To decide what Gob’s bad impression of a chicken might be, Arnett consulted on set in 2003 with series executive producers Mitch Hurwitz and James Vallely. They all tried out different versions for each other. “Jimmy started doing a little bit, then Mitch got up and did some, and then I began trying things,” remembers Arnett. “Picture three grown men hopping around, working out what it would be … They were pitching this really taunting dance, but I wanted to give it this very sharp, almost roosterlike, chest-sticking-out mannerism, like a real macho bravado dance.” And how did clapping get introduced to the move? “Because I wanted it to be only sort of threatening.”
In JavaScript numbers are 64bit floating point numbers which have 53 bits of mantissa. That means you can accurately represent [-2^53, 2^53] as integers in JavaScript. Aka [-9007199254740992, 9007199254740992].
drug companies hiding the results of clinical trials.
(via I did a new talk at TED, on drug companies and hidden data.)
Level 5 of the Stripe CTF revolved around a design issue in an OpenID like protocol.
def authenticated?(body)
body =~ /[^\w]AUTHENTICATED[^\w]*$/
end
...
if authenticated?(body)
session[:auth_user] = username
session[:auth_host] = host
return "Remote server responded with: #{body}." \
" Authenticated as #{username}@#{host}!"This level is an implementation of a federated identity protocol. You give it an endpoint URI and a username and password, it posts the username and password to the endpoint URI, and if the response is 'AUTHENTICATED' then access is allowed. It is easy to be authenticated on a server you control, but this level requires you to authenticate from the server running the level. This level only talks to stripe CTF servers so the first step is to upload a document to the level 2 server containing the text 'AUTHENTICATED' and we can now authenticate on a level 2 server. Notice that the level 5 server will dump out the content of the endpoint URI and that the regexp it uses to detect the text 'AUTHENTICATED' can match on that dump. Accordingly I uploaded an authenticated file to
https://level02-2.stripe-ctf.com/user-ajvivlehdt/uploads/authenticatedhttps://level05-1.stripe-ctf.com/user-qtoyekwrod/?pingback=https%3A%2F%2Flevel02-2.stripe-ctf.com%2Fuser-ajvivlehdt%2Fuploads%2Fauthenticated&username=a&password=aI didn't see any particular code review red flags, really the issue here is that the regular expression testing for 'AUTHENTICATED' is too permisive and the protocol itself doesn't do enough. The protocol requires only a set piece of common literal text to be returned which makes it easy for a server to accidentally fall into authenticating. Having the endpoint URI have to return variable text based on the input would make it much harder for a server to accidentally authenticate.
Level 4 and level 6 of the Stripe CTF had solutions around XSS.
> Registered Users
<%= user[:username] %>
(password: <%= user[:password] %>, last active <%= last_active %>)
The level 4 web application lets you transfer karma to another user and in doing so you are also forced to expose your password to that user. The main user page displays a list of users who have transfered karma to you along with their password. The password is not HTML encoded so we can inject HTML into that user's browser. For instance, we could create an account with the following HTML as the password which will result in XSS with that HTML:
Code review red flags in this case included lack of encoding when using user controlled content to create HTML content, storing passwords in plain text in the database, and displaying passwords generally. By design the web app shows users passwords which is a very bad idea.
...
def self.safe_insert(table, key_values)
key_values.each do |key, value|
# Just in case people try to exfiltrate
# level07-password-holder's password
if value.kind_of?(String) &&
(value.include?('"') || value.include?("'"))
raise "Value has unsafe characters"
end
end
conn[table].insert(key_values)
endThis web app does a much better job than the level 4 app with HTML injection. They use encoding whenever creating HTML using user controlled data, however they don't use encoding when injecting JSON data into script (see post_data initialization above). This JSON data is the last five most recent messages sent on the app so we get to inject script directly. However, the system also ensures that no strings we write contains single or double quotes so we can't get out of the string in the JSON data directly. As it turns out, HTML lets you jump out of a script block using no matter where you are in script. For instance, in the middle of a value in some JSON data we can jump out of script. But we still want to run script, so we can jump right back in. So the frame so far for the message we're going to post is the following:
Stripe's web security CTF's Level 1 and level 2 of the Stripe CTF had issues with missing input validation solutions described below.
$filename = 'secret-combination.txt';
extract($_GET);
if (isset($attempt)) {
$combination = trim(file_get_contents($filename));
if ($attempt === $combination) {The issue here is the usage of the extract php method which extracts name value pairs from the map input parameter and creates corresponding local variables. However this code uses $_GET which contains a map of name value pairs passed in the query of the URI. The expected behavior is to get an attempt variable out, but since no input validation is done I can provide a filename variable and overwrite the value of $filename. Providing an empty string gives an empty string $combination which I can match with an empty string $attempt. So without knowing the combination I can get past the combination check.
Code review red flag in this case was the direct use of $_GET with no validation. Instead of using extract the developer could try to extract specifically the attempt variable manually without using extract.
$dest_dir = "uploads/";
$dest = $dest_dir . basename($_FILES["dispic"]["name"]);
$src = $_FILES["dispic"]["tmp_name"];
if (move_uploaded_file($src, $dest)) {
$_SESSION["dispic_url"] = $dest;
chmod($dest, 0644);
echo "Successfully uploaded your display picture.
";
}
This code accepts POST uploads of images but with no validation to ensure it is not an arbitrary file. And even though it uses chmod to ensure the file is not executable, things like PHP don't require a file to be executable in order to run them. Accordingly, one can upload a PHP script, then navigate to that script to run it. My PHP script dumped out the contents of the file we're interested in for this level:
Code review red flags include manual file management, chmod, and use of file and filename inputs without any kind of validation. If this code controlled the filename and ensured that the extension was one of a set of image extensions, this would solve this issue. Due to browser mime sniffing its additionally a good idea to serve a content-type that starts with "image/" for these uploads to ensure browsers treat these as images and not sniff for script or HTML.
Stripe's web security CTF's level 0 and level 3 had SQL injection solutions described below.
app.get('/*', function(req, res) {
var namespace = req.param('namespace');
if (namespace) {
var query = 'SELECT * FROM secrets WHERE key LIKE ? || ".%"';
db.all(query, namespace, function(err, secrets) {There's no input validation on the namespace parameter and it is injected into the SQL query with no encoding applied. This means you can use the '%' character as the namespace which is the wildcard character matching all secrets.
Code review red flag was using strings to query the database. Additional levels made this harder to exploit by using an API with objects to construct a query rather than strings and by running a query that only returned a single row, only ran a single command, and didn't just dump out the results of the query to the caller.
@app.route('/login', methods=['POST'])
def login():
username = flask.request.form.get('username')
password = flask.request.form.get('password')
if not username:
return "Must provide username\n"
if not password:
return "Must provide password\n"
conn = sqlite3.connect(os.path.join(data_dir, 'users.db'))
cursor = conn.cursor()
query = """SELECT id, password_hash, salt FROM users
WHERE username = '{0}' LIMIT 1""".format(username)
cursor.execute(query)
res = cursor.fetchone()
if not res:
return "There's no such user {0}!\n".format(username)
user_id, password_hash, salt = res
calculated_hash = hashlib.sha256(password + salt)
if calculated_hash.hexdigest() != password_hash:
return "That's not the password for {0}!\n".format(username)There's little input validation on username before it is used to constrcut a SQL query. There's no encoding applied when constructing the SQL query string which is used to, given a username, produce the hashed password and the associated salt. Accordingly one can make username a part of a SQL query command which ensures the original select returns nothing and provide a new SELECT via a UNION that returns some literal values for the hash and salt. For instance the following in blue is the query template and the red is the username injected SQL code:
SELECT id, password_hash, salt FROM users WHERE username = 'doesntexist' UNION SELECT id, ('5e884898da28047151d0e56f8dc6292773603d0d6aabbdd62a11ef721d1542d8') AS password_hash, ('word') AS salt FROM users WHERE username = 'bob' LIMIT 1Code review red flag is again using strings to query the database. Although this level was made more difficult by using an API that returns only a single row and by using the execute method which only runs one command. I was forced to (as a SQL noob) learn the syntax of SELECT in order to figure out UNION and how to return my own literal values.
I was the 546th person to complete Stripe's web security CTF and again had a ton of fun applying my theoretical knowledge of web security issues to the (semi-)real world. As I went through the levels I thought about what red flags jumped out at me (or should have) that I could apply to future code reviews:
| Level | Issue | Code Review Red Flags |
|---|---|---|
| 0 | Simple SQL injection | No encoding when constructing SQL command strings. Constructing SQL command strings instead of SQL API |
| 1 | extract($_GET); | No input validation. |
| 2 | Arbitrary PHP execution | No input validation. Allow file uploads. File permissions modification. |
| 3 | Advanced SQL injection | Constructing SQL command strings instead of SQL API. |
| 4 | HTML injection, XSS and CSRF | No encoding when constructing HTML. No CSRF counter measures. Passwords stored in plain text. Password displayed on site. |
| 5 | Pingback server doesn't need to opt-in | n/a - By design protocol issue. |
| 6 | Script injection and XSS | No encoding while constructing script. Deny list (of dangerous characters). Passwords stored in plain text. Password displayed on site. |
| 7 | Length extension attack | Custom crypto code. Constructing SQL command string instead of SQL API. |
| 8 | Side channel attack | Password handling code. Timing attack mitigation too clever. |
More about each level in the future.
|
From: David Risney
Views: 75
0 ratings
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| Time: 00:43 | More in People & Blogs |
“tl;dr I just made a tool to transform any javascript code into an equivalent sequence of ()[]{}!+ characters. You can try it here, or grab it from github or npm. Keep on reading if you want to know how it works.”
JavaScript has some crazy implicit casts.
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From: David Risney
Views: 69
0 ratings
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|
| Time: 00:53 | More in People & Blogs |
Former FireFox developer on the switch to their continuous update cycle.
Oh no, Chrome is doing such-and-such; we’d better do something equivalent or we’ll fall behind! We thought we needed a rapid update process like Chrome. We were jealous of their rapid update capability, which let them deploy improvements to users continuously. We had to “catch up” with Chrome’s updating capability.
Dealing with servicing on IE for years had led me to some of the same thoughts when I heard FireFox was switching to continuous updates.
A leaf directory in a whole set of files that map from character set byte value to Unicode code point. This one is a set of Microsoft character set byte mappings, but there are other vendors in there too.
Neat demo of Visvalingam’s line simplification algorithm in JavaScript applied to a map of the US.
To simplify geometry to suit the displayed resolution, various line simplification algorithms exist. While Douglas–Peucker is the most well-known, Visvalingam’s algorithm may be more effective and has a remarkably intuitive explanation: it progressively removes points with the least-perceptible change.
Jet Set Radio HD coming soon with awesome soundtrack promised. Exciting!
param([Parameter(Mandatory = $true)] [string] $Path);
$FullPathOriginal = (gp "HKLM:\System\CurrentControlSet\Control\Session Manager\Environment").Path;
if (!($FullPathOriginal.split(";") | ?{ $_ -like $Path })) {
sp "HKLM:\System\CurrentControlSet\Control\Session Manager\Environment" -name Path -value ($FullPathOriginal + ";" +
$Path);
}
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