This repository contains the source code for the projectM Expression Evaluation Library, short "projectm-eval", which is a cross-platform and cross-architecture reimplementation of Milkdrop's pendant, the NullSoft Expression Evaluation Library 2, or short "ns-eel2".
This library aims at being as portable as possible, sacrificing some performance over portability. The original ns-eel2 library directly assembles machine code from compiled assembler fragments. While this is super performant, the assembler code needs to be rewritten manually for every target platform and CPU architecture and is really hard to read or edit.
projectM's Expression Evaluation Library was implemented as a separate project and put under the MIT license to make it useful in other projects, open source and closed source, while the core projectM library stays under the LGPL license.
Implementation and usage details can be found in the "docs" subdirectory.
The projectM Expression Evaluation Library is always being built as a static library. It can also be used as an object library in a subproject of other CMake projects, see the instructions below on how to use it this way.
If you just want to build the library, no other dependencies besides a working toolchain, CMake (3.20 or higher) and a build processor like Make, Ninja, Visual Studio or Xcode are required.
To recreate the parser and lexer or to run tests, additional dependencies need to be installed:
- Bison 3.8 and Flex 2.6 to regenerate the code compiler from the .y/.l files.
- GTest 1.10 or higher to run the unit tests
- Google Benchmark to run the benchmarks.
To specify custom locations for Bison and Flex, set BISON_EXECUTABLE and FLEX_EXECUTABLE accordingly when configuring the project.
For a default build, the library doesn't need any additional specifiers other than the standard CMake parameters like source dir, build dir and generator. Execute the following commands from the source directory (where this file resides):
mkdir cmake-build
cmake -S . -B cmake-build -DCMAKE_BUILD_TYPE=Release -DCMAKE_INSTALL_PREFIX=/path/to/install/dir
cmake --build cmake-build
cmake --install cmake-buildThe resulting files can then be used in other projects. See the Quick Start Guide below for details.
The following guide gives a short overview on what is needed to get your first script running.
If you need to use the ns-eel2 API, please refer to the NullSoft shim ReadMe instead.
If you want to use projectM-Eval as an external project in your CMake builds, use find_package() in your project's
CMakeLists.txt:
find_package(projectM-Eval REQUIRED)You may need to point CMake to the installation directory via
the CMAKE_PREFIX_PATH variable.
To add the include dir and link the static library, simply link the projectM::Eval target to your target, application
or library:
add_executable(MyApp
# Sources go here
)
target_link_libraries(MyApp
PRIVATE
projectM::Eval
)Important: If your final target is a static library, this will not copy any code into it! Any application using this
static library will also have to link the projectM::Eval static library. To include the projectM-Eval object code into
another static library, use the object library/subproject approach below.
If projectM-Eval is an integral part of your project, adding it as a subproject inside the source tree may be the best approach, as it will reduce the number of external dependencies and makes building easier.
If possible, using git submodules is highly recommended as it makes updating the sources from upstream easier. Copying the code into the source tree is also fine though.
Given the sources are checked out/copied to a subdirectory named "projectm-eval" of the directory with the current CMakeLists.txt, simply adding the subdirectory will suffice:
add_subdirectory(projectm-eval)After this include directive, the projectM::Eval target is available for linking, same as with the external package
variant. To link the library as a static library, the CMake code is identical:
add_executable(MyApp
# Sources go here
)
target_link_libraries(MyApp
PRIVATE
projectM::Eval
)If the target is a static library, to which the projectM-Eval object files should be added, then an additional line in the target source list is required:
add_library(MyLib STATIC
$<TARGET_OBJECTS:projectM::Eval>
# Other sources go here
)
target_link_libraries(MyApp
PRIVATE
projectM::Eval
)Note that the library still needs to be linked. While this won't add any code to the target, it will populate the required include directories and compiler flags needed to use the headers.
If CMake is not an option, the static library can be linked manually and the projectm-eval.h header file can be copied
into the project or pointed to via the include directory settings of the build system used.
To use it as an object library, please refer to the platform build tools on how to unpack the static library into its object files or how to copy its contents into another static library.
To integrate projectM-Eval into another application, only a few steps are required to get things set up:
- Implement the memory locking callbacks.
- Create an execution context.
- Compile some code.
- Register and set variables.
- Run the code.
- Destroy the code and context.
Optionally, custom global memory handling can be used. Please see the memory handling docs for details.
In production code, always check returned pointers before using them!
In most cases, multi-threading will not be used, so the memory stubs can be empty functions. Either add a separate code file, or put the following code into any existing implementation file:
#include <projectm-eval.h>
void projectm_eval_memory_host_lock_mutex() {}
void projectm_eval_memory_host_unlock_mutex() {}In C, including the header is optional. If the file is a C++ file, either including the header or adding extern "C"{}
around the implementations is mandatory to prevent the compiler from performing C++ name mangling on the functions.
To run any code, an execution context is required. It will maintain the variables and megabuf data, while also giving access to the reg variables and gmegabuf as needed. In this example, we'll use the internal global memory structures for simplicity, thus we create the context by passing NULL to both parameters.
#include <projectm-eval.h>
#include <stdio.h>
int main()
{
struct projectm_eval_context* ctx = projectm_eval_context_create(NULL, NULL);
/* Insert additional code here */
return 0;
}Now that the context is created, we can already compile code:
struct projectm_eval_code* code = projectm_eval_code_compile(ctx, "x = a; y = 2;");If the code couldn't be compiled, NULL is returned. The projectm_eval_get_error() function can be used to retrieve the
parser error, including line and column.
The above code will surely compile, but uses a variable a which isn't set explicitly. If that's the case, any variable
that was never set before will have an initial value of 0. Yet in most cases, expressions will run on some input from
the application, so in this example, a would be the input. To pass a value to the code, we can register the variable
and use the returned pointer to set or read the value. In this example, we register all three variables and set a
to 100 initially:
PRJM_EVAL_F* var_a = projectm_eval_context_register_variable(ctx, "a");
PRJM_EVAL_F* var_x = projectm_eval_context_register_variable(ctx, "x");
PRJM_EVAL_F* var_y = projectm_eval_context_register_variable(ctx, "y");
*var_a = 100.0;The internal reg00 to reg99 variables can be registered in the same way.
The megabuf and gmegabuf contents cannot be accessed from the outside. If that is required, compile an expression that copies it into a normal variable, register the variable, then execute the code and read the variable contents.
Now the code can be executed:
projectm_eval_code_execute(code);Note that only the code handle is required. The context is stored inside this opaque structure, as any compiled code is firmly tied to a single context. This said, executing code after destroying the context it was compiled in will crash the application!
In this example, the return value of projectm_eval_code_execute() is ignored. If your application is not interested in
variables, but the result of the last statement in the expression, this is the value returned by the function. In this
example, it would be 2, as this is the result of the y = 2 expression.
The execution has changed the contents of the x and y variables, so we can now output all three values to see their
actual contents:
printf("a = %f\nx = %f\ny = %f\n", *var_a, *var_x, *var_y);After we're done with the context and code, everything should be cleaned up properly:
projectm_eval_code_destroy(code);
projectm_eval_context_destroy(ctx);A few notes on cleanup:
- The order in which the context, code handles and memory buffers are destroyed doesn't matter.
- After destroying a handle, do not use this handle or any associated data, e.g. registered variables after the context was destroyed. This will crash the application.
- Code handles can be destroyed right after execution. As variables are stored in the context, their values remain unchanged as long as the context isn't destroyed.
- Never call
free()on the registered variable pointers. The memory they point to is owned and freed by the context.
The docs directory contains a few more documents regarding the API and expression syntax:
- Compiler Internals: A few technical details on how the projectM-Eval compiler/parser works internally.
- Expression Syntax: Full documentation on the expression code syntax, including tricks and caveats. This document is also valid for the original Milkdrop parser.
- Memory Handling: Additional information for using global memory buffers and share them between contexts, plus multi-threading considerations.
If there are still open questions, feel free to visit us on our Discord server. An invitation link can be found in the libprojectM repository on GitHub.
For bugs and feature requests, feel free to contribute a pull request or open an issue in the bug tracker.
