This repository contains the starter code for project 1 (15-440, Fall 2017). It also contains
the tests that we will use to grade your implementation, and two simple echo server/client
(srunner
and crunner
, respectively) programs that you might find useful for your own testing
purposes. These instructions assume you have set your GOPATH
to point to the repository's
root p1/
directory.
If at any point you have any trouble with building, installing, or testing your code, the article
titled How to Write Go Code is a great resource for understanding
how Go workspaces are built and organized. You might also find the documentation for the
go
command to be helpful. As always, feel free to post your questions
on Piazza.
This project was designed for, and tested on AFS cluster machines, though you may choose to write and build your code locally as well.
To make testing your server a bit easier we have provided two simple echo server/client
programs called srunner
and crunner
. If you look at the source code for the two programs,
you’ll notice that they import the github.com/cmu440/lsp
package (in other words, they compile
against the current state of your LSP implementation). We believe you will find these programs
useful in the early stages of development when your client and server implementations are
largely incomplete.
To compile, build, and run these programs, use the go run
command from inside the directory
storing the file (these instructions assume your GOPATH
is pointing to the project’s root
p1/
directory):
go run srunner.go
The srunner
and crunner
programs may be customized using command line flags. For more
information, specify the -h
flag at the command line. For example,
$ go run srunner.go -h
Usage of bin/srunner:
-elim=5: epoch limit
-ems=2000: epoch duration (ms)
-port=9999: port number
-rdrop=0: network read drop percent
-v=false: show srunner logs
-wdrop=0: network write drop percent
-wsize=1: window size
-maxBackoff: maximum interval epoch
We have also provided pre-compiled executables for you to use called srunner-sols
and crunner-sols
.
These binaries were compiled against our reference LSP implementation,
so you might find them useful in the early stages of the development process (for example, if you wanted to test your
Client
implementation but haven’t finished implementing the Server
yet, etc.). Two separate binaries
are provided for Linux and Mac OS X machines (Windows is not supported at this time).
As an example, to start an echo server on port 6060
on an AFS cluster machine, execute the following command:
$GOPATH/bin/linux_amd64/srunner-sols -port=6060
To test your submission, we will execute the following command from inside the
p1/src/github.com/cmu440/lsp
directory for each of the tests (where TestName
is the
name of one of the 44 test cases, such as TestBasic6
or TestWindow1
):
go test -run=TestName
Note that we will execute each test individually using the -run
flag and by specify a regular expression
identifying the name of the test to run. To ensure that previous tests don’t affect the outcome of later tests,
we recommend executing the tests individually (or in small batches, such as go test -run=TestBasic
which will
execute all tests beginning with TestBasic
) as opposed to all together using go test
.
On some tests, we will also check your code for race conditions using Go’s race detector:
go test -race -run=TestName
We have also provided Autolab test scripts mocks in sh/
. When you are inside the
p1/src/github.com/cmu440/lsp
directory and execute corresponding script, you can have a rough sense of what your
score should be like on Autolab.
As with project 0, we will be using Autolab to grade your submissions for this project. We will run some—but not all—of the tests with the race detector enabled.
To submit your code to Autolab, create a lsp.tar
file containing your LSP implementation as follows:
cd p1/src/github.com/cmu440/
tar -cvf lsp.tar lsp/
In order to use the starter code we provide in the hash.go
and message.go
files, use the
following import
statement:
import "github.com/cmu440/bitcoin"
Once you do this, you should be able to make use of the bitcoin
package as follows:
hash := bitcoin.Hash("thom yorke", 19970521)
msg := bitcoin.NewRequest("jonny greenwood", 200, 71010)
To compile the client
, miner
, and server
programs, use the go install
command
as follows (these instructions assume your
GOPATH
is pointing to the project's root p1/
directory):
# Compile the client, miner, and server programs. The resulting binaries
# will be located in the $GOPATH/bin directory.
go install github.com/cmu440/bitcoin/client
go install github.com/cmu440/bitcoin/miner
go install github.com/cmu440/bitcoin/server
# Start the server, specifying the port to listen on.
$GOPATH/bin/server 6060
# Start a miner, specifying the server's host:port.
$GOPATH/bin/miner localhost:6060
# Start the client, specifying the server's host:port, the message
# "bradfitz", and max nonce 9999.
$GOPATH/bin/client localhost:6060 bradfitz 9999
Note that you will need to use the os.Args
variable in your code to access the user-specified
command line arguments.
To submit your code to Autolab, create a cmu440.tar
file containing your part A and part B implementation
as follows:
cd p1/src/github.com/
tar -cvf cmu440.tar cmu440/
Before you begin the project, you should read and understand all of the starter code we provide. To make this experience a little less traumatic (we know, it's a lot :P), fire up a web server and read the documentation in a browser by executing the following command:
godoc -http=:6060 &
Then, navigate to localhost:6060/pkg/github.com/cmu440 in a browser.
Note that you can execute this command from anywhere in your system (assuming your GOPATH
is pointing to the project's root p1/
directory).