Jordan Bancino
662696ce12
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This pull request brings Cytoplasm up from C89 to C99, which makes it much more portable across platforms. In particular, this pull request solves a number of issues with 32-bit platforms. Closes #28. Closes #12. Closes #20. Reviewed-on: #29 |
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.gitea/workflows | ||
examples | ||
man | ||
src | ||
tools | ||
.gitignore | ||
.indent.pro | ||
CHANGELOG.md | ||
configure | ||
LICENSE.txt | ||
README.md |
Cytoplasm (libcytoplasm
)
Cytoplasm is a general-purpose C library for creating high-level (particularly networked and multi-threaded) C applications. It allows applications to take advantage of the speed, flexibility, and simplicity of the C programming language, while providing helpful code to allow applications to perform various complex tasks with minimal effort. Cytoplasm provides high-level data structures, a basic logging facility, an HTTP client and server, and more. It also reports memory leaks, which can aid in debugging.
Cytoplasm aims not to only do one thing well, but to do many things good enough. This is in contrast to other libraries, which only do one thing and thus require the developer to pull in many different libraries. The primary target of Cytoplasm is simple yet higher level C applications that have to perform relatively complex tasks, but don't want to depend on a large number of dependencies.
Cytoplasm is extremely opinionated on the way programs using it are written. It strives to create a comprehensive and tightly-integrated programming environment, while also maintaining C programming correctness. It doesn't do any macro magic or make C look like anything other than C. It is written entirely in C89, and depends only on a POSIX environment. This differentiates it from other general-purpose libraries that often require modern compilers and non-standard language and environment features. Cytoplasm is intended to be extremely portable and simple, while still providing some of the functionality expected in higher-level programming languages in a platform-agnostic manner. In the case of TLS, Cytoplasm wraps low-level TLS libraries to offer a single, unified interface to TLS so that programs do not have to care about the underlying implementation.
Cytoplasm is probably not suitable for embedded programming. It makes liberal use of the heap, and while data structures are designed to conserve memory where possible and practical, minimal memory usage is not really a design goal for Cytoplasm, although Cytoplasm takes care not to use any more memory than it absolutely needs. Cytoplasm also wraps a few standard libraries with additional logic and checking. While this ensures better runtime safety, this inevitably adds a little overhead, which may be unsuitable for time- or space-critical tasks.
Originally a part of Telodendria (https://telodendria.io), a Matrix homeserver written in C, Cytoplasm was split off into its own project due to the desire of some Telodendria developers to use Telodendria's code in other projects. Cytoplasm is still an official Telodendria project, but it is designed specifically to be distributed and used totally independent of Telodendria.
The name "Cytoplasm" was chosen for a few reasons. It plays off the precedent set up by the Matrix organization in naming projects after the parts of a neuron. It also speaks to the function of Cytoplasm. The cytoplasm of a cell is the supporting material. It is what gives the cell its shape, and it facilitates the movement of materials to the other cell parts. Likewise, Cytoplasm aims to provide a support mechanism for C applications that have to perform complex tasks beyond what the C standard library provides.
Cytoplasm also starts with a C, which I think is a nice touch for C libraries. It's also fun to say and unique enough that searching for "libcytoplasm" should bring you to this project and not some other one.
Requirements
Cytoplasm makes the following assumptions about the underlying hardware:
- It has words sizes that are powers of 2, and a native 32-bit integer type exists.
- Integers are represented using two's compliment for negatives.
The ANSI C standard requires an integer type of at least 32 bits, but does not require any more. If Cytoplasm is built on 32-bit platforms that don't provide a native 64-bit integer type, Cytoplasm emulates 64-bit integers. This can make it more portable.
Cytoplasm aims to have zero software dependencies beyond what is mandated by POSIX. You only need the standard math and pthread libraries to build it. TLS support can optionally be enabled with the configuration script. The supported TLS implementations are as follows:
- OpenSSL
- LibreSSL
If TLS support is not enabled, all APIs that use it should fall back to non-TLS behavior in a sensible manner. For example, if TLS support is not enabled, then the HTTP client API will simply return an error if a TLS connection is requested.
Building
If your operating system or software distribution provides a pre-built package of Cytoplasm, you should prefer to use that instead of building it from source.
Cytoplasm uses the standard C library build procedure. Just run these commands:
./configure
make
This will produce the following out/ directory:
out/
lib/
libcytoplasm.so - The Cytoplasm shared library.
libcytoplasm.a - The Cytoplasm static archive.
bin/ - A few useful tools build with Cytoplasm.
man/ - All Cytoplasm API documentation.
You can also run make install
as root
to install Cytoplasm to the system. This will install the libraries, tools, and man
pages.
The configure
script has a number of optional flags, which are as follows:
--with-(openssl|libressl)
: Select the TLS implementation to use. OpenSSL is selected by default.--disable-tls
: Disable TLS altogether.--prefix=<path>
: Set the install prefix to set by default in theMakefile
. This defaults to/usr/local
, which should be appropriate for most Unix-like systems.--(enable|disable)-ld-extra
: Control whether or not to enable additional linking flags that create a more optimized binary. For large compilers such as GCC and Clang, these flags should be enabled. However, if you are using a small or more obscure compiler, then these flags may not be supported, so you can disable them with this option.--(enable|disable)-debug
: Control whether or not to enable debug mode. This sets the optimization level to 0 and builds with debug symbols. Useful for running with a debugger.--static
and--no-static
: Controls whether static binaries for tools are built by default. On BSD systems,--static
is perfectly acceptable, but on GNU systems,--no-static
is often desirable to silence warnings about static binaries emitted by the GNU linker.
Cytoplasm can be customized with the following options:
--lib-name=<name>
: The output name of the library. This defaults toCytoplasm
and should in most cases not be changed.--lib-version=<version>
: The version string to embed in the library binaries. This can be used to indicate build customizations or non-release versions of Cytoplasm.
The following recipes are available in the generated Makefile
:
all
: This is the default target. It builds everything.Cytoplasm
: Build thelibCytoplasm.(so|a)
binaries. If you specified an alternative--lib-name
, then this target will be named after that.docs
: Generate the header documentation asman
pages.tools
: Build the supplemental tools which may be useful for development.clean
: Remove the build and output directories. Cytoplasm builds are out-of-tree, which greatly simplifies this recipe compared to in-tree builds.
If you're developing Cytoplasm, these recipes may also be helpful:
format
: Format the source code usingindent
. This may require a BSDindent
because last time I tried GNUindent
, it didn't like the flags inindent.pro
. Your mileage may vary.license
: Update the license headers in all source code files with the contents of theLICENSE.txt
.
To install Telodendria to your system, the following recipes are available:
install
: This installs Cytoplasm under the prefix set with./configure --prefix=<dir>
or withmake PREFIX=<dir>
. By default, themake
PREFIX
is set to whatever was set withconfigure --prefix
.uninstall
: Uninstall Cytoplasm from the same prefix as specified above.
After a build, you can find the object files in build/
and the output binaries in out/lib/
.
Usage
Cytoplasm provides the typical .so and .a files, which can be used to link programs with it in the usual way. Somewhat unusually for C libraries, however, it provides its own main()
function, so programs written with Cytoplasm provide Main()
instead, which is called by Cytoplasm. Cytoplasm works this way because it needs to perform some setup logic before user code runs and some teardown logic after user code returns.
Here is the canonical Hello World written with Cytoplasm:
#include <Cytoplasm/Log.h>
int Main(void)
{
Log(LOG_INFO, "Hello World!");
return 0;
}
If this file is Hello.c
, then you can compile it by doing this:
$ cc -o hello Hello.c -lCytoplasm
The full form of Main()
expected by the stub is as follows:
int Main(Array *args, HashMap *env);
The first argument is a Cytoplasm array of the command line arguments, and the second is a Cytoplasm hash map of environment variables. Most linkers will let programs omit the env
argument, or both arguments if you don't need either. The return value of Main()
is returned to the operating system, as would be expected.
Note that both arguments to Main may be treated like any other Cytoplasm array or hash map. However, do not invoke ArrayFree()
or HashMapFree()
on the passed pointers, because memory is cleaned up after Main()
returns.
License
All of the code and documentation for Cytoplasm is licensed under the same license as Telodendria itself. Please refer to Telodendria → License for details.
The Cytoplasm logo was designed by Tobskep and is licensed under the Creative Commons Attribution-ShareAlike 4.0 license.