HAT file format
HAT is a format for packaging compiled libraries in the C programming language. HAT stands for "Header Annotated with TOML", and implies that standard C header files are decorated with useful metadata in the TOML markup language.
A HAT package includes one library file and one or more .hat
files. The library file can be a static library (a .a
file on Posix systems or a .lib
file on Windows systems) or a dynamic library (a .so
file on Posix systems or a .dll
file and its accompanying .lib
import library file on Windows systems). For simplicity of documentation, when discussing the "library file" as a unit in a HAT package we are referring to either the single static library file (.a
or .lib
), the single dynamic library file (.so
) on Posix, or the pair of library files that comprise a dynamic library on Windows (.dll
and .lib
import library file). Note that since a HAT package includes only one "library file" it cannot contain both a static and dynamic library, so in the case of a HAT package containing a Windows dynamic library, the .lib
file in the package is always the import library and there is no ambiguity in which file (or pair of files) is being referenced by "library file".
The library file contains all the compiled object code that implements the functions in the HAT package. Each .hat
file contains a combination of standard C function declarations (like a typical .h
file) and metadata in the TOML markup language. The metadata that accompanies each function declaration describes how the function should be called and how it was implemented. The metadata is intended to be both human-readable and machine-readable, providing structured and systematic documentation and allowing downstream tools to examine the package contents.
Each .hat
file has the convenient property that it is simultaneously a valid h-file and a valid TOML file. In other words, the file is structured such that a C compiler will ignore the TOML metadata, while a TOML parser will understand the entire file as a valid TOML file. We accomplish this using a technique we call the hat trick, which is explained below.
What problem does the HAT format solve?
C is among the most popular programming languages, but it also has serious shortcomings. In particular, C libraries are typically opaque and lack mechanisms for systematic documentation and introspection. This is best explained with an example:
Say that we use C to implement an in-place column-wise normalization of a 10x10 matrix. In other words, this function takes a 10x10 matrix A
and divides each column by the Euclidean norm of that column. A highly-optimized implementation of this function would be tailored to the target computer's specific hardware properties, such as its cache size, the number of CPU cores, and perhaps even the presence of a GPU. The declaration of this function in an h-file would look something like this:
void normalize(float* A);
The accompanying library file would contain the compiled machine code for this function. The library/header file pair is opaque, as it provides very little information on how the function should be used, its dependencies, and how it was implemented. Specifically:
- What does the pointer
float* A
point to? By convention, it is reasonable to assume that A
points to the first element of an array that contains the 100 matrix elements, but this is not stated explicitly. - Does the function expect the matrix elements to appear in row-major order, column-major order, Z-order, or something else?
- What is the size of the array
A
? We may have auxiliary knowledge that the array is 100 elements long, but this information is not stated explicitly. - We can see that
A
is not const
, so we know that its elements can be changed by the function, but is it an "output-only" array (its initial values are overwritten) or is it an "input/output" array? We have auxiliary knowledge that A
is both an input and an output, but this is not stated explicitly. - Is this function compiled for Windows or Linux?
- Does it need to be linked to a C runtime library or any other library?
- For which instruction set is the function compiled? Does it rely on SSE extensions? AVX? AVX512?
- Is this a multi-threaded implementation? Does the implementation assume a fixed number of CPU cores?
- Does the implementation rely on GPU hardware?
- Who created this library? Does it have a version number? Is it distributed under an open-source license?
Some of the questions above can be answered by reading the human-readable documentation provided in h-file comments, in README.txt
or LICENSE.txt
files, or in a web page that describes the library. Some of the information may be implied by the library name or the function name (e.g., imagine that the function was named "normalize_10x10_singlecore") or by common sense (e.g., if a GPU is not mentioned anywhere, the function probably doesn't require one). Nevertheless, C does not have a schematized systematic way to express all of this important information. Moreover, human-readable documentation does not expose this information to downstream programming tools. For example, imagine a downstream tool that examines a library and automatically creates tests that measure the performance of each function.
The HAT package format attempts to replace this opacity with transparency, by annotating each declared function with descriptive metadata in TOML.
The HAT trick
As mentioned above, the .hat
file is simultaneously a valid h-file and a valid TOML file. It tricks the C parser into only seeing the valid C parts of the file, while maintaining the structure of a valid TOML file. This is accomplished with the following file structure:
#ifdef TOML
// Add TOML here
[declaration]
code = '''
#endif // TOML
// Add C declarations here
#ifdef TOML
'''
#endif // TOML
What does a C compiler see? Assuming that the TOML
macro is not defined, the parser ignores everything that appears between #ifdef TOML
and #endif
. This leaves whatever appears instead of // Add C declarations here
.
What does a TOML parser see? First note that #
is a comment escape character in TOML, so the #ifdef
and #endif
lines are ignored as comments. Any TOML code that appears instead of // Add TOML here
is parsed normally. Finally, a special TOML table named [declaration]
is defined, and inside it a key named code
with all of the C declarations as a multiline string.
Why is it important for the TOML and the C declarations to live in the same file? Why not put the TOML metadata in a separate file? The fact that C already splits the package code between library files and h-files is already a concern, because the user has to worry about distributing a .h
file with an incorrect version of the library file. We don't want to make things worse by adding yet another separate file. Keeping the metadata in the same file as the function declaration ensures that each declaration is never separated from its metadata.
Multiple .hat
files
The HAT format defines different types of metadata. Some types of metadata (such as the targeted operating system and the license) apply to all of the functions in the packaged library file, while other types of metadata (such as the specification of input and output arguments) are defined per function. Therefore, if two functions require different metadata, and that type of metadata is defined at the file scope, then those functions must be declared in separate .hat
files. For example, if the first function is compiled with AVX512 instructions and the second function makes do with SSE instructions, then these functions must be defined in separate .hat
files. On the other hand, both functions can co-exist in a single library file (recall that a HAT package has a single library file).
The constraint above influences the number of .hat
files in a package. Additionally, the author of the package may decide to split functions up into separate .hat
files to improve readability or organization.
HAT schema
The TOML metadata in each .hat
file follows the TOML schema, defined in schema/hat.tosd
. .hat
file samples can be found in the samples directory.
HAT Tools
Tools for working with HAT packages are available as a Python wheel.
Requirements: Python 3.7 and above.
pip install hatlib
Documentation
You can also clone this repository and build a package locally:
cd <path_to_repo>
pip install build
python -m build
pip install dist/hatlib-<version>-py3-none-any.whl