Release 1.2.0

* README.md: Release updates
incoming
Ray 2017-04-03 15:16:37 -07:00
parent 7a84c71e80
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2017-04-03 Ray Brown <ray@Virtor10>
Release 1.2.0
* README.md: Release updates
2017-04-02 Ray Brown <code@liquibits.com>
Release 1.2.0 Preparation

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README.md
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============================================
Datagram Transport Layer Security for Python
============================================
# Datagram Transport Layer Security for Python
PyDTLS brings Datagram Transport Layer Security (DTLS - RFC 6347:
http://tools.ietf.org/html/rfc6347) to the Python environment. In a
@ -13,47 +11,51 @@ DTLS is now very easy to use in Python. If you're familiar with the
ssl module in Python's standard library, you already know how. All it
takes is passing a datagram/UDP socket to the *wrap_socket* function
instead of a stream/TCP socket. Here's how one sets up the client side
of a connection::
of a connection:
import ssl
from socket import socket, AF_INET, SOCK_DGRAM
from dtls import do_patch
do_patch()
sock = ssl.wrap_socket(socket(AF_INET, SOCK_DGRAM))
sock.connect(('foo.bar.com', 1234))
sock.send('Hi there')
```
import ssl
from socket import socket, AF_INET, SOCK_DGRAM
from dtls import do_patch
do_patch()
sock = ssl.wrap_socket(socket(AF_INET, SOCK_DGRAM))
sock.connect(('foo.bar.com', 1234))
sock.send('Hi there')
```
Design Goals
============
As of version 1.2.0, PyDTLS supports DTLS version 1.2 in addition to
version 1.0. This version also introduces forward secrecy using
elliptic curve cryptography and more fine-grained configuration options.
## Design Goals
The primary design goal of PyDTLS is broad availability. It has therefore
been built to be widely compatible with the following:
* Operating systems: apart from the Python standard library, PyDTLS
relies on the OpenSSL library only. OpenSSL is widely ported, and
in fact the Python standard library's *ssl* module also uses it.
* Python runtime environments: PyDTLS is a package consisting of
pure Python modules only. It should therefore be portable to many
interpreters and runtime environments. It interfaces with OpenSSL
strictly through the standard library's *ctypes* foreign function
library.
* The Python standard library: the standard library's *ssl* module is
Python's de facto interface to SSL/TLS. PyDTLS aims to be compatible
with the full public interface presented by this module. The ssl
module ought to behave identically with respect to all of its
functions and options when used in conjunction with PyDTLS and
datagram sockets as when used without PyDTLS and stream sockets.
* Connection-based protocols: as outlined below, layering security
on top of datagram sockets requires introducing certain
connection constructs normally absent from datagram
sockets. These constructs have been added in such a way as to be
compatible with code that expects to interoperate with
connection-oriented stream sockets. For example, code that
expects to go through server-side bind/listen/accept connection
establishment should be reusable with PyDTLS sockets.
* Operating systems: apart from the Python standard library, PyDTLS
relies on the OpenSSL library only. OpenSSL is widely ported, and
in fact the Python standard library's *ssl* module also uses it.
* Python runtime environments: PyDTLS is a package consisting of
pure Python modules only. It should therefore be portable to many
interpreters and runtime environments. It interfaces with OpenSSL
strictly through the standard library's *ctypes* foreign function
library.
* The Python standard library: the standard library's *ssl* module is
Python's de facto interface to SSL/TLS. PyDTLS aims to be compatible
with the full public interface presented by this module. The ssl
module ought to behave identically with respect to all of its
functions and options when used in conjunction with PyDTLS and
datagram sockets as when used without PyDTLS and stream sockets.
* Connection-based protocols: as outlined below, layering security
on top of datagram sockets requires introducing certain
connection constructs normally absent from datagram
sockets. These constructs have been added in such a way as to be
compatible with code that expects to interoperate with
connection-oriented stream sockets. For example, code that
expects to go through server-side bind/listen/accept connection
establishment should be reusable with PyDTLS sockets.
Distributions
=============
## Distributions
PyDTLS requires version 1.0.0 or higher of the OpenSSL
library. Earlier versions are reported not to offer stable DTLS
@ -67,14 +69,15 @@ no further installation steps.
In comparison, installation of OpenSSL on Microsoft Windows operating
systems is inconvenient. For this reason, source distributions of
PyDTLS are available that include OpenSSL dll's for 32-bit and 64-bit
Windows. For 32-bit Windows, a version built with the MinGW toolchain
is also available. Its archive includes stripped as well as
non-stripped dll's. The latter can be debugged with gdb on
Windows. All dll's have been linked with the Visual Studio 2008
version of the Microsoft C runtime library, msvcr90.dll, the version
used by CPython 2.7. Installation of Microsoft redistributable runtime
packages should therefore not be required on machines with CPython
2.7. The version of OpenSSL distributed with PyDTLS 0.1.0 is 1.0.1c.
The version distributed with PyDTLS 1.2.0 is commit
248cf959672041f38f4d80a4a09ee01d8ab04fe8 (branch OpenSSL_1_0_2-stable,
1.0.2l-dev, containing a desirable fix to DTLSv1_listen not present
in 1.0.2k, the stable version at the time of PyDTLS 1.2.0 release).
The OpenSSL version used by PyDTLS can be determined from the values
of *sslconnection's* DTLS_OPENSSL_VERSION_NUMBER,
@ -83,8 +86,7 @@ are available through the *ssl* module also if *do_patch* has been
called (see below). Note that the OpenSSL version used by PyDTLS may
differ from the one used by the *ssl* module.
Interfaces
==========
## Interfaces
PyDTLS' top-level package, *dtls*, provides DTLS support through the
**SSLConnection** class of its *sslconnection*
@ -111,8 +113,7 @@ exceptions of type **ssl.SSLError** instead of its default
remain identical when interfacing with *ssl* across stream and
datagram sockets.
Connection Handling
===================
## Connection Handling
The DTLS protocol implies a connection as an association between two
network peers where the overall association state is characterized by the
@ -145,12 +146,11 @@ prohibited by *ssl*. *accept* returns peer address information, as
expected. Note that when using the *ssl* interface to *dtls*, *listen*
must be called before calling *accept*.
Demultiplexing
==============
## Demultiplexing
At the network io layer, only datagrams from its connected peer must be
passed to a **SSLConnection** or **SSLSocket** object (unless the object
is unconnected on the server-side, in which case in can be in listening
is unconnected on the server-side, in which case it can be in listening
mode, the initial server-side socket whose role it is to listen for
incoming client connection requests).
@ -203,8 +203,7 @@ socket might now be readable as a result of the forwarded
datagram. *accept* must return so that the application can iterate on
its asynchronous *select* loop.
Shutdown and Unwrapping
=======================
## Shutdown and Unwrapping
PyDTLS implements the SSL/TLS shutdown protocol as it has been adapted
for DTLS. **SSLConnection's** *shutdown* and **SSLSocket's** *unwrap*
@ -227,21 +226,19 @@ passing it to *ssl.wrap_socket* or the **SSLConnection**
constructor. If *osnet* is used, an actual *socket.socket* instance is
returned.
Framework Compatibility
=======================
## Framework Compatibility
PyDTLS sockets have been tested under the following usage modes:
* Using blocking sockets and sockets with timeouts in
multi-threaded UDP servers
* Using non-blocking sockets, and in conjunction with the
asynchronous socket handler, asyncore
* Using blocking sockets, and in conjunction with the network
server framework SocketServer - ThreadingTCPServer (this works
because of PyDTLS's emulation of connection-related calls)
* Using blocking sockets and sockets with timeouts in
multi-threaded UDP servers
* Using non-blocking sockets, and in conjunction with the
asynchronous socket handler, asyncore
* Using blocking sockets, and in conjunction with the network
server framework SocketServer - ThreadingTCPServer (this works
because of PyDTLS's emulation of connection-related calls)
Multi-thread Support
====================
## Multi-thread Support
Using multiple threads with OpenSSL requires implementing a locking
callback. PyDTLS does implement this, and therefore multi-threaded
@ -267,8 +264,16 @@ platforms where PyDTLS loads the same OpenSSL shared object as
*ssl*. On Ubuntu 12.04, for example, this is the case, but on
Microsoft Windows it is not.
Testing
=======
## Testing
A simple echo server is available to be executed from the project root
directory with `python -m dtls.test.echo_seq`. The echo server is
reachable using the code snippet at the top of this document, using port
28000 at "localhost".
Unit test suites can be executed from the project root directory with
`python -m dtls.test.unit [-v]` and `python -m dtls.test.unit_wrapper`
(for the client and server wrappers)
Almost all of the Python standard library's *ssl* unit tests from the
module *test_ssl.py* have been ported to *dtls.test.unit.py*. All tests
@ -311,18 +316,19 @@ benefits of DTLS over SSL). Nevertheless, some useful insights can be
gained by observing the operation of test_perf.py, including software
stack behavior in the presence of some amount of packet loss.
Logging
=======
## Logging
The *dtls* package and its sub-packages log various occurrences,
primarily events that can aid debugging. Especially *router* emits many
messages when the logging level is set to at least *logging.DEBUG*.
dtls/test/echo_seq.py activates this logging level during its operation.
Currently Supported Platforms
=============================
## Currently Supported Platforms
At the time of initial release, PyDTLS 0.1.0 has been tested on Ubuntu
12.04.1 LTS 32-bit and 64-bit, as well as Microsoft Windows 7 32-bit
and 64-bit, using CPython 2.7.3. Patches with additional platform
ports are welcome.
As of release 1.2.0, PyDTLS is tested on Ubuntu 16.04 LTS as well as
Microsoft Windows 10, using CPython 2.7.13.