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This is the reference implementation of https://www.sigbus.info/compilerbook.
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# chibicc: A Small C Compiler
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(The old master has moved to
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[historical/old](https://github.com/rui314/chibicc/tree/historical/old)
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branch. This is a new one uploaded in September 2020.)
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chibicc is yet another small C compiler that implements most C11
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features. Even though it still probably falls into the "toy compilers"
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category just like other small compilers do, chibicc can compile
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several real-world programs, including [Git](https://git-scm.com/),
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[SQLite](https://sqlite.org),
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[libpng](http://www.libpng.org/pub/png/libpng.html) and chibicc
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itself, without making modifications to the compiled programs.
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Generated executables of these programs pass their corresponding test
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suites. So, chibicc actually supports a wide variety of C11 features
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and is able to compile hundreds of thousands of lines of real-world C
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code correctly.
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chibicc is developed as the reference implementation for a book I'm
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currently writing about the C compiler and the low-level programming.
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The book covers the vast topic with an incremental approach; in the first
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chapter, readers will implement a "compiler" that accepts just a single
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number as a "language", which will then gain one feature at a time in each
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section of the book until the language that the compiler accepts matches
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what the C11 spec specifies. I took this incremental approach from [the
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paper](http://scheme2006.cs.uchicago.edu/11-ghuloum.pdf) by Abdulaziz
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Ghuloum.
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Each commit of this project corresponds to a section of the book. For this
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purpose, not only the final state of the project but each commit was
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carefully written with readability in mind. Readers should be able to learn
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how a C language feature can be implemented just by reading one or a few
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commits of this project. For example, this is how
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[while](https://github.com/rui314/chibicc/commit/773115ab2a9c4b96f804311b95b20e9771f0190a),
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[[]](https://github.com/rui314/chibicc/commit/75fbd3dd6efde12eac8225d8b5723093836170a5),
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[?:](https://github.com/rui314/chibicc/commit/1d0e942fd567a35d296d0f10b7693e98b3dd037c),
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and [thread-local
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variable](https://github.com/rui314/chibicc/commit/79644e54cc1805e54428cde68b20d6d493b76d34)
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are implemented. If you have plenty of spare time, it might be fun to read
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it from the [first
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commit](https://github.com/rui314/chibicc/commit/0522e2d77e3ab82d3b80a5be8dbbdc8d4180561c).
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If you like this project, please consider purchasing a copy of the book
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when it becomes available! 😀 I publish the source code here to give people
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early access to it, because I was planing to do that anyway with a
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permissive open-source license after publishing the book. If I don't charge
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for the source code, it doesn't make much sense to me to keep it private. I
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hope to publish the book in 2021.
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You can sign up [here](https://forms.gle/sgrMWHGeGjeeEJcX7) to receive a
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notification when a free chapter is available online or the book is published.
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I pronounce chibicc as _chee bee cee cee_. "chibi" means "mini" or
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"small" in Japanese. "cc" stands for C compiler.
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## Status
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chibicc supports almost all mandatory features and most optional
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features of C11 as well as a few GCC language extensions.
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Features that are often missing in a small compiler but supported by
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chibicc include (but not limited to):
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- Preprocessor
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- float, double and long double (x87 80-bit floating point numbers)
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- Bit-fields
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- alloca()
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- Variable-length arrays
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- Compound literals
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- Thread-local variables
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- Atomic variables
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- Common symbols
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- Designated initializers
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- L, u, U and u8 string literals
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- Functions that take or return structs as values, as specified by the
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x86-64 SystemV ABI
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chibicc does not support complex numbers, K&R-style function prototypes
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and GCC-style inline assembly. Digraphs and trigraphs are intentionally
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left out.
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chibicc outputs a simple but nice error message when it finds an error in
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source code.
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There's no optimization pass. chibicc emits terrible code which is probably
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twice or more slower than GCC's output. I have a plan to add an
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optimization pass once the frontend is done.
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I'm using Ubuntu 20.04 for x86-64 as a development platform. I made a
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few small changes so that chibicc works on Ubuntu 18.04, Fedora 32 and
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Gentoo 2.6, but portability is not my goal at this moment. It may or
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may not work on systems other than Ubuntu 20.04.
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## Internals
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chibicc consists of the following stages:
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- Tokenize: A tokenizer takes a string as an input, breaks it into a list
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of tokens and returns them.
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- Preprocess: A preprocessor takes as an input a list of tokens and output
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a new list of macro-expanded tokens. It interprets preprocessor
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directives while expanding macros.
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- Parse: A recursive descendent parser constructs abstract syntax trees
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from the output of the preprocessor. It also adds a type to each AST
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node.
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- Codegen: A code generator emits an assembly text for given AST nodes.
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## Contributing
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When I find a bug in this compiler, I go back to the original commit that
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introduced the bug and rewrite the commit history as if there were no such
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bug from the beginning. This is an unusual way of fixing bugs, but as a
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part of a book, it is important to keep every commit bug-free.
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Thus, I do not take pull requests in this repo. You can send me a pull
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request if you find a bug, but it is very likely that I will read your
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patch and then apply that to my previous commits by rewriting history. I'll
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credit your name somewhere, but your changes will be rewritten by me before
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submitted to this repository.
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Also, please assume that I will occasionally force-push my local repository
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to this public one to rewrite history. If you clone this project and make
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local commits on top of it, your changes will have to be rebased by hand
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when I force-push new commits.
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## Design principles
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chibicc's core value is its simplicity and the reability of its source
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code. To achieve this goal, I was careful not to be too clever when
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writing code. Let me explain what that means.
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Oftentimes, as you get used to the code base, you are tempted to
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_improve_ the code using more abstractions and clever tricks.
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But that kind of _improvements_ don't always improve readability for
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first-time readers and can actually hurts it. I tried to avoid the
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pitfall as much as possible. I wrote this code not for me but for
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first-time readers.
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If you take a look at the source code, you'll find a couple of
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dumb-looking pieces of code. These are written intentionally that way
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(but at some places I might be actually missing something,
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though). Here is a few notable examples:
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- The recursive descendent parser contains many similar-looking functions
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for similar-looking generative grammar rules. You might be tempted
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to _improve_ it to reduce the duplication using higher-order functions
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or macros, but I thought that that's too complicated. It's better to
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allow small duplications instead.
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- chibicc doesn't try too hard to save memory. An entire input source
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file is read to memory first before the tokenizer kicks in, for example.
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- Slow algorithms are fine if we know that n isn't too big.
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For example, we use a linked list as a set in the preprocessor, so
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the membership check takes O(n) where n is the size of the set. But
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that's fine because we know n is usually very small.
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And even if n can be very big, I stick with a simple slow algorithm
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until it is proved by benchmarks that that's a bottleneck.
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- Each AST node type uses only a few members of the `Node` struct members.
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Other unused `Node` members are just a waste of memory at runtime.
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We could save memory using unions, but I decided to simply put everything
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in the same struct instead. I believe the inefficiency is negligible.
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Even if it matters, we can always change the code to use unions
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at any time. I wanted to avoid premature optimization.
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- chibicc always allocates heap memory using `calloc`, which is a
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variant of `malloc` that clears memory with zero. `calloc` is
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slightly slower than `malloc`, but that should be neligible.
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- Last but not least, chibicc allocates memory using `calloc` but never
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calls `free`. Allocated heap memory is not freed until the process exits.
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I'm sure that this memory management policy (or lack thereof) looks
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very odd, but it makes sense for short-lived programs such as compilers.
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DMD, a compiler for the D programming language, uses the same memory
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management scheme for the same reason, for example [1].
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## About the Author
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I'm Rui Ueyama. I'm the creator of [8cc](https://github.com/rui314/8cc),
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which is a hobby C compiler, and also the original creator of the current
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version of [LLVM lld](https://lld.llvm.org) linker, which is a
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production-quality linker used by various operating systems and large-scale
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build systems.
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## References
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- [tcc](https://bellard.org/tcc/): A small C compiler written by Fabrice
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Bellard. I learned a lot from this compiler, but the design of tcc and
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chibicc are different. In particular, tcc is a one-pass compiler, while
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chibicc is a multi-pass one.
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- [lcc](https://github.com/drh/lcc): Another small C compiler. The creators
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wrote a [book](https://sites.google.com/site/lccretargetablecompiler/)
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about the internals of lcc, which I found a good resource to see how a
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compiler is implemented.
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- [An Incremental Approach to Compiler
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Construction](http://scheme2006.cs.uchicago.edu/11-ghuloum.pdf)
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- [Rob Pike's 5 Rules of Programming](https://users.ece.utexas.edu/~adnan/pike.html)
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[1] https://www.drdobbs.com/cpp/increasing-compiler-speed-by-over-75/240158941
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> DMD does memory allocation in a bit of a sneaky way. Since compilers
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> are short-lived programs, and speed is of the essence, DMD just
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> mallocs away, and never frees.
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