or a dynamic header, or a literal, possibly huffman-encoded. Indexing
   is specific to the H2 connection. This means there is no way any binary data
   can flow between both sides, headers will have to be decoded according to the
   incoming connection's context and re-encoded according to the outgoing
   connection's context, which can significantly differ. In order to avoid the
   parsing trouble we currently face, headers will have to be clearly split
   between name and value. It is worth noting that neither the incoming nor the
   outgoing connections' contexts will be of any use while processing the
   headers. At best we can have some shortcuts for well-known names that map
   well to the static ones (eg: use the first static entry with same name), and
   maybe have a few special cases for static name+value as well. Probably we can
   classify headers in such categories :

     - static name + value
     - static name + other value
     - dynamic name + other value

   This will allow for better processing in some specific cases. Headers
   supporting a single value (:method, :status, :path, ...) should probably
   be stored in a single location with a direct access. That would allow us
   to retrieve a method using hdr[METHOD]. All such indexing must be performed
   while parsing. That also means that HTTP/1 will have to be converted to this
   representation very early in the parser and possibly converted back to H/1
   after processing.

   Header names/values will have to be placed in a small memory area that will
   inevitably get fragmented as headers are rewritten. An automatic packing
   mechanism must be implemented so that when there's no more room, headers are
   simply defragmented/packet to a new table and the old one is released. Just
   like for the static chunks, we need to have a few such tables pre-allocated
   and ready to be swapped at any moment. Repacking must not change any index
   nor affect the way headers are compressed so that it can happen late after a
   retry (send-name-header for example).

 - header processing : can still happen on a (header, value) basis. Reqrep/
   rsprep completely disappear and will have to be replaced with something else
   to support renaming headers and rewriting url/path/...

 - push_promise : servers can push dummy requests+responses. They advertise
   the stream ID in the push_promise frame indicating the associated stream ID.
   This means that it is possible to initiate a client-server stream from the
   information coming from the server and make the data flow as if the client
   had made it. It's likely that we'll have to support two types of server
   connections: those which support push and those which do not. That way client
   streams will be distributed to existing server connections based on their
   capabilities. It's important to keep in mind that PUSH will not be rewritten
   in responses.

 - stream ID mapping : since the stream ID is per H2 connection, stream IDs will
   have to be mapped. Thus a given stream is an entity with two IDs (one per
   side). Or more precisely a stream has two end points, each one carrying an ID
   when it ends on an HTTP2 connection. Also, for each stream ID we need to
   quickly find the associated transaction in progress. Using a small quick
   unique tree seems indicated considering the wide range of valid values.

 - frame sizes : frame have to be remapped between both sides as multiplexed
   connections won't always have the same characteristics. Thus some frames
   might be spliced and others will be sliced.

 - error processing : care must be taken to never break a connection unless it
   is dead or corrupt at the protocol level. Stats counter must exist to observe
   the causes. Timeouts are a great problem because silent connections might
   die out of inactivity. Ping frames should probably be scheduled a few seconds
   before the connection timeout so that an unused connection is verified before
   being killed. Abnormal requests must be dealt with using RST_STREAM.

 - ALPN : ALPN must be observed onthe client side, and transmitted to the server
   side.

 - proxy protocol : proxy protocol makes little to no sense in a multiplexed
   protocol. A per-stream equivalent will surely be needed if implementations
   do not quickly generalize the use of Forward.

 - simplified protocol for local devices (eg: haproxy->varnish in clear and
   without handshake, and possibly even with splicing if the connection's
   settings are shared)

 - logging : logging must report a number of extra information such as the
   stream ID, and whether the transaction was initiated by the client or by the
   server (which can be deduced from the stream ID's parity). In case of push,
   the number of the associated stream must also be reported.

 - memory usage : H2 increases memory usage by mandating use of 16384 bytes
   frame size minimum. That means slightly more than 16kB of buffer in each
   direction to process any frame. It will definitely have an impact on the
   deployed maxconn setting in places using less than this (4..8kB are common).
   Also, the header list is persistent per connection, so if we reach the same
   size as the request, that's another 16kB in each direction, resulting in
   about 48kB of memory where 8 were previously used. A more careful encoder
   can work with a much smaller set even if that implies evicting entries
   between multiple headers of the same message.

 - HTTP/1.0 should very carefully be transported over H2. Since there's no way
   to pass version information in the protocol, the server could use some
   features of HTTP/1.1 that are unsafe in HTTP/1.0 (compression, trailers,
   ...).

 - host / :authority : ":authority" is the norm, and "host" will be absent when
   H2 clients generate :authority. This probably means that a dummy Host header
   will have to be produced internally from :authority and removed when passing
   to H2 behind. This can cause some trouble when passing H2 requests to H1
   proxies, because there's no way to know if the request should contain scheme
   and authority in H1 or not based on the H2 request. Thus a "proxy" option
   will have to be explicitly mentionned on HTTP/1 server lines. One of the
   problem that it creates is that it's not longer possible to pass H/1 requests
   to H/1 proxies without an explicit configuration. Maybe a table of the
   various combinations is needed.

                            :scheme   :authority   host
        HTTP/2 request      present   present      absent
        HTTP/1 server req   absent    absent       present
        HTTP/1 proxy req    present   present      present

   So in the end the issue is only with H/2 requests passed to H/1 proxies.

 - ping frames : they don't indicate any stream ID so by definition they cannot
   be forwarded to any server. The H2 connection should deal with them only.

 There's a layering problem with H2. The framing layer has to be aware of the
 upper layer semantics. We can't simply re-encode HTTP/1 to HTTP/2 then pass
 it over a framing layer to mux the streams, the frame type must be passed below
 so that frames are properly arranged. Header encoding is connection-based and
 all streams using the same connection will interact in the way their headers
 are encoded. Thus the encoder *has* to be placed in the h2_conn entity, and
 this entity has to know for each stream what its headers are.

 Probably that we should remove *all* headers from transported data and move
 them on the fly to a parallel structure that can be shared between H1 and H2
 and consumed at the appropriate level. That means buffers only transport data.
 Trailers have to be dealt with differently.

 So if we consider an H1 request being forwarded between a client and a server,
 it would look approximately like this :

   - request header + body land into a stream's receive buffer
   - headers are indexed and stripped out so that only the body and whatever
     follows remain in the buffer
   - both the header index and the buffer with the body stay attached to the
     stream
   - the sender can rebuild the whole headers. Since they're found in a table
     supposed to be stable, it can rebuild them as many times as desired and
     will always get the same result, so it's safe to build them into the trash
     buffer for immediate sending, just as we do for the PROXY protocol.
   - the upper protocol should probably provide a build_hdr() callback which
     when called by the socket layer, builds this header block based on the
     current stream's header list, ready to be sent.
   - the socket layer has to know how many bytes from the headers are left to be
     forwarded prior to processing the body.
   - the socket layer needs to consume only the acceptable part of the body and
     must not release the buffer if any data remains in it (eg: pipelining over
     H1). This is already handled by channel->o and channel->to_forward.
   - we could possibly have another optional callback to send a preamble before
     data, that could be used to send chunk sizes in H1. The danger is that it
     absolutely needs to be stable if it has to be retried. But it could
     considerably simplify de-chunking.

 When the request is sent to an H2 server, an H2 stream request must be made
 to the server, we find an existing connection whose settings are compatible
 with our needs (eg: tls/clear, push/no-push), and with a spare stream ID. If
 none is found, a new connection must be established, unless maxconn is reached.

 Servers must have a maxstream setting just like they have a maxconn. The same
 queue may be used for that.

 The "tcp-request content" ruleset must apply to the TCP layer. But with HTTP/2
 that becomes impossible (and useless). We still need something like the
 "tcp-request session" hook to apply just after the SSL handshake is done.

 It is impossible to defragment the body on the fly in HTTP/2. Since multiple
 messages are interleaved, we cannot wait for all of them and block the head of
 line. Thus if body analysis is required, it will have to use the stream's
 buffer, which necessarily implies a copy. That means that with each H2 end we
 necessarily have at least one copy. Sometimes we might be able to "splice" some
 bytes from one side to the other without copying into the stream buffer (same
 rules as for TCP splicing).

 In theory, only data should flow through the channel buffer, so each side's
 connector is responsible for encoding data (H1: linear/chunks, H2: frames).
 Maybe the same mechanism could be extrapolated to tunnels / TCP.

 Since we'd use buffers only for data (and for receipt of headers), we need to
 have dynamic buffer allocation.

 Thus :
 - Tx buffers do not exist. We allocate a buffer on the fly when we're ready to
   send something that we need to build and that needs to be persistent in case
   of partial send. H1 headers are built on the fly from the header table to a
   temporary buffer that is immediately sent and whose amount of sent bytes is
   the only information kept (like for PROXY protocol). H2 headers are more
   complex since the encoding depends on what was successfully sent. Thus we
   need to build them and put them into a temporary buffer that remains
   persistent in case send() fails. It is possible to have a limited pool of
   Tx buffers and refrain from sending if there is no more buffer available in
   the pool. In that case we need a wake-up mechanism once a buffer is
   available. Once the data are sent, the Tx buffer is then immediately recycled
   in its pool. Note that no tx buffer being used (eg: for hdr or control) means
   that we have to be able to serialize access to the connection and retry with
   the same stream. It also means that a stream that times out while waiting for
   the connector to read the second half of its request has to stay there, or at
   least needs to be handled gracefully. However if the connector cannot read
   the data to be sent, it means that the buffer is congested and the connection
   is dead, so that probably means it can be killed.

 - Rx buffers have to be pre-allocated just before calling recv(). A connection
   will first try to pick a buffer and disable reception if it fails, then
   subscribe to the list of tasks waiting for an Rx buffer.

 - full Rx buffers might sometimes be moved around to the next buffer instead of
   experiencing a copy. That means that channels and connectors must use the
   same format of buffer, and that only the channel will have to see its
   pointers adjusted.

 - Tx of data should be made as much as possible without copying. That possibly
   means by directly looking into the connection buffer on the other side if
   the local Tx buffer does not exist and the stream buffer is not allocated, or
   even performing a splice() call between the two sides. One of the problem in
   doing this is that it requires proper ordering of the operations (eg: when
   multiple readers are attached to a same buffer). If the splitting occurs upon
   receipt, there's no problem. If we expect to retrieve data directly from the
   original buffer, it's harder since it contains various things in an order
   which does not even indicate what belongs to whom. Thus possibly the only
   mechanism to implement is the buffer permutation which guarantees zero-copy
   and only in the 100% safe case. Also it's atomic and does not cause HOL
   blocking.

 It makes sense to chose the frontend_accept() function right after the
 handshake ended. It is then possible to check the ALPN, the SNI, the ciphers
 and to accept to switch to the h2_conn_accept handler only if everything is OK.
 The h2_conn_accept handler will have to deal with the connection setup,
 initialization of the header table, exchange of the settings frames and
 preparing whatever is needed to fire new streams upon receipt of unknown
 stream IDs. Note: most of the time it will not be possible to splice() because
 we need to know in advance the amount of bytes to write the header, and here it
 will not be possible.

 H2 health checks must be seen as regular transactions/streams. The check runs a
 normal client which seeks an available stream from a server. The server then
 finds one on an existing connection or initiates a new H2 connection. The H2
 checks will have to be configurable for sharing streams or not. Another option
 could be to specify how many requests can be made over existing connections
 before insisting on getting a separate connection. Note that such separate
 connections might end up stacking up once released. So probably that they need
 to be recycled very quickly (eg: fix how many unused ones can exist max).
	2014/10/23 - design thoughts for HTTP/2

	- connections : HTTP/2 depends a lot more on a connection than HTTP/1 because a
	connection holds a compression context (headers table, etc...). We probably
	need to have an h2_conn struct.

	- multiple transactions will be handled in parallel for a given h2_conn. They
	are called streams in HTTP/2 terminology.

	- multiplexing : for a given client-side h2 connection, we can have multiple
	server-side h2 connections. And for a server-side h2 connection, we can have
	multiple client-side h2 connections. Streams circulate in N-to-N fashion.

	- flow control : flow control will be applied between multiple streams. Special
	care must be taken so that an H2 client cannot block some H2 servers by
	sending requests spread over multiple servers to the point where one server
	response is blocked and prevents other responses from the same server from
	reaching their clients. H2 connection buffers must always be empty or nearly
	empty. The per-stream flow control needs to be respected as well as the
	connection's buffers. It is important to implement some fairness between all
	the streams so that it's not always the same which gets the bandwidth when
	the connection is congested.

	- some clients can be H1 with an H2 server (is this really needed ?). Most of
	the initial use case will be H2 clients to H1 servers. It is important to keep
	in mind that H1 servers do not do flow control and that we don't want them to
	block transfers (eg: post upload).

	- internal tasks : some H2 clients will be internal tasks (eg: health checks).
	Some H2 servers will be internal tasks (eg: stats, cache). The model must be
	compatible with this use case.

	- header indexing : headers are transported compressed, with a reference to a
	static or a dynamic header, or a literal, possibly huffman-encoded. Indexing
	is specific to the H2 connection. This means there is no way any binary data
	can flow between both sides, headers will have to be decoded according to the
	incoming connection's context and re-encoded according to the outgoing
	connection's context, which can significantly differ. In order to avoid the
	parsing trouble we currently face, headers will have to be clearly split
	between name and value. It is worth noting that neither the incoming nor the
	outgoing connections' contexts will be of any use while processing the
	headers. At best we can have some shortcuts for well-known names that map
	well to the static ones (eg: use the first static entry with same name), and
	maybe have a few special cases for static name+value as well. Probably we can
	classify headers in such categories :

	- static name + value
	- static name + other value
	- dynamic name + other value

	This will allow for better processing in some specific cases. Headers
	supporting a single value (:method, :status, :path, ...) should probably
	be stored in a single location with a direct access. That would allow us
	to retrieve a method using hdr[METHOD]. All such indexing must be performed
	while parsing. That also means that HTTP/1 will have to be converted to this
	representation very early in the parser and possibly converted back to H/1
	after processing.

	Header names/values will have to be placed in a small memory area that will
	inevitably get fragmented as headers are rewritten. An automatic packing
	mechanism must be implemented so that when there's no more room, headers are
	simply defragmented/packet to a new table and the old one is released. Just
	like for the static chunks, we need to have a few such tables pre-allocated
	and ready to be swapped at any moment. Repacking must not change any index
	nor affect the way headers are compressed so that it can happen late after a
	retry (send-name-header for example).

	- header processing : can still happen on a (header, value) basis. Reqrep/
	rsprep completely disappear and will have to be replaced with something else
	to support renaming headers and rewriting url/path/...

	- push_promise : servers can push dummy requests+responses. They advertise
	the stream ID in the push_promise frame indicating the associated stream ID.
	This means that it is possible to initiate a client-server stream from the
	information coming from the server and make the data flow as if the client
	had made it. It's likely that we'll have to support two types of server
	connections: those which support push and those which do not. That way client
	streams will be distributed to existing server connections based on their
	capabilities. It's important to keep in mind that PUSH will not be rewritten
	in responses.

	- stream ID mapping : since the stream ID is per H2 connection, stream IDs will
	have to be mapped. Thus a given stream is an entity with two IDs (one per
	side). Or more precisely a stream has two end points, each one carrying an ID
	when it ends on an HTTP2 connection. Also, for each stream ID we need to
	quickly find the associated transaction in progress. Using a small quick
	unique tree seems indicated considering the wide range of valid values.

	- frame sizes : frame have to be remapped between both sides as multiplexed
	connections won't always have the same characteristics. Thus some frames
	might be spliced and others will be sliced.

	- error processing : care must be taken to never break a connection unless it
	is dead or corrupt at the protocol level. Stats counter must exist to observe
	the causes. Timeouts are a great problem because silent connections might
	die out of inactivity. Ping frames should probably be scheduled a few seconds
	before the connection timeout so that an unused connection is verified before
	being killed. Abnormal requests must be dealt with using RST_STREAM.

	- ALPN : ALPN must be observed onthe client side, and transmitted to the server
	side.

	- proxy protocol : proxy protocol makes little to no sense in a multiplexed
	protocol. A per-stream equivalent will surely be needed if implementations
	do not quickly generalize the use of Forward.

	- simplified protocol for local devices (eg: haproxy->varnish in clear and
	without handshake, and possibly even with splicing if the connection's
	settings are shared)

	- logging : logging must report a number of extra information such as the
	stream ID, and whether the transaction was initiated by the client or by the
	server (which can be deduced from the stream ID's parity). In case of push,
	the number of the associated stream must also be reported.

	- memory usage : H2 increases memory usage by mandating use of 16384 bytes
	frame size minimum. That means slightly more than 16kB of buffer in each
	direction to process any frame. It will definitely have an impact on the
	deployed maxconn setting in places using less than this (4..8kB are common).
	Also, the header list is persistent per connection, so if we reach the same
	size as the request, that's another 16kB in each direction, resulting in
	about 48kB of memory where 8 were previously used. A more careful encoder
	can work with a much smaller set even if that implies evicting entries
	between multiple headers of the same message.

	- HTTP/1.0 should very carefully be transported over H2. Since there's no way
	to pass version information in the protocol, the server could use some
	features of HTTP/1.1 that are unsafe in HTTP/1.0 (compression, trailers,
	...).

	- host / :authority : ":authority" is the norm, and "host" will be absent when
	H2 clients generate :authority. This probably means that a dummy Host header
	will have to be produced internally from :authority and removed when passing
	to H2 behind. This can cause some trouble when passing H2 requests to H1
	proxies, because there's no way to know if the request should contain scheme
	and authority in H1 or not based on the H2 request. Thus a "proxy" option
	will have to be explicitly mentionned on HTTP/1 server lines. One of the
	problem that it creates is that it's not longer possible to pass H/1 requests
	to H/1 proxies without an explicit configuration. Maybe a table of the
	various combinations is needed.

	:scheme :authority host
	HTTP/2 request present present absent
	HTTP/1 server req absent absent present
	HTTP/1 proxy req present present present

	So in the end the issue is only with H/2 requests passed to H/1 proxies.

	- ping frames : they don't indicate any stream ID so by definition they cannot
	be forwarded to any server. The H2 connection should deal with them only.

	There's a layering problem with H2. The framing layer has to be aware of the
	upper layer semantics. We can't simply re-encode HTTP/1 to HTTP/2 then pass
	it over a framing layer to mux the streams, the frame type must be passed below
	so that frames are properly arranged. Header encoding is connection-based and
	all streams using the same connection will interact in the way their headers
	are encoded. Thus the encoder has to be placed in the h2_conn entity, and
	this entity has to know for each stream what its headers are.

	Probably that we should remove all headers from transported data and move
	them on the fly to a parallel structure that can be shared between H1 and H2
	and consumed at the appropriate level. That means buffers only transport data.
	Trailers have to be dealt with differently.

	So if we consider an H1 request being forwarded between a client and a server,
	it would look approximately like this :

	- request header + body land into a stream's receive buffer
	- headers are indexed and stripped out so that only the body and whatever
	follows remain in the buffer
	- both the header index and the buffer with the body stay attached to the
	stream
	- the sender can rebuild the whole headers. Since they're found in a table
	supposed to be stable, it can rebuild them as many times as desired and
	will always get the same result, so it's safe to build them into the trash
	buffer for immediate sending, just as we do for the PROXY protocol.
	- the upper protocol should probably provide a build_hdr() callback which
	when called by the socket layer, builds this header block based on the
	current stream's header list, ready to be sent.
	- the socket layer has to know how many bytes from the headers are left to be
	forwarded prior to processing the body.
	- the socket layer needs to consume only the acceptable part of the body and
	must not release the buffer if any data remains in it (eg: pipelining over
	H1). This is already handled by channel->o and channel->to_forward.
	- we could possibly have another optional callback to send a preamble before
	data, that could be used to send chunk sizes in H1. The danger is that it
	absolutely needs to be stable if it has to be retried. But it could
	considerably simplify de-chunking.

	When the request is sent to an H2 server, an H2 stream request must be made
	to the server, we find an existing connection whose settings are compatible
	with our needs (eg: tls/clear, push/no-push), and with a spare stream ID. If
	none is found, a new connection must be established, unless maxconn is reached.

	Servers must have a maxstream setting just like they have a maxconn. The same
	queue may be used for that.

	The "tcp-request content" ruleset must apply to the TCP layer. But with HTTP/2
	that becomes impossible (and useless). We still need something like the
	"tcp-request session" hook to apply just after the SSL handshake is done.

	It is impossible to defragment the body on the fly in HTTP/2. Since multiple
	messages are interleaved, we cannot wait for all of them and block the head of
	line. Thus if body analysis is required, it will have to use the stream's
	buffer, which necessarily implies a copy. That means that with each H2 end we
	necessarily have at least one copy. Sometimes we might be able to "splice" some
	bytes from one side to the other without copying into the stream buffer (same
	rules as for TCP splicing).

	In theory, only data should flow through the channel buffer, so each side's
	connector is responsible for encoding data (H1: linear/chunks, H2: frames).
	Maybe the same mechanism could be extrapolated to tunnels / TCP.

	Since we'd use buffers only for data (and for receipt of headers), we need to
	have dynamic buffer allocation.

	Thus :
	- Tx buffers do not exist. We allocate a buffer on the fly when we're ready to
	send something that we need to build and that needs to be persistent in case
	of partial send. H1 headers are built on the fly from the header table to a
	temporary buffer that is immediately sent and whose amount of sent bytes is
	the only information kept (like for PROXY protocol). H2 headers are more
	complex since the encoding depends on what was successfully sent. Thus we
	need to build them and put them into a temporary buffer that remains
	persistent in case send() fails. It is possible to have a limited pool of
	Tx buffers and refrain from sending if there is no more buffer available in
	the pool. In that case we need a wake-up mechanism once a buffer is
	available. Once the data are sent, the Tx buffer is then immediately recycled
	in its pool. Note that no tx buffer being used (eg: for hdr or control) means
	that we have to be able to serialize access to the connection and retry with
	the same stream. It also means that a stream that times out while waiting for
	the connector to read the second half of its request has to stay there, or at
	least needs to be handled gracefully. However if the connector cannot read
	the data to be sent, it means that the buffer is congested and the connection
	is dead, so that probably means it can be killed.

	- Rx buffers have to be pre-allocated just before calling recv(). A connection
	will first try to pick a buffer and disable reception if it fails, then
	subscribe to the list of tasks waiting for an Rx buffer.

	- full Rx buffers might sometimes be moved around to the next buffer instead of
	experiencing a copy. That means that channels and connectors must use the
	same format of buffer, and that only the channel will have to see its
	pointers adjusted.

	- Tx of data should be made as much as possible without copying. That possibly
	means by directly looking into the connection buffer on the other side if
	the local Tx buffer does not exist and the stream buffer is not allocated, or
	even performing a splice() call between the two sides. One of the problem in
	doing this is that it requires proper ordering of the operations (eg: when
	multiple readers are attached to a same buffer). If the splitting occurs upon
	receipt, there's no problem. If we expect to retrieve data directly from the
	original buffer, it's harder since it contains various things in an order
	which does not even indicate what belongs to whom. Thus possibly the only
	mechanism to implement is the buffer permutation which guarantees zero-copy
	and only in the 100% safe case. Also it's atomic and does not cause HOL
	blocking.

	It makes sense to chose the frontend_accept() function right after the
	handshake ended. It is then possible to check the ALPN, the SNI, the ciphers
	and to accept to switch to the h2_conn_accept handler only if everything is OK.
	The h2_conn_accept handler will have to deal with the connection setup,
	initialization of the header table, exchange of the settings frames and
	preparing whatever is needed to fire new streams upon receipt of unknown
	stream IDs. Note: most of the time it will not be possible to splice() because
	we need to know in advance the amount of bytes to write the header, and here it
	will not be possible.

	H2 health checks must be seen as regular transactions/streams. The check runs a
	normal client which seeks an available stream from a server. The server then
	finds one on an existing connection or initiates a new H2 connection. The H2
	checks will have to be configurable for sharing streams or not. Another option
	could be to specify how many requests can be made over existing connections
	before insisting on getting a separate connection. Note that such separate
	connections might end up stacking up once released. So probably that they need
	to be recycled very quickly (eg: fix how many unused ones can exist max).