Ok, so this used to be a dead project. It required calling out to all sorts of hackery to generate PHP extensions, or PHP itself.
Now, thanks to FFI landing in PHP 7.4, the potential for all sorts of crazy is HUGE.
So here we go :)
Install PHP 7.4, being sure to enable the FFI extension, OpenSSL extension, mbstring extension, and zlib extension (--with-ffi --with-openssl --enable-mbstring --with-zlib
).
Also, you need to install the system dependency llvm-4.0
. On Ubuntu:
me@local:~$ sudo apt-get install llvm-4.0-dev clang-4.0
Then run composer install
.
This project comes with one working and one non-working (yet) Dockerfile. The makefile uses a reasonably old version of Ubuntu (16.04), and once FFIMe is fixed for newer versions of glibc, it will switch to use 18.04 (or newer).
To build, use make:
me@local:~$ make build
This will take a while (upwards of 10 minutes likely). It will install an Ubuntu container with a custom compile of PHP-7.4 and everything you need to get up and running. It will also composer install all dependencies as well as run the pre-processor. Once it's done, you can run tests:
me@local:~$ make test
This will execute all unit tests inside the container.
To run your own code or play with the compiler, you can open a shell using make shell
:
me@local:~$ make shell
root@662c59ae4527:/compiler# php bin/jit.php -r 'echo "Hello World\n";'
Hello World
There are three main ways of using this compiler:
This compiler mode implements its own PHP Virtual Machine, just like PHP does. This is effectively a giant switch statement in a loop.
No, seriously. It's literally a giant switch statement...
Practically, it's a REALLY slow way to run your PHP code. Well, it's slow because it's in PHP, and PHP is already running on top of a VM written in C.
But what if we could change that...
This compiler mode takes PHP code and generates machine code out of it. Then, instead of letting the code run in the VM above, it just calls to the machine code.
It's WAY faster to run (faster than PHP 7.4, when you don't account for compile time).
But it also takes a long time to compile (compiling is SLOW, because it's being compiled from PHP).
Every time you run it, it compiles again.
That brings us to our final mode:
This compiler mode actually generates native machine code, and outputs it to an executable.
This means, that you can take PHP code, and generate a standalone binary. One that's implemented without a VM. That means it's (in theory at least) as fast as native C.
Well, that's not true. But it's pretty dang fast.
There are four CLI entrypoints, and all 4 behave (somewhat) like the PHP cli:
php bin/vm.php
- Run code in a VMphp bin/jit.php
- Compile all code, and then run itphp bin/compile.php
- Compile all code, and output a.o
file.php bin/print.php
- Compile and output CFG and the generated OpCodes (useful for debugging)
Specifying code from STDIN
(this works for all 4 entrypoints):
me@local:~$ echo '<?php echo "Hello World\n";' | php bin/vm.php
Hello World
You can also specify on the CLI via -r
argument:
me@local:~$ php bin/jit.php -r 'echo "Hello World\n";'
Hello World
And you can specify a file:
me@local:~$ echo '<?php echo "Hello World\n";' > test.php
me@local:~$ php bin/vm.php test.php
When compiling using bin/compile.php
, you can also specify an "output file" with -o
(this defaults to the input file, with .php
removed). This will generate an executable binary on your system, ready to execute
me@local:~$ echo '<?php echo "Hello World\n";' > test.php
me@local:~$ php bin/compile.php -o other test.php
me@local:~$ ./other
Hello World
Or, using the default:
me@local:~$ echo '<?php echo "Hello World\n";' > test.php
me@local:~$ php bin/compile.php test.php
me@local:~$ ./test
Hello World
If you pass the -l
parameter, it will not execute the code, but instead just perform the compilation. This will allow you to test to see if the code even will compile (hint: most currently will not).
Sometimes, you want to see what's going on. If you do, try the bin/print.php
entrypoint. It will output two types of information. The first is the Control Flow Graph, and the second is the compiled opcodes.
me@local:~$ php bin/print.php -r 'echo "Hello World\n";'
Control Flow Graph:
Block#1
Terminal_Echo
expr: LITERAL<inferred:string>('Hello World
')
Terminal_Return
OpCodes:
block_0:
TYPE_ECHO(0, null, null)
TYPE_RETURN_VOID(null, null, null)
Right now, this only supports an EXTREMELY limited subset of PHP. There is no support for dynamic anything. Arrays aren't supported. Neither Object properties nor methods are supported. And the only builtin functions that are supported are var_dump
and strlen
.
But it's a start...
Since this is bleeding edge, debuggability is key. To that vein, both bin/jit.php
and bin/compile.php
accept a -y
flag which will output a pair of debugging files (they default to the prefix of the name of the script, but you can specify another prefix following the flag).
me@local:~$ echo '<?php echo "Hello World\n";' > demo.php
me@local:~$ php bin/compile.php -y demo.php
# Produces:
# demo - executable of the code
# demo.bc - LLVM intermediary bytecode associated with the compiled code
# demo.s - assembly generated by the compiled code
Checkout the examples folder.
So, is this thing any fast? Well, let's look at the internal benchmarks. You can run them yourself with make bench
, and it'll give you the following output (running 5 iterations of each test, and averaging the time).
Check out the results in the Benchmarks folder.
This is after the port to using LLVM under the hood. So the port to LLVM appears to have been well worth it, even just from a performance standpoint.
To run the benchmarks yourself, you need to pass a series of ENV vars for each PHP version you want to test. For example, the above chart is generated with::
Without opcache doing optimizations, the bin/jit.php
is actually able to get close to native PHP with ack(3,9) and mandelbrot (without opcache) for 7.3 and 7.4. It's even able to hang with PHP 8's experimental JIT compiler for ack(3,9). For ack(3,10) it's able to be the fastest execution method.
Most other tests are actually WAY slower with the bin/jit.php
compiler. That's because the test itself is slower than the baseline time to parse and compile a file (about 0.2 seconds right now).
And note that this is running the compiler on top of PHP. At some point, the goal is to get the compiler to compile itself, hopefully cutting the time to compile down by at least a few hundred percent.
Simply look at the difference between everything and the "compiled time" column (which is the result of the AOT compiler generating a binary). This shows the potential in this compilation approach. If we can solve the overhead of parsing/compiling in PHP for the bin/jit.php
examples, then man could this fly...
So yeah, there's definitely potential here... evil grin