This is an experimental implementation of Google's SPDY protocol in C.
This library provides SPDY version 2, 3 and 3.1 framing layer implementation. It does not perform any I/O operations. When the library needs them, it calls the callback functions provided by the application. It also does not include any event polling mechanism, so the application can freely choose the way of handling events. This library code does not depend on any particular SSL library (except for example programs which depend on OpenSSL 1.0.1 or later).
This project also develops SPDY client, server and proxy on top of Spdylay library. See SPDY Client and Server Programs section.
Most of the SPDY/2, SPDY/3 and SPDY/3.1 functionality has been implemented. In both versions, the direct support of server-push has not been available yet. The application can achieve server-push using primitive APIs though.
As described below, we can create SPDY client and server with the current Spdylay API.
The following packages are needed to build the library:
- pkg-config >= 0.20
- zlib >= 1.2.3
To build and run the unit test programs, the following packages are needed:
- cunit >= 2.1
To build and run the example programs, the following packages are needed:
- OpenSSL >= 1.0.1
To enable -a
option (getting linked assets from the downloaded
resource) in spdycat
(one of the example program), the following
packages are needed:
- libxml2 >= 2.7.7
To build SPDY/HTTPS to HTTP reverse proxy shrpx
(one of the
example program), the following packages are needed:
- libevent-openssl >= 2.0.8
If you are using Ubuntu 12.04, you need the following packages installed:
- autoconf
- automake
- autotools-dev
- libtool
- pkg-config
- zlib1g-dev
- libcunit1-dev
- libssl-dev
- libxml2-dev
- libevent-dev
Building from git is easy, but please be sure that at least autoconf 2.68 is used:
$ autoreconf -i $ automake $ autoconf $ ./configure $ make
To build documentation, run:
$ make html
The documents will be generated under doc/manual/html/
.
The generated documents will not be installed with make install
.
In this section, we briefly describe how to build Android binary using Android NDK cross-compiler on Debian Linux.
We offer android-config
and android-make
scripts to make the
build easier. To make these script work, NDK toolchain must be
installed in the following way. First, let introduce ANDROID_HOME
environment variable. We need to install toolchain under
$ANDROID_HOME/toolchain
. An user can freely choose the path for
ANDROID_HOME
. For example, to install toolchain under
$ANDROID_HOME/toolchain
, do this in the the directory where NDK is
unpacked:
$ build/tools/make-standalone-toolchain.sh --platform=android-9 --install-dir=$ANDROID_HOME/toolchain
The platform level is not important here because we don't use Android specific C/C++ API.
The dependent libraries, such as OpenSSL and libevent should be built
with the toolchain and installed under $ANDROID_HOME/usr/local
.
We recommend to build these libraries as static library to make the
deployment easier. libxml2 support is currently disabled.
We use zlib which comes with Android NDK, so we don't have to build it by ourselves.
Before running android-config
and android-make
,
ANDOIRD_HOME
environment variable must be set to point to the
correct path.
After android-config
, run android-make
to compile sources.
android-make
is just include path to cross compiler in PATH
and run make. So if you include path to corss compiler by yourself,
you can just run make to build spdylay and tools as usual.
The public API reference is available on online. Visit http://tatsuhiro-t.github.io/spdylay/. All public APIs are in spdylay/spdylay.h. All public API functions as well as the callback function typedefs are documented.
The src directory contains SPDY client and server implementations using Spdylay library. These programs are intended to make sure that Spdylay API is acutally usable for real implementation and also for debugging purposes. Please note that OpenSSL with NPN support is required in order to build and run these programs. At the time of this writing, the OpenSSL 1.0.1 supports NPN.
The SPDY client is called spdycat
. It is a dead simple downloader
like wget/curl. It connects to SPDY server and gets resources given in
the command-line:
$ src/spdycat -h Usage: spdycat [-Oansv23] [-t <SECONDS>] [-w <WINDOW_BITS>] [--cert=<CERT>] [--key=<KEY>] [--no-tls] [-d <FILE>] [-m <N>] [-p <PROXY_HOST>] [-P <PROXY_PORT>] <URI>... OPTIONS: -v, --verbose Print debug information such as reception/ transmission of frames and name/value pairs. -n, --null-out Discard downloaded data. -O, --remote-name Save download data in the current directory. The filename is dereived from URI. If URI ends with '/', 'index.html' is used as a filename. Not implemented yet. -2, --spdy2 Only use SPDY/2. -3, --spdy3 Only use SPDY/3. --spdy3-1 Only use SPDY/3.1. -t, --timeout=<N> Timeout each request after <N> seconds. -w, --window-bits=<N> Sets the initial window size to 2**<N>. -a, --get-assets Download assets such as stylesheets, images and script files linked from the downloaded resource. Only links whose origins are the same with the linking resource will be downloaded. -s, --stat Print statistics. -H, --header Add a header to the requests. --cert=<CERT> Use the specified client certificate file. The file must be in PEM format. --key=<KEY> Use the client private key file. The file must be in PEM format. --no-tls Disable SSL/TLS. Use -2, -3 or --spdy3-1 to specify SPDY protocol version to use. -d, --data=<FILE> Post FILE to server. If - is given, data will be read from stdin. -m, --multiply=<N> Request each URI <N> times. By default, same URI is not requested twice. This option disables it too. -p, --proxy=<HOST> Use this host as a SPDY proxy -P, --proxy-port=<PORT> Use this as the port of the SPDY proxy if one is set --color Force colored log output. $ src/spdycat -nv https://www.google.com/ [ 0.021] NPN select next protocol: the remote server offers: * spdy/4a4 * spdy/3.1 * spdy/3 * http/1.1 NPN selected the protocol: spdy/3.1 [ 0.029] Handshake complete [ 0.029] recv SETTINGS frame <version=3, flags=0, length=20> (niv=2) [4(1):100] [7(0):1048576] [ 0.029] recv WINDOW_UPDATE frame <version=3, flags=0, length=8> (stream_id=0, delta_window_size=983040) [ 0.029] send SYN_STREAM frame <version=3, flags=1, length=221> (stream_id=1, assoc_stream_id=0, pri=3) :host: www.google.com :method: GET :path: / :scheme: https :version: HTTP/1.1 accept: */* accept-encoding: gzip, deflate user-agent: spdylay/1.2.0-DEV [ 0.080] recv SYN_REPLY frame <version=3, flags=0, length=619> (stream_id=1) :status: 302 Found :version: HTTP/1.1 alternate-protocol: 443:quic cache-control: private content-length: 262 content-type: text/html; charset=UTF-8 date: Tue, 19 Nov 2013 13:47:18 GMT location: https://www.google.co.jp/ server: gws x-frame-options: SAMEORIGIN x-xss-protection: 1; mode=block [ 0.080] recv DATA frame (stream_id=1, flags=1, length=262) [ 0.080] send GOAWAY frame <version=3, flags=0, length=8> (last_good_stream_id=0)
SPDY server is called spdyd
and serves static files. It is single
threaded and multiplexes connections using non-blocking socket. The
static files are read using blocking I/O system call, read(2)
. It
speaks SPDY/2 and SPDY/3:
$ src/spdyd --htdocs=/your/htdocs/ -v 3000 server.key server.crt IPv4: listen on port 3000 IPv6: listen on port 3000 The negotiated next protocol: spdy/3.1 [id=1] [ 1.296] send SETTINGS frame <version=3, flags=0, length=12> (niv=1) [4(0):100] [id=1] [ 1.297] recv SYN_STREAM frame <version=3, flags=1, length=228> (stream_id=1, assoc_stream_id=0, pri=3) :host: localhost:3000 :method: GET :path: /README :scheme: https :version: HTTP/1.1 accept: */* accept-encoding: gzip, deflate user-agent: spdylay/1.2.0-DEV [id=1] [ 1.297] send SYN_REPLY frame <version=3, flags=0, length=116> (stream_id=1) :status: 200 OK :version: HTTP/1.1 cache-control: max-age=3600 content-length: 66 date: Tue, 19 Nov 2013 14:35:24 GMT last-modified: Tue, 17 Jan 2012 15:39:01 GMT server: spdyd spdylay/1.2.0-DEV [id=1] [ 1.297] send DATA frame (stream_id=1, flags=0, length=66) [id=1] [ 1.297] send DATA frame (stream_id=1, flags=1, length=0) [id=1] [ 1.297] stream_id=1 closed [id=1] [ 1.297] recv GOAWAY frame <version=3, flags=0, length=8> (last_good_stream_id=0) [id=1] [ 1.297] closed
Currently, spdyd
needs epoll
or kqueue
.
The shrpx
is a multi-threaded reverse proxy for SPDY/HTTPS. It
converts SPDY/HTTPS traffic to plain HTTP. It is initially developed
as a reverse proxy, but now it has other operation modes such as a
frontend forward proxy. For example, with --spdy-proxy
(-s
in
shorthand) option, it can be used as secure SPDY proxy with a proxy
(e.g., Squid) in the backend. With --cliet-proxy
(-p
) option,
it acts like an ordinaly forward proxy but expects secure SPDY proxy
in the backend. Thus it becomes an adapter to secure SPDY proxy for
clients which does not support secure SPDY proxy. The another notable
operation mode is --spdy-relay
, which just relays SPDY/HTTPS
traffic to the backend in SPDY. The following table summarizes the
operation modes.
Mode option | Frontend | Backend | Note |
---|---|---|---|
default | SPDY/HTTPS | HTTP | Reverse proxy |
--spdy |
SPDY/HTTPS | HTTP | SPDY proxy |
--spdy-relay |
SPDY/HTTPS | SPDY | |
--client |
HTTP | SPDY | |
--client-proxy |
HTTP | SPDY | Forward proxy |
The shrpx
supports configuration file. See --conf
option and
sample configuration file shrpx.conf.sample
.
We briefly describe the architecture of shrpx
here. It has a
dedicated thread which listens on server sockets. When it accepted
the incoming connection, it passes the file descriptor of the incoming
connection to one of the worker thread. Each worker thread has its
own event loop and can handle many connections using non-blocking I/O.
The number of worker thread can be specified using the command-line
option. The libevent is used to handle
low-level network I/O.
Here is the command-line options:
$ src/shrpx -h Usage: shrpx [-Dh] [-s|--client|-p] [-b <HOST,PORT>] [-f <HOST,PORT>] [-n <CORES>] [-c <NUM>] [-L <LEVEL>] [OPTIONS...] [<PRIVATE_KEY> <CERT>] A reverse proxy for SPDY/HTTPS. Positional arguments: <PRIVATE_KEY> Set path to server's private key. Required unless either -p or --client is specified. <CERT> Set path to server's certificate. Required unless either -p or --client is specified. OPTIONS: Connections: -b, --backend=<HOST,PORT> Set backend host and port. Default: '127.0.0.1,80' -f, --frontend=<HOST,PORT> Set frontend host and port. Default: '0.0.0.0,3000' --backlog=<NUM> Set listen backlog size. Default: 256 --backend-ipv4 Resolve backend hostname to IPv4 address only. --backend-ipv6 Resolve backend hostname to IPv6 address only. Performance: -n, --workers=<CORES> Set the number of worker threads. Default: 1 --read-rate=<RATE> Set maximum average read rate on frontend connection. Setting 0 to this option means read rate is unlimited. Default: 1048576 --read-burst=<SIZE> Set maximum read burst size on frontend connection. Setting 0 to this option means read burst size is unlimited. Default: 4194304 --write-rate=<RATE> Set maximum average write rate on frontend connection. Setting 0 to this option means write rate is unlimited. Default: 0 --write-burst=<SIZE> Set maximum write burst size on frontend connection. Setting 0 to this option means write burst size is unlimited. Default: 0 Timeout: --frontend-spdy-read-timeout=<SEC> Specify read timeout for SPDY frontend connection. Default: 180 --frontend-read-timeout=<SEC> Specify read timeout for non-SPDY frontend connection. Default: 180 --frontend-write-timeout=<SEC> Specify write timeout for both SPDY and non-SPDY frontends. connection. Default: 60 --backend-read-timeout=<SEC> Specify read timeout for backend connection. Default: 900 --backend-write-timeout=<SEC> Specify write timeout for backend connection. Default: 60 --backend-keep-alive-timeout=<SEC> Specify keep-alive timeout for backend connection. Default: 60 --backend-http-proxy-uri=<URI> Specify proxy URI in the form http://[<USER>:<PASS>@]<PROXY>:<PORT>. If a proxy requires authentication, specify <USER> and <PASS>. Note that they must be properly percent-encoded. This proxy is used when the backend connection is SPDY. First, make a CONNECT request to the proxy and it connects to the backend on behalf of shrpx. This forms tunnel. After that, shrpx performs SSL/TLS handshake with the downstream through the tunnel. The timeouts when connecting and making CONNECT request can be specified by --backend-read-timeout and --backend-write-timeout options. SSL/TLS: --ciphers=<SUITE> Set allowed cipher list. The format of the string is described in OpenSSL ciphers(1). If this option is used, --honor-cipher-order is implicitly enabled. --honor-cipher-order Honor server cipher order, giving the ability to mitigate BEAST attacks. -k, --insecure When used with -p or --client, don't verify backend server's certificate. --cacert=<PATH> When used with -p or --client, set path to trusted CA certificate file. The file must be in PEM format. It can contain multiple certificates. If the linked OpenSSL is configured to load system wide certificates, they are loaded at startup regardless of this option. --private-key-passwd-file=<FILEPATH> Path to file that contains password for the server's private key. If none is given and the private key is password protected it'll be requested interactively. --subcert=<KEYPATH>:<CERTPATH> Specify additional certificate and private key file. Shrpx will choose certificates based on the hostname indicated by client using TLS SNI extension. This option can be used multiple times. --backend-tls-sni-field=<HOST> Explicitly set the content of the TLS SNI extension. This will default to the backend HOST name. --dh-param-file=<PATH> Path to file that contains DH parameters in PEM format. Without this option, DHE cipher suites are not available. --verify-client Require and verify client certificate. --verify-client-cacert=<PATH> Path to file that contains CA certificates to verify client certificate. The file must be in PEM format. It can contain multiple certificates. --client-private-key-file=<PATH> Path to file that contains client private key used in backend client authentication. --client-cert-file=<PATH> Path to file that contains client certificate used in backend client authentication. --tls-proto-list=<LIST> Comma delimited list of SSL/TLS protocol to be enabled. The following protocols are available: TLSv1.2, TLSv1.1, TLSv1.0, SSLv3 The name matching is done in case-insensitive manner. The parameter must be delimited by a single comma only and any white spaces are treated as a part of protocol string. Default: TLSv1.2,TLSv1.1,TLSv1.0 SPDY: -c, --spdy-max-concurrent-streams=<NUM> Set the maximum number of the concurrent streams in one SPDY session. Default: 100 --frontend-spdy-window-bits=<N> Sets the per-stream initial window size of SPDY frontend connection to 2**<N>. Default: 16 --frontend-spdy-connection-window-bits=<N> Sets the per-connection window size of SPDY frontend connection to 2**<N>. Default: 16 --frontend-spdy-no-tls Disable SSL/TLS on frontend SPDY connections. SPDY protocol must be specified using --frontend-spdy-proto. This option also disables frontend HTTP/1.1. --frontend-spdy-proto Specify SPDY protocol used in frontend connection if --frontend-spdy-no-tls is used. Default: spdy/3.1 --backend-spdy-window-bits=<N> Sets the per-stream initial window size of SPDY backend connection to 2**<N>. Default: 16 --backend-spdy-connection-window-bits=<N> Sets the per-connection window size of SPDY backend connection to 2**<N>. Default: 16 --backend-spdy-no-tls Disable SSL/TLS on backend SPDY connections. SPDY protocol must be specified using --backend-spdy-proto --backend-spdy-proto Specify SPDY protocol used in backend connection if --backend-spdy-no-tls is used. Default: spdy/3.1 Mode: -s, --spdy-proxy Enable secure SPDY proxy mode. --spdy-bridge Communicate with the backend in SPDY. Thus the incoming SPDY/HTTPS connections are converted to SPDY connection and relayed to the backend. See --backend-http-proxy-uri option if you are behind the proxy and want to connect to the outside SPDY proxy. --client Instead of accepting SPDY/HTTPS connection, accept HTTP connection and communicate with backend server in SPDY. To use shrpx as a forward proxy, use -p option instead. -p, --client-proxy Like --client option, but it also requires the request path from frontend must be an absolute URI, suitable for use as a forward proxy. Logging: -L, --log-level=<LEVEL> Set the severity level of log output. INFO, WARNING, ERROR and FATAL. Default: WARNING --accesslog Print simple accesslog to stderr. --syslog Send log messages to syslog. --syslog-facility=<FACILITY> Set syslog facility. Default: daemon Misc: --add-x-forwarded-for Append X-Forwarded-For header field to the downstream request. --no-via Don't append to Via header field. If Via header field is received, it is left unaltered. -D, --daemon Run in a background. If -D is used, the current working directory is changed to '/'. --pid-file=<PATH> Set path to save PID of this program. --user=<USER> Run this program as USER. This option is intended to be used to drop root privileges. --conf=<PATH> Load configuration from PATH. Default: /etc/shrpx/shrpx.conf -v, --version Print version and exit. -h, --help Print this help and exit.
For those of you who are curious, shrpx
is an abbreviation of
"Spdy/https to Http Reverse ProXy".
Without any of -s
, --spdy-bridge
, -p
and --client
options, shrpx
works as reverse proxy to the backend server:
Client <-- (SPDY, HTTPS) --> Shrpx <-- (HTTP) --> Web Server [reverse proxy]
With -s
option, it works as secure SPDY proxy:
Client <-- (SPDY, HTTPS) --> Shrpx <-- (HTTP) --> Proxy [SPDY proxy] (e.g., Squid)
The Client
in the above is needs to be configured to use shrpx as
secure SPDY proxy.
At the time of this writing, Chrome is the only browser which supports secure SPDY proxy. The one way to configure Chrome to use secure SPDY proxy is create proxy.pac script like this:
function FindProxyForURL(url, host) { return "HTTPS SERVERADDR:PORT"; }
SERVERADDR
and PORT
is the hostname/address and port of the
machine shrpx is running. Please note that Chrome requires valid
certificate for secure SPDY proxy.
Then run chrome with the following arguments:
$ google-chrome --proxy-pac-url=file:///path/to/proxy.pac --use-npn
Note
At the time of this writing, Chrome 24 limits the maximum
concurrent connections to the proxy to 32. And due to the
limitation of socket pool handling in Chrome, it is quickly filled
up if SPDY proxy is used and many SPDY sessions are established. If
it reaches the limit, the new connections are simply blocked until
existing connections are timed out. (See Chrome Issue 92244). The
workaround is make the number of maximum connections high, say, 99,
which is the highest. To do this, you need to change so called
Policy setup. See Policy Templates for
details how to change Policy setup on the platform you use. The
Policy name we are looking for is MaxConnectionsPerProxy
For example, if you are using Linux, follow the instruction
described in Linux Quick Start and
create /etc/opt/chrome/policies/managed/test_policy.json
file
with the following content and restart Chrome:
{ "MaxConnectionsPerProxy" :99 }
With --spdy-bridge
, it accepts SPDY/HTTPS connections and
communicates with backend in SPDY:
Client <-- (SPDY, HTTPS) --> Shrpx <-- (SPDY) --> Web or SPDY Proxy etc [SPDY bridge] (e.g., shrpx -s)
With -p
option, it works as forward proxy and expects that the
backend is secure SPDY proxy:
Client <-- (HTTP) --> Shrpx <-- (SPDY) --> Secure SPDY Proxy [forward proxy] (e.g., shrpx -s or node-spdyproxy)
The Client
is needs to be configured to use shrpx as forward proxy.
In this configuration, clients which do not support secure SPDY proxy
can use secure SPDY proxy through shrpx
. Putting shrpx
in the
same box or same network with the clients, this configuration can
bring the benefits of secure SPDY proxy to those clients. Since the
maximum number of connections per server still applies in proxy
connection, the performance gain is not obvious. For example, if the
maximum number of connections per server is 6, after sending 6
requests to the proxy, client blocks further requests, which kills
performance which might be gained in SPDY connection. For clients
which can tweak these values (e.g.,
network.http.max-connections-per-server
in Firefox), increasing
them may improve the performance.
With --client
option, it works as reverse proxy and expects that
the backend is SPDY-enabled Web server:
Client <-- (HTTP) --> Shrpx <-- (SPDY) --> Web Server [reverse proxy]
For the operation modes which talk to the backend in SPDY, the backend
connections can be tunneled though HTTP proxy. The proxy is specified
using --backend-http-proxy-uri
option. The following figure
illustrates the example of --spdy-bridge
and
--backend-http-proxy-uri
option to talk to the outside SPDY proxy
through HTTP proxy:
Client <-- (SPDY, HTTPS) --> Shrpx <-- (SPDY) -- [SPDY bridge] --===================---> SPDY Proxy (HTTP proxy tunnel) (e.g., shrpx -s)
The examples directory contains a simple SPDY client implementation in C.
The library comes with Python wrapper python-spdylay
. See
python
directory.