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Cjango-Unchained

Cjango is a lightweight C++ Web framework that provides high-speed server responses and aims for Django-like usability.

Installation

git clone [email protected]:mengdilin/Cjango-Unchained.git

# -std=c++1z needs recent g++, so
# on Ubuntu 14.04
sudo add-apt-repository ppa:ubuntu-toolchain-r/test
sudo apt-get update
sudo apt-get install g++-6

cd Cjango-Unchained

make
# or make -j[number of cores] on multicore machines
# e.g. "make -j2"

# -C: search Makefile (default) in the specified subdir
# same as "cd callbacks && make ; cd .."
make -C callbacks

Usage

python manage.py runserver 8000         # if you prefer more Django-like execution

or

./runapp runserver 8000                 # directly execute C++ if you don't have Python installed

And access to http://127.0.0.1:8000 shows Cjango welcome page.

Demo

To run the 2 demos under the demo folder

make -C demo/http-get-demo/callbacks
python manage.py runserver 8000 --setting apps/http-get-demo/json/settings.json

or

sudo apt-get install libsqlite3-dev           # On Ubuntu for no <sqlite3.h> error
make -C demo/http-get-demo/callbacks
python manage.py runserver 8000 --setting apps/http-post-demo/json/settings.json

Unit Tests and Integration Tests

Cjango has unit tests for individual components of the library: Router and http_parser functionalities. To run these unit tests:

cd src/
make clean & make test
make test-run

Additionally, Cjango provides end-to-end integration tests (refer to test/ for details)

make clean & make & make clean -C apps/http-post-demo/callbacks/ & make -C apps/http-post-demo/callbacks/
python manage.py runserver 8000 --setting apps/http-post-demo/json/settings.json &
cd test/
python test.py --lib verifications_post_demo --config config.json test_post_demo.json

Main files

  • Cjango-Unchained ... root directory (can be renamed)
    • callbacks ... default directory for you to write C++ functions
    • json ... json files for app configurations
    • templates ... default directory for storing template html files
    • static ... default directory for static files like images
    • src ... Cjango C++ codes. Usually you don't have to look into it.
    • Makefile ... Makefile to compile Cjango
    • manage.py ... A wrapper script for running src/runapp executable conveniently

Features

Asyncronous request handling

Cjango adopts the asyncronous socket request handling. It is able to establish multiple socket connections simultaneously without blocking. The maximum number of concurrent connections it can handle depends on system specification.

Regular expression URL matching

As in Django, Cjango deal with URL routing by regex matching. All matching rules are written in urls.json as like in Django's urls.py. The earlier rules have higher priorities (first-match, first-served).

urls.json is dynamically (i.e. at runtime) loaded into our routing logic and enables each callback function to be compiled separately from main application. This is the most notable functionality in Cjango.

Template file rendering by HttpResponse::render_to_response()

All template files are placed under callbacks/templates. And in source files, they can be referenced by callbacks/templates/<file name> (Note: the relative path is started from runapp executable, not from each callback object files).

HTTP 1.0 Compatibility with Session Support

Cjango provides a HttpSession object that provides a way to identify a user across more than one page request or visit to a Web site and to store information about that user. The session object is implemented on top of the cookie functionality that Cjango also provides.

As of April 2017, Cjango can handle HTTP 1.0 requests and responses.

Cjango supports Http session (similar with django.contrib.sessions).

Json Support

python manage.py runserver 8000
# On another terminal

PCUser@abc callbacks (master) $ curl -s http://127.0.0.1:8000/json | jq '.'
{
  "parents": [
    {
      "sha": "54b9c9bdb225af5d886466d72f47eafc51acb4f7",
      "url": "https://api.github.com/repos/stedolan/jq/commits/54b",
      "html_url": "https://github.com/stedolan/jq/commit/54b"
    },
    {
      "sha": "8b1b503609c161fea4b003a7179b3fbb2dd4345a",
      "url": "https://api.github.com/repos/stedolan/jq/commits/8b1",
      "html_url": "https://github.com/stedolan/jq/commit/8b1"
    }
  ]
}
PCUser@abc callbacks (master) $ curl -s http://127.0.0.1:8000/json | jq '.parents[0]'
{
  "sha": "54b9c9bdb225af5d886466d72f47eafc51acb4f7",
  "url": "https://api.github.com/repos/stedolan/jq/commits/54b",
  "html_url": "https://github.com/stedolan/jq/commit/54b"
}

Whitelist-based debug messages

Suppose that you compiled Cjango in debug mode (make DEBUG=1). If you run Cjango simply by ./runapp runserver 8000 , you would see a flooding number of debugging messages like this:

user@host Cjango-Unchained $ ./runapp runserver 8000

[20170416 20:00:03.857] [route] [info] [router.cpp:112:load_all] loaded urls.json
[20170416 20:00:03.857] [route] [info] [router.cpp:19:add_route] updated route: /
[20170416 20:00:03.858] [route] [info] [router.cpp:19:add_route] updated route: /cjango
[20170416 20:00:03.858] [route] [info] [router.cpp:19:add_route] updated route: /[0-9]{4}/[0-9]{2}
[20170416 20:00:03.859] [route] [info] [router.cpp:19:add_route] updated route: /home
[20170416 20:00:03.860] [skt] [info] [app.cpp:292:run] Invoked for port: 8000
[20170416 20:00:03.860] [skt] [info] [app.cpp:304:run] Created server socket: 5
[20170416 20:00:03.860] [skt] [info] [app.cpp:250:spawn_monitor_thread] detached a new thread
[20170416 20:00:11.428] [skt] [info] [app.cpp:376:run] Number of sockets readable: 1
[20170416 20:00:11.428] [skt] [info] [app.cpp:385:run] Server socket readable
[20170416 20:00:11.582] [skt] [info] [app.cpp:403:run] Client socket 21 readable
[20170416 20:00:11.582] [http] [info] [req_parser.cpp:134:get_http_request_line] uri fields:
[20170416 20:00:11.583] [http] [info] [req_parser.cpp:71:get_http_cookie] cookie: csrftoken=...
[20170416 20:00:11.583] [http] [info] [req_parser.cpp:71:get_http_cookie] cookie: session=10...
[20170416 20:00:11.583] [skt] [info] [app.cpp:119:worker] finished request
[20170416 20:00:11.583] [route] [info] [router.cpp:159:get_http_response] ret callback for /home
[20170416 20:00:11.583] [http] [info] [http_req.cpp:90:get_session] cookie:   session, 10596601
[20170416 20:00:11.583] [http] [info] [http_req.cpp:95:get_session] found session key: 10596601
[20170416 20:00:11.583] [http] [info] [http_req.cpp:96:get_session] key equals 604414511: false
[20170416 20:00:11.583] [http] [info] [http_req.cpp:102:get_session] cannot find session id: 1059...
[20170416 20:00:11.583] [skt] [info] [app.cpp:216:handle_request] Created and detached new thread
[20170416 20:00:11.584] [session] [info] [mycall.cpp:39:page_index] session id: 10596601668567
[20170416 20:00:11.584] [session] [info] [mycall.cpp:41:page_index] session:  user, unspecified
[20170416 20:00:11.584] [skt] [info] [app.cpp:155:worker] Worker thread closing socket 21
[20170416 20:00:11.902] [skt] [info] [app.cpp:376:run] Number of sockets readable: 1
[20170416 20:00:11.902] [skt] [info] [app.cpp:403:run] Client socket 22 readable
[20170416 20:00:11.902] [skt] [info] [app.cpp:174:handle_request] socket 22 recv returns: 677
[20170416 20:00:11.902] [skt] [info] [app.cpp:174:handle_request] socket 22 recv returns: -1
[20170416 20:00:11.902] [skt] [info] [app.cpp:201:handle_request] May try again later on socket 22
[20170416 20:00:11.902] [skt] [info] [app.cpp:107:worker] Worker thread invoked for socket 22
...

But if you're debugging your original callbacks with http session fucntionality, and if you know other modules are working correctly, you would like to suppress irrelavant log messages.

Cjango can hide non-informative log messages by runtime --whitelist argument.

./runapp runserver 8080 --whitelist session http

[2017-04-16 20:00:11.582] [http] [info] [req_parser.cpp:134:get_req_line] uri fields:
[2017-04-16 20:00:11.583] [http] [info] [req_parser.cpp:71:get_cookie] cookie pair:  csrftoken=TN
[2017-04-16 20:00:11.583] [http] [info] [req_parser.cpp:71:get_cookie] cookie pair:  session=1059
[2017-04-16 20:00:11.583] [http] [info] [req.cpp:90:get_session] cookie:  session, 10596601668567
[2017-04-16 20:00:11.583] [http] [info] [req.cpp:95:get_session] found session key: 10596601668567
[2017-04-16 20:00:11.583] [http] [info] [req.cpp:96:get_session] key equals 60441451194812: false
[2017-04-16 20:00:11.583] [http] [info] [req.cpp:102:get_session] cannot find session id: 1059
[2017-04-16 20:00:11.584] [session] [info] [mycallback.cpp:39:page_index] index session id: 10596601668567
[2017-04-16 20:00:11.584] [session] [info] [mycallback.cpp:41:page_index] session:  user, unspecified

User-defined logger category

Moreover, you can even add your own logger category in your callback functions without recompiling your main app executable:

extern "C" http::HttpResponse render_top_page(http::HttpRequest request) {
      ...
      _SPDLOG("cookie-v2", info, "state:  {}, {}", it->first, it->second);
      ...
}
[2017-04-16 20:00:11.584] [cookie-v2] [info] [your_callback.cpp:39:render_top_page] state: 32 58

How does this work?

Cjango defines a convenient CjangoLogger class on top of Spdlog C++ logger library.

More specifically, CjangoLogger::operator[] checks whether the specified-name logger exists before logging. If no corresponding logger exists, it would spawn a new logger with the specified name. Thus, you can add your own logger category at runtime. Again, your callback function can be compiled separately from main Cjango application*. This approach is the opposite approach of std::vector::operator[], which does not checks out-of-range condition in priority to performance.

Suppressing logs

While the above flexible log handling incurs slight runtime overhead, make DEBUG=0 disables all debugging messages and set your application in production mode. In production mode, all debugging functions are removed by preprocessing and incur no runtime overhead.

Dynamic Callback Loading

Consideration

At first, we thought to port Django's API as much as possible, and naively assumed that's a straightforward path. That was not the case. We soon found out there are a fairly large amount of design choices for implementing similar functionalities in different languages. One such example is callback handlings. Callback functions are the functions that handle coming HTTP requests and return appropriate HTTP responses. In Python's Django, every source file updated at runtime can be reloadable, and updating callback functitons are straightforward.

In existing famous C++ web application frameworks, users have to recompile the entire application every time they change callback functions which handle coming HTTP requests. All callback functions are defined in application routing logic, and cannot be loadable to a running app as far as we researched.

Cjango solves this issue by leveraging Dynamic Loading functionality. In Cjango, users can modify/add URL-callback hashmaps and callbacks themselves without any server downtime. All URL-callback mappings are written in callbacks/urls.json. When you change the urls.json file, cjango monitors and detects the json file change and dynamically reload your new functions. This is inspired by a 3D C++ racing game "HexRacer" which employs text configuration files as dynamic loading triggers.

Example 1: Changing an existing callback to another function

When your main application is invoked, Cjango automatically spawns a file-monitoring thread by spawn_monitor_thread() before an http request handling event loop of App class. The monotoring thread checks the callbacks/urls.json change for every one second by App::monitor_file_change(), and if it's changed, reloading the routing file to update callback hashmaps (Router::pattern_to_callback) by Router::load_url_pattern_from_file(). More specifically, all .so files specified in the callbacks/urls.json file are loaded by Router::load_shared_object_file() and then Cjango loads callbacks from the files by Router::load_callback().

Note that if the specified .so file is not located to the path, Cjango instead loads a default callback function which returns 500 Internal Server Error on web browsers and generates a debugging message to terminal.

For example, suppose you defined render_with_db_fast and render_with_db_fast_v2 in your callbacks/db-access.cpp. If your callback function is written in a single file, you can compile your callback function without writing single line of Make commands.

$ make
g++ -std=c++1z -Wall -DCJANGO_DYNLOAD -I./../app/ -I./../lib/ -fPIC -c db-access.cpp
g++ -std=c++1z -Wall -DCJANGO_DYNLOAD -I./../app/ -I./../lib/ -L./../app/ -lhttp_response -lhttp_request -shared -o db-access.so db-access.o

$ ls
db-access.cpp    db-access.o   db-access.so   urls.json

Then, let's modify your urls.json from

{
  "/booklist" : {
    "file" : "callbacks/db-access.so",
    "funcname": "render_with_db_fast"
  }
}

to

{
  "/booklist" : {
    "file" : "callbacks/db-access.so",
    "funcname": "render_with_db_fast_v2"
  }
}

Immediately after you saved the urls.json, Cjango's file-monitoring thread detects the change and automatically reloads your render_with_db_fast_v2 callback function. You don't need a hassle to make all application -- just 2 characters change.

If you're a traditional C++ programer, you can also stores old callback functions by shared object version numbers (e.g. db-access.so.0.1 or db-access.so.0.2) and a soft link to db-access.so.

Example 2: Updating an existing callback to its newer version (with same name)

Since the file-monitoring thread just checks the url-mapping file, it's possible that the thread doesn't notice the shared object file even if you updated your callback function. However, the solution is simple -- just to enable commented-out touch urls.json command. touch changes the urls.json's recent modification time, and then Cjango can notice its change.

Error Handlings
  • Case 1: Typo in callback file/function name (non-existent callbacks). These cases are thrown as invalid function specified error in debug mode, and 500 Internal Server Error in production mode.
  • Case 2: No URL pattern match. These cases are 404 Not Found error.

Credits

Libraries