Posted on February 28, 2009
by Michael
I recently had to do some DNSSEC-type (somewhat low-level) cryptography work, and found the
seeming lack of Ruby OpenSSL documentation a big pain. I found numerous examples of how OpenSSL is commonly used with PEM-encoded keys, but precious little information on low-level key loading. To save others the trouble of having to dig up some of this, I’ve collected some short examples of how to do low-level RSA and DSA building from a lower level than most use.
This table summarizes the variables which need to be set to use an RSA public and private key.
RSA Keys
| Key Type | Item | Description |
| RSA Public | e | Public Exponent |
| RSA | n | Modulus |
| RSA Private | d | Private Exponent |
| RSA Private | p | Prime 1 |
| RSA Private | q | Prime 2 |
| RSA Private | dmq1 | Exponent 1 |
| RSA Private | dmp1 | Exponent 2 |
| RSA Private | iqmp | Coefficient |
Thus, in order to make a working RSA public key (so the method key.publicencrypt() or key.publicdecrypt() work) you must set at least n and e. For a working private key, you would need to load all of the items. Exposing any of the items marked as “RSA Private” above will cause a key compromise.
RSA Example
In this example, a 128-bit RSA key is loaded from numerical values. In DNSSEC, the public key is stored in the DNSKEY record for the zones. Don’t use these numbers for real crypto; the short key length is used only to make the numbers short enough to fit in the screen width. For real work, 1024 is probably a reasonable minimum length for short-lived uses, and 2048 for longer-term use.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
|
require 'openssl'
#
# Build a RSA public key. We only need to load two things
# here in order to use the public key to use it to encrypt,
# sign, or verify.
#
pub = OpenSSL::PKey::RSA::new
pub.e = 65537
pub.n = 216457604585180710748301099018726389113
# At this point, this will work:
crypted = pub.public_encrypt("test")
#
# Build an RSA private key. For the private key to work, we need
# to load the entire key, private and public components. As we
# should have access to both, this is not really a problem.
#
prv = OpenSSL::PKey::RSA::new
prv.e = 65537
prv.d = 178210827022942698143906513631075003381
prv.n = 216457604585180710748301099018726389113
prv.p = 15294921647876231099
prv.q = 14152253249053866587
prv.dmp1 = 6806715058393856237
prv.dmq1 = 637679537428568107
prv.iqmp = 6672106206837437412
# Now we have a working private key.
puts prv.private_decrypt(crypted) # prints "test" |
DSA keys
A DSA key is more or less the same, just with different variable names. It is also split into a public and private part, and the key can be loaded from individual components just as easily.
| Key Type | Item | Description |
| DSA Public | pub_key | Public Key |
| DSA | q | Prime 1 |
| DSA | p | Prime 2 |
| DSA | g | Multiplicative order modulo p is q |
| DSA Private | priv_key | Private Key |
DSA Example
Unfortunately, this example has some numbers which are too long to display nicely.
I have used a trick to convert them from strings into integers so they
will fit here. Normally you would not need to do this.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
|
require 'openssl'
#
# Build an DSA private key. For the private key to work, we need
# to load the entire key, private and public components. As we
# should have access to both, this is not really a problem.
#
prv = OpenSSL::PKey::DSA::new
prv.pub_key = ("899167044393666062859565588228279347268072456516837337" +
"963353916587148226144760114643916732975837345856985656" +
"3340384802383806137452386519280693373122367959").to_i
prv.p = ("952649509730281181203079535805855260554748337655197352471196" +
"869232197576949258404031665397657842790773780623545384978542" +
"6685417827665656974405272756289291").to_i
prv.q = 903197981571669745498020976355730183999507610553
prv.g = ("535694721480531756072717909769318961974692885092552247120424" +
"749877864650255208980198391972633196543370921493242375015765" +
"755160911031468160738717891191998").to_i
prv.priv_key = 557886499717422048101097620625259920363848888840
# At this point, this will work:
signature = prv.sign(OpenSSL::Digest::DSS1.new, "test")
#
# Build a DSA public key. We only need to load two things
# here in order to use the public key to use it to encrypt,
# sign, or verify.
#
pub = OpenSSL::PKey::DSA::new
pub.pub_key = ("899167044393666062859565588228279347268072456516837337" +
"963353916587148226144760114643916732975837345856985656" +
"3340384802383806137452386519280693373122367959").to_i
pub.p = ("952649509730281181203079535805855260554748337655197352471196" +
"869232197576949258404031665397657842790773780623545384978542" +
"6685417827665656974405272756289291").to_i
pub.q = 903197981571669745498020976355730183999507610553
pub.g = ("535694721480531756072717909769318961974692885092552247120424" +
"749877864650255208980198391972633196543370921493242375015765" +
"755160911031468160738717891191998").to_i
# Now we have a working private key. Verify the signature
if pub.verify(OpenSSL::Digest::DSS1.new, signature, "test")
puts "Signature verified."
else
puts "Signature verification failed."
end |
Tagged with: cryptography programming ruby security
| 0 comments
Posted on February 28, 2009
by Michael
I have often wished to add a trivial search capability to my controllers which would allow searching on different fields. Without getting into a mess of many different if statements each of which has a different set of conditions, I use something much like the following:
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
|
def index
cond_hash = {}
cond_strings = []
if params[:search]
cond_hash[:login] = "%#{params[:search]}%"
cond_hash[:email] = "%#{params[:search]}%"
cond_strings << "(login ILIKE :login OR email ILIKE :email)"
end
if params[:search_address]
cond_hash[:address] = params[:search_address]
cond_strings << "(address == :address)"
end
conditions = cond_strings.join(" AND ")
@users = User.all :conditions => [ conditions, cond_hash ]
end |
It may be safer to use users.login, users.email, and
users.address in the SQL-like strings above.
Tagged with: programming ruby ruby-on-rails
| 0 comments
Posted on February 28, 2009
by Michael
Rails is a great framework, but it has gained something of a bad reputation in terms of error reporting. Everyone has seen them – those ugly 500-status “we’re sorry, but something has gone wrong” messages.
In a finished application, this just doesn’t cut it. It used to be necessary to trap
the error using something like this:
1
2
3
4
5
6
7
8
|
def rescue_action_in_public(exception)
case exception
when ::ActiveRecord::RecordNotFound
render :file => "#{Rails.public_path}/404.html", :status => 404
else
render :file => "#{Rails.public_path}/500.html", :status => 500
end
end |
The problem is that, as error causes begin to pile up, this method gets messy. Plus,
you might want to render something different in one controller than in another, and
would either need to duplicate all the logic, put controller-specific cases in the ApplicationController, or call ApplicationController::rescueactionin_public directly.
Enter Rails 2.x error handling. Drop this in your controller or ApplicationController.
1
2
3
|
rescue_from(ActiveRecord::RecordNotFound) do |e|
render :file => "#{Rails.public_path}/404_record_not_found.html", :status => 404
end |
By building up a rich set of rescue_from handlers in the ApplicationController, and only
overriding the ones you wish to make per-controller, you have fine-grained control. And they
work exactly the same in development and testing as they do in production.
Tagged with: programming ruby-on-rails
| 0 comments
Posted on February 26, 2009
by Michael
I love Ruby. I love Ruby on Rails. Rarely have I found a language or a framework that just works.
However, you still have to know the finer details sometimes. I recently made a model for a DNS zone. The name in the model is the “front part” of a fully qualified domain name. For instance, if zone.name = “foo” then I would write the name into my name server’s configuration files as “foo.example.com.”
Knowing that people were evil, I saw that if a user put a string in like “example.com. NS hackerz-will-someday-rule-the-earth.ru.\nfoo” I would happily write out two strings, one being rather bad.
Knowing how easy this sort of data validation is in Rails, I made my model look like:
1
2
3
4
5
6
7
|
class Zone < ActiveRecord::Base
validates_presence_of :name
validates_uniqueness_of :name
validates_format_of :name,
:with => /^[a-zA-Z0-9\-\_\.]+$/,
:message => "contains invalid characters."
end |
Happy, I ran a few tests using my browser and found that I could not insert names with spaces, colons, tabs, etc. Then, several days later, I decided it was time to write tests for this.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
|
require 'test_helper'
class ZoneTest < ActiveSupport::TestCase
def test_name_with_newline_fails
z = Zone.new(:name => "test\nzone")
assert !z.valid?
assert z.errors.on(:name)
end
def test_name_with_space_fails
z = Zone.new(:name => "test zone")
assert !z.valid?
assert z.errors.on(:name)
end
end |
Imagine my surprise when testnamewithspacefails() passed, and the one I was most worried about, testnamewithnewlinefails(), did not!
Not all regular expressions are alike.
The problem is in what I thought ^ and $ actually matched. I thought these meant “match the beginning and ending of the string.” However, it turns out it means “match the beginning and ending of each line contained in the string,” where lines are divided by newlines. Ooops.
Changing ^ into \A and $ into \Z fixed this problem. Now I’m auditing all the code in this application to see if there are other problems like this.
This is just one thing to add to an ever-growing security checklist for my Rails work. It’s also a very typical security hole: programmer error.
Tagged with: programming ruby ruby-on-rails security
| 0 comments
Posted on February 24, 2009
by Michael
OK, so I admit it. I love sharp knives. Well, more exactly I love my knives to be sharp.
So, I bought a Wüsthof knife sharpener, fully expecting it to suck.
I am now happily using my knives to chop and cut, not saw, through things again.
Oh, and my knives are J.A.Henckels professional “S” series.
Tagged with: cooking sharp-things tools
| 1 comment
Posted on February 21, 2009
by Michael
And that’s ‘“bi-truncate” not “bit-uncate”.
What’s it do?
1
2
|
"This is a test".bitruncate(:length => 6) ==> "Thi...est"
"This is a test".bitruncate(:elength => 6) ==> "...a test" |
The default options are { :length => 30 } which will produce 15 characters from the front and 15 from the end, putting … marks in the middle.
For rails, I put this in my lib/core_extensions.rb file.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
|
#
# Copyright (c) 2009 Michael Graff. All rights reserved.
#
# Redistribution and use in source and binary forms, with or
# without modification, are permitted provided that the following
# conditions are met:
# 1. Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
# 2. Redistributions in binary form must reproduce the above
# copyright notice, this list of conditions and the following
# disclaimer in the documentation and/or other materials provided
# with the distribution.
# 3. The name of Michael Graff may not be used to endorse or promote
# products derived from this software without specific prior
# written permission.
#
# THIS SOFTWARE IS PROVIDED BY Michael Graff ``AS IS'' AND ANY
# EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
# THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
# PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL Micahel Graff
# BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
# EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED
# TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND
# ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
# OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
# OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY
# OF SUCH DAMAGE.
#
class String
#
# Truncate from both ends of a string. The :length parameter, which defaults
# to 30, will return the first 15 and the last 15 characters from a string
# if it is longer than 30 characters. If it is shorter, the entire string
# is returned.
#
# Another way to specify the front and back portions are with :flength and
# :elength. If you specify one of these but not the other then you will
# not get the missing part. e.g., :flength => 10 alone will return only
# the first 10 charcters of the string. This is the same as the standard
# truncate(s, :length => 10) helper.
#
# If a :length parameter is provided it will override any other lengths
# specified.
#
def bitruncate(options = {})
maxlength = options[:length] || 0
flength = options[:flength] || 0
elength = options[:elength] || 0
omission = options[:omission] || '...'
if maxlength == 0 && flength == 0 && elength == 0
maxlength = 30
end
if maxlength != 0
flength = maxlength / 2
elength = maxlength / 2
end
return self if length <= (flength + elength)
front = ''
back = ''
if flength > 0
front = self[0..(flength - 1)]
end
if elength > 0
back = self[(length - elength)..(length)]
end
front + omission + back
end
end |
Filed under: Programming |
Tagged with: programming ruby
| 0 comments