A tool for building protocol services
Project description
PolyPacket
Poly Packet is backend and code generation tool for creating messaging protocols/Services. Protocols are described in an YAML document which can be easily shared with all components of a system.
A python script is used to parse the YAML file and generate code as well as documentation. The code generation tool can create the back end service, app layer, and even an entire linux utility app
Protocol Generation
Protocols are generated using YAML. The messaging structure is made up 4 entity types:
- Field
- Packet
- Val
- Struct
Fields
A field is a data object within a packet. These can be expressed either as nested yaml, or an inline dictionary
Example fields:
fields:
- sensorA: { type: int16 ,desc: Value of Sensor A}
- sensorB:
type: int
format: hex
desc: Value of Sensor B
- sensorsC_Z:
type: int*24
desc: Values for remaining 24 sensors
type: The data type for the field. *n indicates it is an array with a max size of n
format: (optional) This sets the display format used for the toString and toJsonString methods [ hex , dec , assci ]
desc: (optional) The description of the field. This is used to create the documentation
Fields can be nested into 'Field Groups' for convenience
fields:
- header:
- src: {type: uint16, desc: Address of node sending message }
- dst: {type: uint16, desc: Address of node to receive message }
Note these will be added to the packet as regular fields. The grouping is just for convenience
Packets
A Packet describes an entire message and is made up of fields
example Packet:
packets:
- Data:
desc: contains data from a sensor
fields:
- sensorA
- sensorB
- sensorName
name: The name of the packet
desc: (optional) description of the packet for documentation
response: (optional) name of the packet type expected in response to this message (if any)
within the packet we reference Fields which have already been declared in the Fields section. these references contain 3 attributes:
name: The name of the field
req: (optional) makes the field a requirement for this packet type
desc: (optional) description of this field for this packet type, will override fields description in the documentation for this packet type only
Val
Val entities are used for defining options in enum and flags fields.
fields:
- cmd:
type: enum
format: hex
desc: command byte for controlling node
vals:
- led_ON: { desc: turns on led}
- led_OFF: { desc: turns off led}
- reset: { desc: resets device }
In this example an enum is used to set up some predefined options for the cmd field. enums are created with sequential values starting at 0. a flags field is defined in the same way, but instead of sequential numbers, it shifts bits to the left, to create a group of individually set-able flags.
Struct
Structs are essentially the same thing as packets in that they are a collection of fields. The only real difference is the name, and that the code generation tool will create classes for structs.
structs:
- Node:
desc: struct for modeling node
field:
- sensorA
- sensorB
- sensorName
The idea being that a Struct will hold data locally, and can be easily updated from a message. Any packet can be copied to another packet using the packet copy funtion. this function can be used with any 2 packets/structs but will only copy the fields that have in common:
sp_struct_t thisNode; //must be initialized with sp_struct_build(&thisNode, SP_STRUCT_NODE);
HandlerStatus_e sp_Data_handler(sp_packet_t* sp_data)
{
sp_packet_copy(&thisNode, sf_data); //update thisNode from incoming data packet
return PACKET_HANDLED;
}
HandlerStatus_e sp_GetData_handler(sp_packet_t* sp_getData, sp_packet_t* sp_data)
{
sp_packet_copy( sp_data, &thisNode); //update data packet with fields from thisNode
return PACKET_HANDLED;
}
sp is just the prefix for the sample protocol
Example:
The following example show the YAML for a simple message protocol.
---
name: sample
prefix: sp
desc: This is a sample protocol made up to demonstrate features of the PolyPacket
code generation tool. The idea is to have a tool that can automatically create parseable/serializable
messaging for embedded systems
###########################################################################################################
# FIELDS #
###########################################################################################################
fields:
- sensorA: { type: int16 ,desc: Value of Sensor A}
- sensorB:
type: int
desc: Value of Sensor B
- sensorName:
type: string
desc: Name of sensor
- cmd:
type: enum
format: hex
desc: command byte for controlling node
vals:
- led_ON: { desc: turns on led}
- led_OFF: { desc: turns off led}
- reset: { desc: resets device }
###########################################################################################################
# Packets #
###########################################################################################################
packets:
- SendCmd:
desc: Message to send command to node
fields:
- cmd
- GetData:
desc: Message tp get data from node
response: Data
- Data:
desc: contains data from a sensor
fields:
- sensorA
- sensorB
- sensorName
###########################################################################################################
# Structs #
###########################################################################################################
structs:
- Node:
desc: struct for modeling node
field:
- sensorA
- sensorB
- sensorName
The YAML sets up 3 Fields:
cmd - Command for device
sensorA - Value of Sensor A
sensorB - Value of Sensor B
sensorName - Name of sensor
It then lists the packets, and which fields are in each packet. fields are considered optional in a packet unless specified with req="true". So in this example you could send a Data packet that only contained sensorB and sensorName.
Using Poly Packet
To use poly packet, write your YAML to define the fields and packets in your protocol. Then use poly-make to generate the source code, or poly-packet to run the an interactive interface with the protocol
poly-packet
the poly-packet tool can be used to test a protocol, or just as a utility for existing devices. The tool features auto-complete and you can get a list of options with 'tab'
terminal 1: int the first terminal open the tool and then connect to port 8000
poly-packet -i sample_protocol.yml -c connect udp:8000
terminal 2: on the second, open port 8001 and connect to 8000. To send a packet, type the name of the packet and then fill in the fields (make sure to use separating commas)
poly-packet -i sample_protocol.yml -c connect udp:8001:8000
#then from the poly-packet terminal:
Data sensorA: 89 , sensorB: 87 , sensorName: test name
poly-make
poly-make is the tool that will turn the yaml description into c code for projects.
The easiest way to get familiar is to generate a utility. This will create an entire cmake project, and is a good starting point:
poly-make -i sample_protocol.yml -u sample_util
## To buil/run:
cd sample_util/build
cmake ..
make
./sample_util
If you would rather just create the service code and/or application layer in an existing project you can use:
poly-make -i sample_protocol.yml -o . -a
- -i is for input file, this will be the YAML file used
- -o is the output directory, this is where the code and documentation will be generated
- -a tells the tool to create an application layer for you. This is just skeleton code with all of the packet handlers and initialization code
- -u specifies a path to create a standalone serial utility for the service
by default all functions will start with the prefix 'pp'. but the 'prefix' attribute can be used in the YAML to set a different prefix. this allows the use of multiple services/protocols in a single project without conflict
Using Generated Code
This example shows how to use the code to create a service. The service is initialized with 1 interface:
Initializing service
sp_service_init(1); //initialize the service with 1 interface
For devices where multiple hardware ports are being used by the same protocol, you can use more interfaces
Register Tx functions
For each interface we need to register a send function. This allows us the service to handle the actual sending so we can automate things like acknowledgements and retries. There are two types of send callbacks that can be registered:
typedef HandlerStatus_e (*poly_tx_byte_callback)(uint8_t* data , int len);
typedef HandlerStatus_e (*poly_tx_packet_callback)(poly_packet_t* packet );
The tx_byte callback will pass the packet as an array of COBS encoded bytes which can be sent directly over a serial connection. The tx_packet will pass a reference to the packet itself which can be converted to JSON, or manipulated before sending.
sp_service_register_tx_bytes(0, &uart_send ); // register sending function for raw bytes
sp_service_register_tx_packet(0, &json_send ); // register sending function for entire packet
once we have registered a callback for an interface, we can send messages to it using the quick send functions generated for the service.
sp_sendGetData();
Feed the service
The underlying service is responsible for packing and parsing the data. So wherever you read bytes off of the hardware interface, just feed them to the service.
Encoded Bytes
void uart_rx_handler(uint8_t* data, int len)
{
sp_service_feed(0,datam len);
}
If you are working with JSON you have two options. you can feed the json message to the service for normal handling or call the json handler to bypass the normal service queue. This option make it easy to use the service in synchronous tasks such as responding to an http request
Async JSON
void app_json_async_handler(char* strJson, int len)
{
sp_service_feed_json(0,strJson, len);
}
Sync JSON
void app_json_sync_handler(const char* strRequest, int len, char* strResp)
{
HandlerStatus_e status;
status = sp_handle_json(strRequest, len, strResp);
}
From here the service will take care of parsing the data and dispatching messages to the proper message handler.
Sending messages
The service creates one-liner functions for easily sending simple messages
Using the example protocol we can send a message to get data from a remote device on interface 0 with:
sp_sendGetData(0);
for packet types with data fields, the datafields get turned into the arguments for the function
sp_sendData(0, 97, 98, "My Sensor name");
Creating a message (Be sure to clean after)
If for some reason you need to build your own message, you can do that as well, but be sure to clean it when you are done.
sp_packet_t msg;
sp_packet_init(&msg,SP_SETDATA_PACKET);
next we set fields in the message
sp_setSrc(msg,0xABCD );
sp_setDst(msg,0xCDEF);
sp_send(0,&msg);
When creating your own packets, make sure they are cleaned up after
sp_clean(&msg);
Receive Handlers
The generated service creates a handler for each packet type, they are created with weak attributes, so they can be overridden by just declaring them again in our code. If you specify a response for a packet in the YAML, the generated handler will have a pointer to responding packet. As long as the handler returns 'PACKET_HANDLED', the service will send the reply. If no reponse is specified the service will send an 'Ack' packet
The following is our handler for 'SetData' type packets
/**
*@brief Handler for receiving GetData packets
*@param GetData incoming GetData packet
*@param Data Data packet to respond with
*@return handling status
*/
HandlerStatus_e sp_GetData_handler(sp_packet_t* sp_GetData, sp_packet_t* sp_Data)
{
sp_setSensorA(sp_Data, 97);
sp_setSensorB(sp_Data, 98);
sp_setSensorName(sp_Data, "My sensor");
return PACKET_HANDLED;
}
Process
The service is meant to be run on many platforms, so it does not have built in threading/tasking. For it to continue handling messages, we have to call its process function either in a thread/task or in our super-loop
while(1)
{
sp_service_process();
}
Project details
Release history Release notifications | RSS feed
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.