mirror of https://github.com/Desuuuu/klipper.git
docs: Add Protocol.md with information on host / firmware communication
Signed-off-by: Kevin O'Connor <kevin@koconnor.net>
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@ -4,6 +4,9 @@ installing, and running Klipper.
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See [code overview](Code_Overview.md) for developer information on the
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structure and layout of the Klipper code.
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See [protocol](Protocol.md) for developer information on the messaging
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protocol between host and firmware.
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See [debugging](Debugging.md) for developer information on how to test
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and debug Klipper.
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@ -0,0 +1,296 @@
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Klipper uses a binary protocol for communication between host and
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firmware. This page provides a high-level description of that
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protocol.
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The goal of the protocol is to enable an error-free communication
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channel between the host and firmware that is low-latency,
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low-bandwidth, and low-complexity for the firmware.
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The protocol acts as a
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[RPC](https://en.wikipedia.org/wiki/Remote_procedure_call) mechanism
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between firmware and host. The firmware declares the commands that the
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host may invoke along with the response messages that it can
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generate. The host uses that information to command the firmware to
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perform actions and to interpret the results.
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Firmware Interface
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==================
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Declaring commands
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------------------
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The firmware declares a "command" by using the DECL_COMMAND() macro in
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the C code. For example:
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```
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DECL_COMMAND(command_set_digital_out, "set_digital_out pin=%u value=%c");
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```
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The above declares a command named "set_digital_out". This allows the
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host to "invoke" this command which would cause the
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command_set_digital_out() C function will be executed in the
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firmware. The above also indicates that the command takes two integer
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parameters. When the command_set_digital_out() C code is executed, it
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will be passed an array containing these two integers - the first
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corresponding to the 'pin' and the second corresponding to the
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'value'.
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In general, the parameters are described with printf() style
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parameters (eg, "%u"). In the above example, "value=" is a parameter
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name and "%c" indicates the parameter is an integer. The parameter
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name is used as documentation. In this example, the "%c" is used as
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documentation to indicate the expected integer is 1 byte in size (the
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declared integer size does not impact the parsing or encoding).
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At firmware compile time, the build will collect all commands declared
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with DECL_COMMAND(), determine their parameters, and arrange for them
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to be callable.
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Declaring responses
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-------------------
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To send information from the firmware to the host a "response" is
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generated. These are both declared and transmitted using the sendf() C
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macro. For example:
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```
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sendf("status clock=%u status=%c", sched_read_time(), sched_is_shutdown());
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```
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The above transmits a "status" response message that contains two
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integer parameters ("clock" and "status"). At firmware compile time
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the build automatically finds all sendf() calls and generates encoders
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for them. The first parameter of the sendf() function describes the
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response and it is in the same format as command declarations.
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The host can arrange to register a callback function for each
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response. So, in effect, commands allow the host to invoke C functions
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in the firmware and responses allow the firmware to invoke code in the
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host.
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The firmware should only invoke sendf() from command or task handlers,
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and it should not be invoked from interrupts or timers. The firmware
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does not need to issue a sendf() from a command, it is not limited in
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the number of times sendf() may be invoked, and it may invoke sendf()
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at any time from a task handler.
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### Output responses
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To simplify debugging, the firmware also has an output() C
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function. For example:
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```
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output("The value of %u is %s with size %u.", x, buf, buf_len);
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```
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The output() function is similar in usage to printf() - it is intended
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to generate and format arbitrary messages for human consumption. It is
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a wrapper around sendf() and as with sendf() it should not be called
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from interrupts or timers.
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Low-level message encoding
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==========================
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To accomplish the above RPC mechanism, each command and response is
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encoded into a binary format for transmission. This section describes
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the transmission system.
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Message Blocks
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--------------
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All data sent from host to firmware and vice-versa are contained in
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"message blocks". A message block has a two byte header and a three
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byte trailer. The format of a message block is:
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```
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<1 byte length><1 byte sequence><n-byte content><2 byte crc><1 byte sync>
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```
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The length byte contains the number of bytes in the message block
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including the header and trailer bytes (thus the minimum message
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length is 5 bytes). The maximum message block length is currently 64
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bytes. The sequence byte contains a 4 bit sequence number in the
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low-order bits and the high-order bits always contain 0x10 (the
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high-order bits are reserved for future use). The content bytes
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contain arbitrary data and its format is described in the following
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section. The crc bytes contain a 16bit CCITT
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[CRC](https://en.wikipedia.org/wiki/Cyclic_redundancy_check) of the
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message block including the header bytes but excluding the trailer
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bytes. The sync byte is 0x7e.
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The format of the message block is inspired by
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[HDLC](https://en.wikipedia.org/wiki/High-Level_Data_Link_Control)
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message frames. Like in HDLC, the message block may optionally contain
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an additional sync character at the start of the block. Unlike in
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HDLC, a sync character is not exclusive to the framing and may be
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present in the message block content.
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Message Block Contents
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----------------------
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Each message block sent from host to firmware contains a series of
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zero or more message commands in its contents. Each command starts
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with a Variable Length Quantity (VLQ) encoded command-id followed by
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zero or more VLQ parameters for the given command. So, the contents of
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an example message block might look like:
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```
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<id_cmd_a><param1><id_cmd_b><param1><param2><id_cmd_c><id_cmd_d>
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```
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In order to encode and parse the message contents, both the host and
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firmware must agree on a "data dictionary". The data dictionary
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associates high-level commands with specific integer command-ids along
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with the number of parameters that the command takes. When processing
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the data, the parser will know to expect a specific number of VLQ
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encoded parameters following a given command. So, in the above
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example, both the host and firmware would know that "id_cmd_a" is
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always followed by exactly one parameter, "id_cmd_b" two parameters,
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and "id_cmd_c" / "id_cmd_d" zero parameters.
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The message contents for blocks sent from firmware to host follow the
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same format. The identifiers in these messages are "response ids", but
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they serve the same purpose and follow the same encoding rules. In
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practice, message blocks sent from the firmware to the host never
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contain more than one response in the message block contents.
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### Variable Length Quantities
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See the [wikipedia article](https://en.wikipedia.org/wiki/Variable-length_quantity)
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for more information on the general format of VLQ encoded
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integers. Klipper uses an encoding scheme that supports both positive
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and negative integers. Integers close to zero use less bytes to encode
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and positive integers typically encode using less bytes than negative
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integers. The following table shows the number of bytes each integer
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takes to encode:
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| Integer | Encoded size |
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|---------------------------|--------------|
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| -32 .. 95 | 1 |
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| -4096 .. 12287 | 2 |
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| -524288 .. 1572863 | 3 |
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| -67108864 .. 201326591 | 4 |
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| -2147483648 .. 4294967295 | 5 |
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### Variable length strings
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As an exception to the above encoding rules, if a parameter to a
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command or response is a dynamic string then the parameter is not
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encoded as a simple VLQ integer. Instead it is encoded by transmitting
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the length as a VLQ encoded integer followed by the contents itself:
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```
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<VLQ encoded length><n-byte contents>
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```
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The data dictionary includes information on each parameter so that
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both the host and firmware know which command parameters use simple
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VLQ encoding and which parameters use string encoding.
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Data Dictionary
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===============
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In order for meaningful communications to be established between
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firmware and host, both sides must agree on a "data dictionary". This
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data dictionary contains the integer identifiers for commands and
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responses along with the number of parameters and the types of
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parameters for each command/response.
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At compile time the firmware build uses the contents of DECL_COMMAND()
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and sendf() macros to generate the data dictionary. The build
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automatically assigns unique identifiers to each command and
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response. The data dictionary maps the high-level names (eg,
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"get_status") to the integer command ids. This allows the host and
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firmware to use descriptive ASCII names while still using minimal
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bandwidth.
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The host queries the data dictionary when it first connects to the
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firmware. Once the host downloads the data dictionary from the
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firmware, it uses that data dictionary to encode all commands and to
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parse all responses from the firmware. The host must therefore handle
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a dynamic data dictionary. However, to keep the firmware simple, the
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firmware always uses its static (compiled in) data dictionary.
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The data dictionary is queried by sending "identify" commands to the
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firmware. The firmware will respond to each identify command with an
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"identify_response" message. Since these two commands are needed prior
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to obtaining the data dictionary, their integer ids and parameter
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types are hard-coded in both the firmware and the host. The
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"identify_response" response id is 0, the "identify" command id
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is 1. Other than having hard-coded ids the identify command and its
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response are declared and transmitted the same way as other commands
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and responses. No other command or response is hard-coded.
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The format of the transmitted data dictionary itself is a zlib
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compressed JSON string. The firmware compile process generates the
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string, compresses it, and stores it in the text section of the
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firmware. The data dictionary can be much larger than the maximum
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message block size - the host downloads it by sending multiple
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identify commands requesting progressive chunks of the data
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dictionary. Once all chunks are obtained the host will assemble the
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chunks, uncompress the data, and parse the contents.
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In addition to information on the communication protocol, the data
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dictionary also contains firmware version, configuration, and other
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useful information.
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Static Strings
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--------------
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To reduce bandwidth the data dictionary also contains a set of static
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strings known to the firmware. This is useful when sending messages
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from firmware to host. For example, if the firmware were to run:
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```
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shutdown("Unable to handle command");
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```
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The error message can be encoded and sent using a single VLQ. The host
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uses the data dictionary to resolve the VLQ encoded static string id
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to the associated message in the data dictionary.
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Message flow
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============
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Message commands sent from host to firmware are intended to be
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error-free. The firmware will check the CRC and sequence numbers in
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each message block to ensure the commands are accurate and
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in-order. The firmware always processes message blocks in-order -
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should it receive a block out-of-order it will discard it and any
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other out-of-order blocks until it receives blocks with the correct
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sequencing.
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The low-level host code implements an automatic retransmission system
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for lost and corrupt message blocks sent to the firmware. To
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facilitate this, the firmware transmits an "ack message block" after
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each successfully received message block. The host schedules a timeout
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after sending each block and it will retransmit should the timeout
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expire without receiving a corresponding "ack". In addition, if the
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firmware detects a corrupt or out-of-order block it may transmit a
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"nak message block" to facilitate fast retransmission.
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An "ack" is a message block with empty content (ie, a 5 byte message
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block) and a sequence number greater than the last received host
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sequence number. A "nak" is a message block with empty content and a
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sequence number less than the last received host sequence number.
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The protocol facilitates a "window" transmission system so that the
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host can have many outstanding message blocks in-flight at a
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time. (This is in addition to the many commands that may be present in
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a given message block.) This allows maximum bandwidth utilization even
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in the event of transmission latency. The timeout, retransmit,
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windowing, and ack mechanism are inspired by similar mechanisms in
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[TCP](https://en.wikipedia.org/wiki/Transmission_Control_Protocol).
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In the other direction, message blocks sent from firmware to host are
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designed to be error-free, but they do not have assured
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transmission. (Responses should not be corrupt, but they may go
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missing.) This is done to keep the implementation in the firmware
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simple. There is no automatic retransmission system for responses -
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the high-level code is expected to be capable of handling an
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occasional missing response (usually by re-requesting the content or
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setting up a recurring schedule of response transmission). The
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sequence number field in message blocks sent to the host is always one
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greater than the last received sequence number of message blocks
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received from the host. It is not used to track sequences of response
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message blocks.
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