Difference between revisions of "Example socket"
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− | {{todo| | + | {{todo|SEOKWREV (01.03.14-12:37->JG+);(01.03.14-14:00->MD+);(01.03.14-15:35->KY+);(04.07.14-10:10->BS+);(04.10.14-11:30->BS+)|Jgreene|project=oe 4,oe 5,jg,md,SEOKWREV,ky,bs}} |
+ | |||
+ | {{#seo: | ||
+ | |title=Example socket | ||
+ | |titlemode=append | ||
+ | |keywords=Example socket,Socket Server,Ethernet Network,Socket Client | ||
+ | |description=This is a guide to the <code>socket</code> C example project included in the EMAC OE SDK. | ||
+ | }} | ||
This is a guide to the <code>socket</code> C example project included in the EMAC OE SDK. | This is a guide to the <code>socket</code> C example project included in the EMAC OE SDK. | ||
− | This application | + | This application demonstrates how to set up sockets for host and client nodes on an ethernet network. |
The <code>socket</code> project builds one executable: <code>socket</code>. | The <code>socket</code> project builds one executable: <code>socket</code>. | ||
− | |||
== Opening, Building and Uploading the Project Files == | == Opening, Building and Uploading the Project Files == | ||
− | + | For information on opening the project from within Eclipse, please see [[Importing the EMAC OE SDK Projects with Eclipse]]. Then, follow [[Using the EMAC OE SDK Projects with Eclipse]] for information on how to build, upload and execute the example. | |
− | + | Alternatively, the <code>Makefile</code> can be used with the <code>make</code> command from the commandline to build and upload the example. For information on this method, please see [[Using EMAC OE SDK Example Projects]]. | |
− | + | ====EMAC SDK 5.X==== | |
− | + | For information on opening the project from within QtCreator, please see [[Getting_Started_With_Qt_Creator#Adding_Source_Files | QtCreator: Adding Source Files]]. Then, follow [[Getting Started With Qt Creator]] for information on how to build, upload and execute the example. | |
− | < | + | Alternatively, the <code>CMakefile.txt</code> can be used with the <code>cmake</code> command from the commandline to build and upload the example. For information on this method, please see [[Getting_Started_with_the_EMAC_OE_SDK#Target_Machine_Compiling | Getting Started with the EMAC OE SDK]]. |
− | |||
− | |||
− | |||
− | < | ||
− | |||
− | |||
+ | Code can be found at http://git.emacinc.com/OE/example-projects | ||
==Usage and Behavior== | ==Usage and Behavior== | ||
Line 32: | Line 33: | ||
===Using <code>socket</code>=== | ===Using <code>socket</code>=== | ||
− | + | ./socket -sc [ADDRESS] PORT | |
+ | |||
+ | ;-s:Create a ''server'', specify the PORT to listen to. | ||
+ | ;-c:Create a ''client'', specify the server's ADDRESS and PORT. | ||
+ | |||
+ | For our demonstration we create a ''server'' and a ''client''. Upon activation the server waits for a connection. Upon activation the client connects with the server. When the server detects the client's connection it sends a message to the client. Then the client sends that message right back to the server. The server compares the message it sent to the client with the message it just got from the client. If they match then we have performed a successful transmission. | ||
+ | |||
+ | ===Usage Example. One machine=== | ||
+ | |||
+ | We're going to create a ''server'' and ''client'' on the same machine. The machine will talk to itself. | ||
+ | |||
+ | Create the server | ||
+ | |||
+ | '''Note''' We're using port ''9999''. It's arbitrarily chosen and assumed to be free. | ||
+ | |||
+ | <syntaxhighlight lang="text"> | ||
+ | root@som9g20:/tmp# ./socket -s 9999 | ||
+ | |||
+ | Starting server | ||
+ | Making socket | ||
+ | Binding to port 9999opened socket as fd (3) on port (9999) for stream i/o | ||
+ | Server | ||
+ | sin_family = 2 | ||
+ | sin_addr.s_addr = 0 | ||
+ | sin_port = 9999 | ||
+ | |||
+ | Making a listen queue of 5 elements | ||
+ | Waiting for a connection | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | ...and it's waiting for a connection. Note that you can't do anything else in this console because it's occupied with the <code>socket</code> program. So open another console and, if necessary, log-on. | ||
+ | |||
+ | Create the client. | ||
+ | |||
+ | '''Note''' We're using port ''9999'', the same port for which the server is configured; and the localhost address: 127.0.0.1 | ||
+ | |||
+ | <syntaxhighlight lang="text"> | ||
+ | root@som9g20:/tmp# ./socket -c 127.0.0.1 9999 | ||
+ | |||
+ | Making a socket | ||
+ | Connecting to 127.0.0.1 on port 9999 | ||
+ | Received "Message from the socket server" from server | ||
+ | |||
+ | Writing "Message from the socket server" to server | ||
+ | Closing socket | ||
+ | </syntaxhighlight> | ||
+ | |||
+ | This is what happened: The server started up and waited for a connection. Then we started the client and it immediately connected to the server. The server noticed that connection and sent a message to the client: "Message from the socket server". The client received the message and sent it right back to the server. The server compared the two messages to check the accuracy of the transmission. The messages matched so the transmission was successful. | ||
+ | |||
+ | ===Usage Example. Two machines=== | ||
+ | |||
+ | Get 2 machines. In this example, a SoM9g20 and a SoM 9g45 are used. These machines will be referred to as ''MACHINE0'' and ''MACHINE1''.<br \> | ||
Compile and upload the <code>socket</code> executable to each of them.<br \> | Compile and upload the <code>socket</code> executable to each of them.<br \> | ||
Connect them both to the same ethernet network.<br \> | Connect them both to the same ethernet network.<br \> | ||
− | On MACHINE0 run the <code>socket</code> program | + | '''On MACHINE0 run the <code>socket</code> program.''' |
som9g45:/tmp# ./socket -s 9999 | som9g45:/tmp# ./socket -s 9999 | ||
− | Note that | + | Note that '''-s''' was specified, thus configuring MACHINE0 as a server. ''9999'' is an arbitrarily chosen (and assumed to be free) port address on the host machine. |
− | + | MACHINE0 has now been configured as a server and is waiting for a connection. | |
− | On MACHINE1 run the <code>socket</code> program | + | '''On MACHINE1, run the <code>socket</code> program.''' |
som9g20:/tmp# ./socket -c 10.0.2.204 9999 | som9g20:/tmp# ./socket -c 10.0.2.204 9999 | ||
− | Note that | + | Note that the '''-c''' argument was specified, thus configuring MACHINE1 as a '''client'''. ''10.0.2.204'' is the host machine's address (this will need to be determined. Use ''minicom'' or a similar terminal program). ''9999'' is the port address on the host machine. |
− | |||
− | |||
− | '''On MACHINE0 you will see something like this:''' | + | '''On MACHINE0, you will see something like this:''' |
− | <syntaxhighlight lang=" | + | <syntaxhighlight lang="text"> |
som9g45:/tmp# ./socket -s 9999 | som9g45:/tmp# ./socket -s 9999 | ||
Line 68: | Line 118: | ||
Closing the socket | Closing the socket | ||
Waiting for a connection | Waiting for a connection | ||
− | </syntaxhighlight | + | </syntaxhighlight> |
− | '''On MACHINE1 you will see something like this:''' | + | '''On MACHINE1, you will see something like this:''' |
− | <syntaxhighlight lang=" | + | <syntaxhighlight lang="text"> |
root@som9g20:/tmp# ./socket -c 10.0.2.204 9999 | root@som9g20:/tmp# ./socket -c 10.0.2.204 9999 | ||
Line 80: | Line 130: | ||
Writing "Message from the socket server" to server | Writing "Message from the socket server" to server | ||
Closing socket | Closing socket | ||
− | </syntaxhighlight"> | + | </syntaxhighlight> |
+ | |||
+ | This is what happened: MACHINE0 (the server) was configured as a server and waited for a connection. MACHINE1 (the client) connected to MACHINE0. MACHINE0 noticed the connection and sent a message to MACHINE1: "Message from the socket server". MACHINE1 received the message and sent it right back. MACHINE0 compared the two messages to check the accuracy of the transmission. The messages matched so the transmission was successful. | ||
+ | |||
+ | ==Summary== | ||
+ | The <code>socket</code> C example project demonstrates how to set up host and client node sockets on an ethernet network. |
Latest revision as of 13:22, 30 November 2022
This is a guide to the socket
C example project included in the EMAC OE SDK.
This application demonstrates how to set up sockets for host and client nodes on an ethernet network.
The socket
project builds one executable: socket
.
Contents
Opening, Building and Uploading the Project Files
For information on opening the project from within Eclipse, please see Importing the EMAC OE SDK Projects with Eclipse. Then, follow Using the EMAC OE SDK Projects with Eclipse for information on how to build, upload and execute the example.
Alternatively, the Makefile
can be used with the make
command from the commandline to build and upload the example. For information on this method, please see Using EMAC OE SDK Example Projects.
EMAC SDK 5.X
For information on opening the project from within QtCreator, please see QtCreator: Adding Source Files. Then, follow Getting Started With Qt Creator for information on how to build, upload and execute the example.
Alternatively, the CMakefile.txt
can be used with the cmake
command from the commandline to build and upload the example. For information on this method, please see Getting Started with the EMAC OE SDK.
Code can be found at http://git.emacinc.com/OE/example-projects
Usage and Behavior
Hardware Requirements
The socket
C example project will run just fine on any system for which it can be compiled.
Using socket
./socket -sc [ADDRESS] PORT
- -s
- Create a server, specify the PORT to listen to.
- -c
- Create a client, specify the server's ADDRESS and PORT.
For our demonstration we create a server and a client. Upon activation the server waits for a connection. Upon activation the client connects with the server. When the server detects the client's connection it sends a message to the client. Then the client sends that message right back to the server. The server compares the message it sent to the client with the message it just got from the client. If they match then we have performed a successful transmission.
Usage Example. One machine
We're going to create a server and client on the same machine. The machine will talk to itself.
Create the server
Note We're using port 9999. It's arbitrarily chosen and assumed to be free.
root@som9g20:/tmp# ./socket -s 9999
Starting server
Making socket
Binding to port 9999opened socket as fd (3) on port (9999) for stream i/o
Server
sin_family = 2
sin_addr.s_addr = 0
sin_port = 9999
Making a listen queue of 5 elements
Waiting for a connection
...and it's waiting for a connection. Note that you can't do anything else in this console because it's occupied with the socket
program. So open another console and, if necessary, log-on.
Create the client.
Note We're using port 9999, the same port for which the server is configured; and the localhost address: 127.0.0.1
root@som9g20:/tmp# ./socket -c 127.0.0.1 9999
Making a socket
Connecting to 127.0.0.1 on port 9999
Received "Message from the socket server" from server
Writing "Message from the socket server" to server
Closing socket
This is what happened: The server started up and waited for a connection. Then we started the client and it immediately connected to the server. The server noticed that connection and sent a message to the client: "Message from the socket server". The client received the message and sent it right back to the server. The server compared the two messages to check the accuracy of the transmission. The messages matched so the transmission was successful.
Usage Example. Two machines
Get 2 machines. In this example, a SoM9g20 and a SoM 9g45 are used. These machines will be referred to as MACHINE0 and MACHINE1.
Compile and upload the socket
executable to each of them.
Connect them both to the same ethernet network.
On MACHINE0 run the socket
program.
som9g45:/tmp# ./socket -s 9999
Note that -s was specified, thus configuring MACHINE0 as a server. 9999 is an arbitrarily chosen (and assumed to be free) port address on the host machine.
MACHINE0 has now been configured as a server and is waiting for a connection.
On MACHINE1, run the socket
program.
som9g20:/tmp# ./socket -c 10.0.2.204 9999
Note that the -c argument was specified, thus configuring MACHINE1 as a client. 10.0.2.204 is the host machine's address (this will need to be determined. Use minicom or a similar terminal program). 9999 is the port address on the host machine.
On MACHINE0, you will see something like this:
som9g45:/tmp# ./socket -s 9999
Starting server
Making socket
Binding to port 9999opened socket as fd (3) on port (9999) for stream i/o
Server
sin_family = 2
sin_addr.s_addr = 0
sin_port = 9999
Making a listen queue of 5 elements
Waiting for a connection
Got a connection
Sending "Message from the socket server" to client
The messages match
Closing the socket
Waiting for a connection
On MACHINE1, you will see something like this:
root@som9g20:/tmp# ./socket -c 10.0.2.204 9999
Making a socket
Connecting to 10.0.2.204 on port 9999
Received "Message from the socket server" from server
Writing "Message from the socket server" to server
Closing socket
This is what happened: MACHINE0 (the server) was configured as a server and waited for a connection. MACHINE1 (the client) connected to MACHINE0. MACHINE0 noticed the connection and sent a message to MACHINE1: "Message from the socket server". MACHINE1 received the message and sent it right back. MACHINE0 compared the two messages to check the accuracy of the transmission. The messages matched so the transmission was successful.
Summary
The socket
C example project demonstrates how to set up host and client node sockets on an ethernet network.