# HG changeset patch # User Gregory Szorc # Date 1535401844 25200 # Node ID b0e0db1565d1978d4c996316fbc6b6552f06eb5e # Parent 623081f2abc2c99dfa52344051976c5d33b63ee3 internals: extract frame-based protocol docs to own document wireprotocol.txt is quite long and difficult to digest. The frame-based protocol is effectively a standalone concept (and could even be used outside of Mercurial). So this commit extracts its docs to a standalone file. The first few paragraphs were rewritten as part of the extraction. Sections headers were adjusted accordingly. Existing referalls in wireprotocol.txt were updated to refer to the new doc / concept, which I've started referring to as `hgrpc`. I'm on the fence as to whether to move the HTTP and SSH transport details to the new doc as well. For now, I'm leaving them in wireprotocol.txt. Differential Revision: https://phab.mercurial-scm.org/D4443 diff -r 623081f2abc2 -r b0e0db1565d1 contrib/wix/help.wxs --- a/contrib/wix/help.wxs Wed Sep 12 22:19:29 2018 +0900 +++ b/contrib/wix/help.wxs Mon Aug 27 13:30:44 2018 -0700 @@ -51,6 +51,7 @@ + diff -r 623081f2abc2 -r b0e0db1565d1 mercurial/help/internals/wireprotocol.txt --- a/mercurial/help/internals/wireprotocol.txt Wed Sep 12 22:19:29 2018 +0900 +++ b/mercurial/help/internals/wireprotocol.txt Mon Aug 27 13:30:44 2018 -0700 @@ -220,9 +220,10 @@ Requests to unknown commands or URLS result in an HTTP 404. TODO formally define response type, how error is communicated, etc. -HTTP request and response bodies use the *Unified Frame-Based Protocol* -(defined below) for media exchange. The entirety of the HTTP message -body is 0 or more frames as defined by this protocol. +HTTP request and response bodies use the ``hgrpc`` protocol for media +exchange.` (See :hg:`help internals.wireprotocolrpc` for details of +the protocol.) The entirety of the HTTP message body is 0 or more frames +as defined by this protocol. Clients and servers MUST advertise the ``TBD`` media type via the ``Content-Type`` request and response headers. In addition, clients MUST @@ -236,11 +237,10 @@ Servers receiving requests with an invalid ``Content-Type`` header SHOULD respond with an HTTP 415. -The command to run is specified in the POST payload as defined by the -*Unified Frame-Based Protocol*. This is redundant with data already -encoded in the URL. This is by design, so server operators can have -better understanding about server activity from looking merely at -HTTP access logs. +The command to run is specified in the POST payload as defined by ``hgrpc``. +This is redundant with data already encoded in the URL. This is by design, +so server operators can have better understanding about server activity from +looking merely at HTTP access logs. In most circumstances, the command specified in the URL MUST match the command specified in the frame-based payload or the server will @@ -254,9 +254,9 @@ *any* command and allow the execution of multiple commands. If the HTTP request issues multiple commands across multiple frames, all issued commands will be processed by the server. Per the defined -behavior of the *Unified Frame-Based Protocol*, commands may be -issued interleaved and responses may come back in a different order -than they were issued. Clients MUST be able to deal with this. +behavior of ``hgrpc```, commands may be issued interleaved and responses +may come back in a different order than they were issued. Clients MUST +be able to deal with this. SSH Protocol ============ @@ -513,503 +513,6 @@ Following capabilities advertisement, the peers communicate using version 1 of the SSH transport. -Unified Frame-Based Protocol -============================ - -**Experimental and under development** - -The *Unified Frame-Based Protocol* is a communications protocol between -Mercurial peers. The protocol aims to be mostly transport agnostic -(works similarly on HTTP, SSH, etc). - -To operate the protocol, a bi-directional, half-duplex pipe supporting -ordered sends and receives is required. That is, each peer has one pipe -for sending data and another for receiving. - -All data is read and written in atomic units called *frames*. These -are conceptually similar to TCP packets. Higher-level functionality -is built on the exchange and processing of frames. - -All frames are associated with a *stream*. A *stream* provides a -unidirectional grouping of frames. Streams facilitate two goals: -content encoding and parallelism. There is a dedicated section on -streams below. - -The protocol is request-response based: the client issues requests to -the server, which issues replies to those requests. Server-initiated -messaging is not currently supported, but this specification carves -out room to implement it. - -All frames are associated with a numbered request. Frames can thus -be logically grouped by their request ID. - -Frames begin with an 8 octet header followed by a variable length -payload:: - - +------------------------------------------------+ - | Length (24) | - +--------------------------------+---------------+ - | Request ID (16) | Stream ID (8) | - +------------------+-------------+---------------+ - | Stream Flags (8) | - +-----------+------+ - | Type (4) | - +-----------+ - | Flags (4) | - +===========+===================================================| - | Frame Payload (0...) ... - +---------------------------------------------------------------+ - -The length of the frame payload is expressed as an unsigned 24 bit -little endian integer. Values larger than 65535 MUST NOT be used unless -given permission by the server as part of the negotiated capabilities -during the handshake. The frame header is not part of the advertised -frame length. The payload length is the over-the-wire length. If there -is content encoding applied to the payload as part of the frame's stream, -the length is the output of that content encoding, not the input. - -The 16-bit ``Request ID`` field denotes the integer request identifier, -stored as an unsigned little endian integer. Odd numbered requests are -client-initiated. Even numbered requests are server-initiated. This -refers to where the *request* was initiated - not where the *frame* was -initiated, so servers will send frames with odd ``Request ID`` in -response to client-initiated requests. Implementations are advised to -start ordering request identifiers at ``1`` and ``0``, increment by -``2``, and wrap around if all available numbers have been exhausted. - -The 8-bit ``Stream ID`` field denotes the stream that the frame is -associated with. Frames belonging to a stream may have content -encoding applied and the receiver may need to decode the raw frame -payload to obtain the original data. Odd numbered IDs are -client-initiated. Even numbered IDs are server-initiated. - -The 8-bit ``Stream Flags`` field defines stream processing semantics. -See the section on streams below. - -The 4-bit ``Type`` field denotes the type of frame being sent. - -The 4-bit ``Flags`` field defines special, per-type attributes for -the frame. - -The sections below define the frame types and their behavior. - -Command Request (``0x01``) --------------------------- - -This frame contains a request to run a command. - -The payload consists of a CBOR map defining the command request. The -bytestring keys of that map are: - -name - Name of the command that should be executed (bytestring). -args - Map of bytestring keys to various value types containing the named - arguments to this command. - - Each command defines its own set of argument names and their expected - types. - -This frame type MUST ONLY be sent from clients to servers: it is illegal -for a server to send this frame to a client. - -The following flag values are defined for this type: - -0x01 - New command request. When set, this frame represents the beginning - of a new request to run a command. The ``Request ID`` attached to this - frame MUST NOT be active. -0x02 - Command request continuation. When set, this frame is a continuation - from a previous command request frame for its ``Request ID``. This - flag is set when the CBOR data for a command request does not fit - in a single frame. -0x04 - Additional frames expected. When set, the command request didn't fit - into a single frame and additional CBOR data follows in a subsequent - frame. -0x08 - Command data frames expected. When set, command data frames are - expected to follow the final command request frame for this request. - -``0x01`` MUST be set on the initial command request frame for a -``Request ID``. - -``0x01`` or ``0x02`` MUST be set to indicate this frame's role in -a series of command request frames. - -If command data frames are to be sent, ``0x08`` MUST be set on ALL -command request frames. - -Command Data (``0x02``) ------------------------ - -This frame contains raw data for a command. - -Most commands can be executed by specifying arguments. However, -arguments have an upper bound to their length. For commands that -accept data that is beyond this length or whose length isn't known -when the command is initially sent, they will need to stream -arbitrary data to the server. This frame type facilitates the sending -of this data. - -The payload of this frame type consists of a stream of raw data to be -consumed by the command handler on the server. The format of the data -is command specific. - -The following flag values are defined for this type: - -0x01 - Command data continuation. When set, the data for this command - continues into a subsequent frame. - -0x02 - End of data. When set, command data has been fully sent to the - server. The command has been fully issued and no new data for this - command will be sent. The next frame will belong to a new command. - -Command Response Data (``0x03``) --------------------------------- - -This frame contains response data to an issued command. - -Response data ALWAYS consists of a series of 1 or more CBOR encoded -values. A CBOR value may be using indefinite length encoding. And the -bytes constituting the value may span several frames. - -The following flag values are defined for this type: - -0x01 - Data continuation. When set, an additional frame containing response data - will follow. -0x02 - End of data. When set, the response data has been fully sent and - no additional frames for this response will be sent. - -The ``0x01`` flag is mutually exclusive with the ``0x02`` flag. - -Error Occurred (``0x05``) -------------------------- - -Some kind of error occurred. - -There are 3 general kinds of failures that can occur: - -* Command error encountered before any response issued -* Command error encountered after a response was issued -* Protocol or stream level error - -This frame type is used to capture the latter cases. (The general -command error case is handled by the leading CBOR map in -``Command Response`` frames.) - -The payload of this frame contains a CBOR map detailing the error. That -map has the following bytestring keys: - -type - (bytestring) The overall type of error encountered. Can be one of the - following values: - - protocol - A protocol-level error occurred. This typically means someone - is violating the framing protocol semantics and the server is - refusing to proceed. - - server - A server-level error occurred. This typically indicates some kind of - logic error on the server, likely the fault of the server. - - command - A command-level error, likely the fault of the client. - -message - (array of maps) A richly formatted message that is intended for - human consumption. See the ``Human Output Side-Channel`` frame - section for a description of the format of this data structure. - -Human Output Side-Channel (``0x06``) ------------------------------------- - -This frame contains a message that is intended to be displayed to -people. Whereas most frames communicate machine readable data, this -frame communicates textual data that is intended to be shown to -humans. - -The frame consists of a series of *formatting requests*. Each formatting -request consists of a formatting string, arguments for that formatting -string, and labels to apply to that formatting string. - -A formatting string is a printf()-like string that allows variable -substitution within the string. Labels allow the rendered text to be -*decorated*. Assuming use of the canonical Mercurial code base, a -formatting string can be the input to the ``i18n._`` function. This -allows messages emitted from the server to be localized. So even if -the server has different i18n settings, people could see messages in -their *native* settings. Similarly, the use of labels allows -decorations like coloring and underlining to be applied using the -client's configured rendering settings. - -Formatting strings are similar to ``printf()`` strings or how -Python's ``%`` operator works. The only supported formatting sequences -are ``%s`` and ``%%``. ``%s`` will be replaced by whatever the string -at that position resolves to. ``%%`` will be replaced by ``%``. All -other 2-byte sequences beginning with ``%`` represent a literal -``%`` followed by that character. However, future versions of the -wire protocol reserve the right to allow clients to opt in to receiving -formatting strings with additional formatters, hence why ``%%`` is -required to represent the literal ``%``. - -The frame payload consists of a CBOR array of CBOR maps. Each map -defines an *atom* of text data to print. Each *atom* has the following -bytestring keys: - -msg - (bytestring) The formatting string. Content MUST be ASCII. -args (optional) - Array of bytestrings defining arguments to the formatting string. -labels (optional) - Array of bytestrings defining labels to apply to this atom. - -All data to be printed MUST be encoded into a single frame: this frame -does not support spanning data across multiple frames. - -All textual data encoded in these frames is assumed to be line delimited. -The last atom in the frame SHOULD end with a newline (``\n``). If it -doesn't, clients MAY add a newline to facilitate immediate printing. - -Progress Update (``0x07``) --------------------------- - -This frame holds the progress of an operation on the peer. Consumption -of these frames allows clients to display progress bars, estimated -completion times, etc. - -Each frame defines the progress of a single operation on the peer. The -payload consists of a CBOR map with the following bytestring keys: - -topic - Topic name (string) -pos - Current numeric position within the topic (integer) -total - Total/end numeric position of this topic (unsigned integer) -label (optional) - Unit label (string) -item (optional) - Item name (string) - -Progress state is created when a frame is received referencing a -*topic* that isn't currently tracked. Progress tracking for that -*topic* is finished when a frame is received reporting the current -position of that topic as ``-1``. - -Multiple *topics* may be active at any given time. - -Rendering of progress information is not mandated or governed by this -specification: implementations MAY render progress information however -they see fit, including not at all. - -The string data describing the topic SHOULD be static strings to -facilitate receivers localizing that string data. The emitter -MUST normalize all string data to valid UTF-8 and receivers SHOULD -validate that received data conforms to UTF-8. The topic name -SHOULD be ASCII. - -Stream Encoding Settings (``0x08``) ------------------------------------ - -This frame type holds information defining the content encoding -settings for a *stream*. - -This frame type is likely consumed by the protocol layer and is not -passed on to applications. - -This frame type MUST ONLY occur on frames having the *Beginning of Stream* -``Stream Flag`` set. - -The payload of this frame defines what content encoding has (possibly) -been applied to the payloads of subsequent frames in this stream. - -The payload begins with an 8-bit integer defining the length of the -encoding *profile*, followed by the string name of that profile, which -must be an ASCII string. All bytes that follow can be used by that -profile for supplemental settings definitions. See the section below -on defined encoding profiles. - -Stream States and Flags ------------------------ - -Streams can be in two states: *open* and *closed*. An *open* stream -is active and frames attached to that stream could arrive at any time. -A *closed* stream is not active. If a frame attached to a *closed* -stream arrives, that frame MUST have an appropriate stream flag -set indicating beginning of stream. All streams are in the *closed* -state by default. - -The ``Stream Flags`` field denotes a set of bit flags for defining -the relationship of this frame within a stream. The following flags -are defined: - -0x01 - Beginning of stream. The first frame in the stream MUST set this - flag. When received, the ``Stream ID`` this frame is attached to - becomes ``open``. - -0x02 - End of stream. The last frame in a stream MUST set this flag. When - received, the ``Stream ID`` this frame is attached to becomes - ``closed``. Any content encoding context associated with this stream - can be destroyed after processing the payload of this frame. - -0x04 - Apply content encoding. When set, any content encoding settings - defined by the stream should be applied when attempting to read - the frame. When not set, the frame payload isn't encoded. - -Streams -------- - -Streams - along with ``Request IDs`` - facilitate grouping of frames. -But the purpose of each is quite different and the groupings they -constitute are independent. - -A ``Request ID`` is essentially a tag. It tells you which logical -request a frame is associated with. - -A *stream* is a sequence of frames grouped for the express purpose -of applying a stateful encoding or for denoting sub-groups of frames. - -Unlike ``Request ID``s which span the request and response, a stream -is unidirectional and stream IDs are independent from client to -server. - -There is no strict hierarchical relationship between ``Request IDs`` -and *streams*. A stream can contain frames having multiple -``Request IDs``. Frames belonging to the same ``Request ID`` can -span multiple streams. - -One goal of streams is to facilitate content encoding. A stream can -define an encoding to be applied to frame payloads. For example, the -payload transmitted over the wire may contain output from a -zstandard compression operation and the receiving end may decompress -that payload to obtain the original data. - -The other goal of streams is to facilitate concurrent execution. For -example, a server could spawn 4 threads to service a request that can -be easily parallelized. Each of those 4 threads could write into its -own stream. Those streams could then in turn be delivered to 4 threads -on the receiving end, with each thread consuming its stream in near -isolation. The *main* thread on both ends merely does I/O and -encodes/decodes frame headers: the bulk of the work is done by worker -threads. - -In addition, since content encoding is defined per stream, each -*worker thread* could perform potentially CPU bound work concurrently -with other threads. This approach of applying encoding at the -sub-protocol / stream level eliminates a potential resource constraint -on the protocol stream as a whole (it is common for the throughput of -a compression engine to be smaller than the throughput of a network). - -Having multiple streams - each with their own encoding settings - also -facilitates the use of advanced data compression techniques. For -example, a transmitter could see that it is generating data faster -and slower than the receiving end is consuming it and adjust its -compression settings to trade CPU for compression ratio accordingly. - -While streams can define a content encoding, not all frames within -that stream must use that content encoding. This can be useful when -data is being served from caches and being derived dynamically. A -cache could pre-compressed data so the server doesn't have to -recompress it. The ability to pick and choose which frames are -compressed allows servers to easily send data to the wire without -involving potentially expensive encoding overhead. - -Content Encoding Profiles -------------------------- - -Streams can have named content encoding *profiles* associated with -them. A profile defines a shared understanding of content encoding -settings and behavior. - -The following profiles are defined: - -TBD - -Command Protocol ----------------- - -A client can request that a remote run a command by sending it -frames defining that command. This logical stream is composed of -1 or more ``Command Request`` frames and and 0 or more ``Command Data`` -frames. - -All frames composing a single command request MUST be associated with -the same ``Request ID``. - -Clients MAY send additional command requests without waiting on the -response to a previous command request. If they do so, they MUST ensure -that the ``Request ID`` field of outbound frames does not conflict -with that of an active ``Request ID`` whose response has not yet been -fully received. - -Servers MAY respond to commands in a different order than they were -sent over the wire. Clients MUST be prepared to deal with this. Servers -also MAY start executing commands in a different order than they were -received, or MAY execute multiple commands concurrently. - -If there is a dependency between commands or a race condition between -commands executing (e.g. a read-only command that depends on the results -of a command that mutates the repository), then clients MUST NOT send -frames issuing a command until a response to all dependent commands has -been received. -TODO think about whether we should express dependencies between commands -to avoid roundtrip latency. - -A command is defined by a command name, 0 or more command arguments, -and optional command data. - -Arguments are the recommended mechanism for transferring fixed sets of -parameters to a command. Data is appropriate for transferring variable -data. Thinking in terms of HTTP, arguments would be headers and data -would be the message body. - -It is recommended for servers to delay the dispatch of a command -until all argument have been received. Servers MAY impose limits on the -maximum argument size. -TODO define failure mechanism. - -Servers MAY dispatch to commands immediately once argument data -is available or delay until command data is received in full. - -Once a ``Command Request`` frame is sent, a client must be prepared to -receive any of the following frames associated with that request: -``Command Response``, ``Error Response``, ``Human Output Side-Channel``, -``Progress Update``. - -The *main* response for a command will be in ``Command Response`` frames. -The payloads of these frames consist of 1 or more CBOR encoded values. -The first CBOR value on the first ``Command Response`` frame is special -and denotes the overall status of the command. This CBOR map contains -the following bytestring keys: - -status - (bytestring) A well-defined message containing the overall status of - this command request. The following values are defined: - - ok - The command was received successfully and its response follows. - error - There was an error processing the command. More details about the - error are encoded in the ``error`` key. - -error (optional) - A map containing information about an encountered error. The map has the - following keys: - - message - (array of maps) A message describing the error. The message uses the - same format as those in the ``Human Output Side-Channel`` frame. - Capabilities ============ diff -r 623081f2abc2 -r b0e0db1565d1 mercurial/help/internals/wireprotocolrpc.txt --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/mercurial/help/internals/wireprotocolrpc.txt Mon Aug 27 13:30:44 2018 -0700 @@ -0,0 +1,516 @@ +**Experimental and under development** + +This document describe's Mercurial's transport-agnostic remote procedure +call (RPC) protocol which is used to perform interactions with remote +servers. This protocol is also referred to as ``hgrpc``. + +The protocol has the following high-level features: + +* Concurrent request and response support (multiple commands can be issued + simultaneously and responses can be streamed simultaneously). +* Supports half-duplex and full-duplex connections. +* All data is transmitted within *frames*, which have a well-defined + header and encode their length. +* Side-channels for sending progress updates and printing output. Text + output from the remote can be localized locally. +* Support for simultaneous and long-lived compression streams, even across + requests. +* Uses CBOR for data exchange. + +The protocol is not specific to Mercurial and could be used by other +applications. + +High-level Overview +=================== + +To operate the protocol, a bi-directional, half-duplex pipe supporting +ordered sends and receives is required. That is, each peer has one pipe +for sending data and another for receiving. Full-duplex pipes are also +supported. + +All data is read and written in atomic units called *frames*. These +are conceptually similar to TCP packets. Higher-level functionality +is built on the exchange and processing of frames. + +All frames are associated with a *stream*. A *stream* provides a +unidirectional grouping of frames. Streams facilitate two goals: +content encoding and parallelism. There is a dedicated section on +streams below. + +The protocol is request-response based: the client issues requests to +the server, which issues replies to those requests. Server-initiated +messaging is not currently supported, but this specification carves +out room to implement it. + +All frames are associated with a numbered request. Frames can thus +be logically grouped by their request ID. + +Frames +====== + +Frames begin with an 8 octet header followed by a variable length +payload:: + + +------------------------------------------------+ + | Length (24) | + +--------------------------------+---------------+ + | Request ID (16) | Stream ID (8) | + +------------------+-------------+---------------+ + | Stream Flags (8) | + +-----------+------+ + | Type (4) | + +-----------+ + | Flags (4) | + +===========+===================================================| + | Frame Payload (0...) ... + +---------------------------------------------------------------+ + +The length of the frame payload is expressed as an unsigned 24 bit +little endian integer. Values larger than 65535 MUST NOT be used unless +given permission by the server as part of the negotiated capabilities +during the handshake. The frame header is not part of the advertised +frame length. The payload length is the over-the-wire length. If there +is content encoding applied to the payload as part of the frame's stream, +the length is the output of that content encoding, not the input. + +The 16-bit ``Request ID`` field denotes the integer request identifier, +stored as an unsigned little endian integer. Odd numbered requests are +client-initiated. Even numbered requests are server-initiated. This +refers to where the *request* was initiated - not where the *frame* was +initiated, so servers will send frames with odd ``Request ID`` in +response to client-initiated requests. Implementations are advised to +start ordering request identifiers at ``1`` and ``0``, increment by +``2``, and wrap around if all available numbers have been exhausted. + +The 8-bit ``Stream ID`` field denotes the stream that the frame is +associated with. Frames belonging to a stream may have content +encoding applied and the receiver may need to decode the raw frame +payload to obtain the original data. Odd numbered IDs are +client-initiated. Even numbered IDs are server-initiated. + +The 8-bit ``Stream Flags`` field defines stream processing semantics. +See the section on streams below. + +The 4-bit ``Type`` field denotes the type of frame being sent. + +The 4-bit ``Flags`` field defines special, per-type attributes for +the frame. + +The sections below define the frame types and their behavior. + +Command Request (``0x01``) +-------------------------- + +This frame contains a request to run a command. + +The payload consists of a CBOR map defining the command request. The +bytestring keys of that map are: + +name + Name of the command that should be executed (bytestring). +args + Map of bytestring keys to various value types containing the named + arguments to this command. + + Each command defines its own set of argument names and their expected + types. + +This frame type MUST ONLY be sent from clients to servers: it is illegal +for a server to send this frame to a client. + +The following flag values are defined for this type: + +0x01 + New command request. When set, this frame represents the beginning + of a new request to run a command. The ``Request ID`` attached to this + frame MUST NOT be active. +0x02 + Command request continuation. When set, this frame is a continuation + from a previous command request frame for its ``Request ID``. This + flag is set when the CBOR data for a command request does not fit + in a single frame. +0x04 + Additional frames expected. When set, the command request didn't fit + into a single frame and additional CBOR data follows in a subsequent + frame. +0x08 + Command data frames expected. When set, command data frames are + expected to follow the final command request frame for this request. + +``0x01`` MUST be set on the initial command request frame for a +``Request ID``. + +``0x01`` or ``0x02`` MUST be set to indicate this frame's role in +a series of command request frames. + +If command data frames are to be sent, ``0x08`` MUST be set on ALL +command request frames. + +Command Data (``0x02``) +----------------------- + +This frame contains raw data for a command. + +Most commands can be executed by specifying arguments. However, +arguments have an upper bound to their length. For commands that +accept data that is beyond this length or whose length isn't known +when the command is initially sent, they will need to stream +arbitrary data to the server. This frame type facilitates the sending +of this data. + +The payload of this frame type consists of a stream of raw data to be +consumed by the command handler on the server. The format of the data +is command specific. + +The following flag values are defined for this type: + +0x01 + Command data continuation. When set, the data for this command + continues into a subsequent frame. + +0x02 + End of data. When set, command data has been fully sent to the + server. The command has been fully issued and no new data for this + command will be sent. The next frame will belong to a new command. + +Command Response Data (``0x03``) +-------------------------------- + +This frame contains response data to an issued command. + +Response data ALWAYS consists of a series of 1 or more CBOR encoded +values. A CBOR value may be using indefinite length encoding. And the +bytes constituting the value may span several frames. + +The following flag values are defined for this type: + +0x01 + Data continuation. When set, an additional frame containing response data + will follow. +0x02 + End of data. When set, the response data has been fully sent and + no additional frames for this response will be sent. + +The ``0x01`` flag is mutually exclusive with the ``0x02`` flag. + +Error Occurred (``0x05``) +------------------------- + +Some kind of error occurred. + +There are 3 general kinds of failures that can occur: + +* Command error encountered before any response issued +* Command error encountered after a response was issued +* Protocol or stream level error + +This frame type is used to capture the latter cases. (The general +command error case is handled by the leading CBOR map in +``Command Response`` frames.) + +The payload of this frame contains a CBOR map detailing the error. That +map has the following bytestring keys: + +type + (bytestring) The overall type of error encountered. Can be one of the + following values: + + protocol + A protocol-level error occurred. This typically means someone + is violating the framing protocol semantics and the server is + refusing to proceed. + + server + A server-level error occurred. This typically indicates some kind of + logic error on the server, likely the fault of the server. + + command + A command-level error, likely the fault of the client. + +message + (array of maps) A richly formatted message that is intended for + human consumption. See the ``Human Output Side-Channel`` frame + section for a description of the format of this data structure. + +Human Output Side-Channel (``0x06``) +------------------------------------ + +This frame contains a message that is intended to be displayed to +people. Whereas most frames communicate machine readable data, this +frame communicates textual data that is intended to be shown to +humans. + +The frame consists of a series of *formatting requests*. Each formatting +request consists of a formatting string, arguments for that formatting +string, and labels to apply to that formatting string. + +A formatting string is a printf()-like string that allows variable +substitution within the string. Labels allow the rendered text to be +*decorated*. Assuming use of the canonical Mercurial code base, a +formatting string can be the input to the ``i18n._`` function. This +allows messages emitted from the server to be localized. So even if +the server has different i18n settings, people could see messages in +their *native* settings. Similarly, the use of labels allows +decorations like coloring and underlining to be applied using the +client's configured rendering settings. + +Formatting strings are similar to ``printf()`` strings or how +Python's ``%`` operator works. The only supported formatting sequences +are ``%s`` and ``%%``. ``%s`` will be replaced by whatever the string +at that position resolves to. ``%%`` will be replaced by ``%``. All +other 2-byte sequences beginning with ``%`` represent a literal +``%`` followed by that character. However, future versions of the +wire protocol reserve the right to allow clients to opt in to receiving +formatting strings with additional formatters, hence why ``%%`` is +required to represent the literal ``%``. + +The frame payload consists of a CBOR array of CBOR maps. Each map +defines an *atom* of text data to print. Each *atom* has the following +bytestring keys: + +msg + (bytestring) The formatting string. Content MUST be ASCII. +args (optional) + Array of bytestrings defining arguments to the formatting string. +labels (optional) + Array of bytestrings defining labels to apply to this atom. + +All data to be printed MUST be encoded into a single frame: this frame +does not support spanning data across multiple frames. + +All textual data encoded in these frames is assumed to be line delimited. +The last atom in the frame SHOULD end with a newline (``\n``). If it +doesn't, clients MAY add a newline to facilitate immediate printing. + +Progress Update (``0x07``) +-------------------------- + +This frame holds the progress of an operation on the peer. Consumption +of these frames allows clients to display progress bars, estimated +completion times, etc. + +Each frame defines the progress of a single operation on the peer. The +payload consists of a CBOR map with the following bytestring keys: + +topic + Topic name (string) +pos + Current numeric position within the topic (integer) +total + Total/end numeric position of this topic (unsigned integer) +label (optional) + Unit label (string) +item (optional) + Item name (string) + +Progress state is created when a frame is received referencing a +*topic* that isn't currently tracked. Progress tracking for that +*topic* is finished when a frame is received reporting the current +position of that topic as ``-1``. + +Multiple *topics* may be active at any given time. + +Rendering of progress information is not mandated or governed by this +specification: implementations MAY render progress information however +they see fit, including not at all. + +The string data describing the topic SHOULD be static strings to +facilitate receivers localizing that string data. The emitter +MUST normalize all string data to valid UTF-8 and receivers SHOULD +validate that received data conforms to UTF-8. The topic name +SHOULD be ASCII. + +Stream Encoding Settings (``0x08``) +----------------------------------- + +This frame type holds information defining the content encoding +settings for a *stream*. + +This frame type is likely consumed by the protocol layer and is not +passed on to applications. + +This frame type MUST ONLY occur on frames having the *Beginning of Stream* +``Stream Flag`` set. + +The payload of this frame defines what content encoding has (possibly) +been applied to the payloads of subsequent frames in this stream. + +The payload begins with an 8-bit integer defining the length of the +encoding *profile*, followed by the string name of that profile, which +must be an ASCII string. All bytes that follow can be used by that +profile for supplemental settings definitions. See the section below +on defined encoding profiles. + +Stream States and Flags +======================= + +Streams can be in two states: *open* and *closed*. An *open* stream +is active and frames attached to that stream could arrive at any time. +A *closed* stream is not active. If a frame attached to a *closed* +stream arrives, that frame MUST have an appropriate stream flag +set indicating beginning of stream. All streams are in the *closed* +state by default. + +The ``Stream Flags`` field denotes a set of bit flags for defining +the relationship of this frame within a stream. The following flags +are defined: + +0x01 + Beginning of stream. The first frame in the stream MUST set this + flag. When received, the ``Stream ID`` this frame is attached to + becomes ``open``. + +0x02 + End of stream. The last frame in a stream MUST set this flag. When + received, the ``Stream ID`` this frame is attached to becomes + ``closed``. Any content encoding context associated with this stream + can be destroyed after processing the payload of this frame. + +0x04 + Apply content encoding. When set, any content encoding settings + defined by the stream should be applied when attempting to read + the frame. When not set, the frame payload isn't encoded. + +Streams +======= + +Streams - along with ``Request IDs`` - facilitate grouping of frames. +But the purpose of each is quite different and the groupings they +constitute are independent. + +A ``Request ID`` is essentially a tag. It tells you which logical +request a frame is associated with. + +A *stream* is a sequence of frames grouped for the express purpose +of applying a stateful encoding or for denoting sub-groups of frames. + +Unlike ``Request ID``s which span the request and response, a stream +is unidirectional and stream IDs are independent from client to +server. + +There is no strict hierarchical relationship between ``Request IDs`` +and *streams*. A stream can contain frames having multiple +``Request IDs``. Frames belonging to the same ``Request ID`` can +span multiple streams. + +One goal of streams is to facilitate content encoding. A stream can +define an encoding to be applied to frame payloads. For example, the +payload transmitted over the wire may contain output from a +zstandard compression operation and the receiving end may decompress +that payload to obtain the original data. + +The other goal of streams is to facilitate concurrent execution. For +example, a server could spawn 4 threads to service a request that can +be easily parallelized. Each of those 4 threads could write into its +own stream. Those streams could then in turn be delivered to 4 threads +on the receiving end, with each thread consuming its stream in near +isolation. The *main* thread on both ends merely does I/O and +encodes/decodes frame headers: the bulk of the work is done by worker +threads. + +In addition, since content encoding is defined per stream, each +*worker thread* could perform potentially CPU bound work concurrently +with other threads. This approach of applying encoding at the +sub-protocol / stream level eliminates a potential resource constraint +on the protocol stream as a whole (it is common for the throughput of +a compression engine to be smaller than the throughput of a network). + +Having multiple streams - each with their own encoding settings - also +facilitates the use of advanced data compression techniques. For +example, a transmitter could see that it is generating data faster +and slower than the receiving end is consuming it and adjust its +compression settings to trade CPU for compression ratio accordingly. + +While streams can define a content encoding, not all frames within +that stream must use that content encoding. This can be useful when +data is being served from caches and being derived dynamically. A +cache could pre-compressed data so the server doesn't have to +recompress it. The ability to pick and choose which frames are +compressed allows servers to easily send data to the wire without +involving potentially expensive encoding overhead. + +Content Encoding Profiles +========================= + +Streams can have named content encoding *profiles* associated with +them. A profile defines a shared understanding of content encoding +settings and behavior. + +The following profiles are defined: + +TBD + +Command Protocol +================ + +A client can request that a remote run a command by sending it +frames defining that command. This logical stream is composed of +1 or more ``Command Request`` frames and and 0 or more ``Command Data`` +frames. + +All frames composing a single command request MUST be associated with +the same ``Request ID``. + +Clients MAY send additional command requests without waiting on the +response to a previous command request. If they do so, they MUST ensure +that the ``Request ID`` field of outbound frames does not conflict +with that of an active ``Request ID`` whose response has not yet been +fully received. + +Servers MAY respond to commands in a different order than they were +sent over the wire. Clients MUST be prepared to deal with this. Servers +also MAY start executing commands in a different order than they were +received, or MAY execute multiple commands concurrently. + +If there is a dependency between commands or a race condition between +commands executing (e.g. a read-only command that depends on the results +of a command that mutates the repository), then clients MUST NOT send +frames issuing a command until a response to all dependent commands has +been received. +TODO think about whether we should express dependencies between commands +to avoid roundtrip latency. + +A command is defined by a command name, 0 or more command arguments, +and optional command data. + +Arguments are the recommended mechanism for transferring fixed sets of +parameters to a command. Data is appropriate for transferring variable +data. Thinking in terms of HTTP, arguments would be headers and data +would be the message body. + +It is recommended for servers to delay the dispatch of a command +until all argument have been received. Servers MAY impose limits on the +maximum argument size. +TODO define failure mechanism. + +Servers MAY dispatch to commands immediately once argument data +is available or delay until command data is received in full. + +Once a ``Command Request`` frame is sent, a client must be prepared to +receive any of the following frames associated with that request: +``Command Response``, ``Error Response``, ``Human Output Side-Channel``, +``Progress Update``. + +The *main* response for a command will be in ``Command Response`` frames. +The payloads of these frames consist of 1 or more CBOR encoded values. +The first CBOR value on the first ``Command Response`` frame is special +and denotes the overall status of the command. This CBOR map contains +the following bytestring keys: + +status + (bytestring) A well-defined message containing the overall status of + this command request. The following values are defined: + + ok + The command was received successfully and its response follows. + error + There was an error processing the command. More details about the + error are encoded in the ``error`` key. + +error (optional) + A map containing information about an encountered error. The map has the + following keys: + + message + (array of maps) A message describing the error. The message uses the + same format as those in the ``Human Output Side-Channel`` frame.