shecc
is built from scratch, targeting both 32-bit Arm and RISC-V architectures,
as a self-compiling compiler for a subset of the C language.
Despite its simplistic nature, it is capable of performing basic optimization strategies as a standalone optimizing compiler.
- Generate executable Linux ELF binaries for ARMv7-A and RV32IM.
- Provide a minimal C standard library for basic I/O on GNU/Linux.
- The cross-compiler is written in ANSI C, making it compatible with most platforms.
- Include a self-contained C front-end with an integrated machine code generator; no external assembler or linker needed.
- Utilize a two-pass compilation process: the first pass checks syntax and breaks down complex statements into basic operations, while the second pass translates these operations into Arm/RISC-V machine code.
- Develop a register allocation system that is compatible with RISC-style architectures.
- Implement an architecture-independent, static single assignment (SSA)-based middle-end for enhanced optimizations.
shecc
is capable of compiling C source files written in the following
syntax:
- data types: char, int, struct, and pointer
- condition statements: if, while, for, switch, case, break, return, and general expressions
- compound assignments:
+=
,-=
,*=
- global/local variable initializations for supported data types
- e.g.
int i = [expr]
- e.g.
- limited support for preprocessor directives:
#define
,#ifdef
,#elif
,#endif
,#undef
, and#error
- non-nested variadic macros with
__VA_ARGS__
identifier
The backend targets armv7hf with Linux ABI, verified on Raspberry Pi 3, and also supports RISC-V 32-bit architecture, verified with QEMU.
The steps to validate shecc
bootstrapping:
stage0
:shecc
source code is initially compiled using an ordinary compiler which generates a native executable. The generated compiler can be used as a cross-compiler.stage1
: The built binary reads its own source code as input and generates an ARMv7-A/RV32IM binary.stage2
: The generated ARMv7-A/RV32IM binary is invoked (via QEMU or running on Arm and RISC-V devices) with its own source code as input and generates another ARMv7-A/RV32IM binary.bootstrap
: Build thestage1
andstage2
compilers, and verify that they are byte-wise identical. If so,shecc
can compile its own source code and produce new versions of that same program.
Code generator in shecc
does not rely on external utilities. You only need
ordinary C compilers such as gcc
and clang
. However, shecc
would bootstrap
itself, and Arm/RISC-V ISA emulation is required. Install QEMU for Arm/RISC-V user
emulation on GNU/Linux:
$ sudo apt-get install qemu-user
It is still possible to build shecc
on macOS or Microsoft Windows. However,
the second stage bootstrapping would fail due to qemu-arm
absence.
To execute the snapshot test, install the packages below:
$ sudo apt-get install graphviz jq
Configure which backend you want, shecc
supports ARMv7-A and RV32IM backend:
$ make config ARCH=arm
# Target machine code switch to Arm
$ make config ARCH=riscv
# Target machine code switch to RISC-V
Run make
and you should see this:
CC+LD out/inliner
GEN out/libc.inc
CC out/src/main.o
LD out/shecc
SHECC out/shecc-stage1.elf
SHECC out/shecc-stage2.elf
File out/shecc
is the first stage compiler. Its usage:
$ shecc [-o output] [+m] [--no-libc] [--dump-ir] <infile.c>
Compiler options:
-o
: Specify output file name (default:out.elf
)+m
: Use hardware multiplication/division instructions (default: disabled)--no-libc
: Exclude embedded C library (default: embedded)--dump-ir
: Dump intermediate representation (IR)
Example:
$ out/shecc -o fib tests/fib.c
$ chmod +x fib
$ qemu-arm fib
To ensure the consistency of frontend (lexer, parser) behavior when working on it, the snapshot test is introduced. The snapshot test dumps IRs from the executable and compares the structural identity with the provided snapshots.
Verify the emitted IRs by specifying check-snapshots
target when invoking make
:
$ make check-snapshots
If the compiler frontend is updated, the emitted IRs might be changed.
Thus, you can update snapshots by specifying update-snapshots
target when invoking make
:
$ make update-snapshots
Notice that the above 2 targets will update all backend snapshots at once, to update/check current backend's snapshot,
use update-snapshot
/ check-snapshot
instead.
shecc
comes with unit tests. To run the tests, give check
as an argument:
$ make check
Reference output:
TEST STAGE 0
...
int main(int argc, int argv) { exit(sizeof(char)); } => 1
int main(int argc, int argv) { int a; a = 0; switch (3) { case 0: return 2; case 3: a = 10; break; case 1: return 0; } exit(a); } => 10
int main(int argc, int argv) { int a; a = 0; switch (3) { case 0: return 2; default: a = 10; break; } exit(a); } => 10
OK
TEST STAGE 2
...
int main(int argc, int argv) { exit(sizeof(char*)); }
exit code => 4
output =>
int main(int argc, int argv) { exit(sizeof(int*)); }
exit code => 4
output =>
OK
To clean up the generated compiler files, execute the command make clean
.
For resetting architecture configurations, use the command make distclean
.
Once the option --dump-ir
is passed to shecc
, the intermediate representation (IR)
will be generated. Take the file tests/fib.c
for example. It consists of a recursive
Fibonacci sequence function.
int fib(int n)
{
if (n == 0)
return 0;
else if (n == 1)
return 1;
return fib(n - 1) + fib(n - 2);
}
Execute the following to generate IR:
$ out/shecc --dump-ir -o fib tests/fib.c
Line-by-line explanation between C source and IR:
C Source IR Explanation
------------------+---------------------------------------+----------------------------------------------------------------------------------
int fib(int n) def int @fib(int %n) Indicate a function definition
{ {
if (n == 0) const %.t1001, $0 Load constant 0 into a temporary variable ".t1001"
%.t1002 = eq %n, %.t1001 Test "n" equals ".t1001" or not, and write the result in temporary variable ".t1002"
br %.t1002, .label.1177, .label.1178 If ".t1002" equals zero, goto false label ".label.1178", otherwise,
goto true label ".label.1177"
.label.1177
return 0; const %.t1003, $0 Load constant 0 into a temporary variable ".t1003"
ret %.t1003 Return ".t1003"
j .label.1184 Jump to endif label ".label.1184"
.label.1178
else if (n == 1) const %.t1004, $1 Load constant 1 into a temporary variable ".t1004"
%.t1005 = eq %n, %.t1004 Test "n" equals ".t1004" or not, and write the result in temporary variable ".t1005"
br %.t1005, .label.1183, .label.1184 If ".t1005" equals zero, goto false label ".label.1184". Otherwise,
goto true label ".label.1183"
.label.1183
return 1; const %.t1006, $1 Load constant 1 into a temporary variable ".t1006"
ret %.t1006 Return ".t1006"
.label.1184
return
fib(n - 1) const %.t1007, $1 Load constant 1 into a temporary variable ".t1007"
%.t1008 = sub %n, %.t1007 Subtract ".t1007" from "n", and store the result in temporary variable ".t1008"
push %.t1008 Prepare parameter for function call
call @fib, 1 Call function "fib" with one parameter
+ retval %.t1009 Store return value in temporary variable ".t1009"
fib(n - 2); const %.t1010, $2 Load constant 2 into a temporary variable ".t1010"
%.t1011 = sub %n, %.t1010 Subtract ".t1010" from "n", and store the result in temporary variable ".t1011"
push %.t1011 Prepare parameter for function call
call @fib, 1 Call function "fib" with one parameter
retval %.t1012 Store return value in temporary variable ".t1012"
%.t1013 = add %.t1009, %.t1012 Add ".t1009" and ".t1012", and store the result in temporary variable ".t1013"
ret %.t1013 Return ".t1013"
} }
- The generated ELF lacks of .bss and .rodata section
- The support of varying number of function arguments is incomplete. No
<stdarg.h>
can be used. Alternatively, check the implementationprintf
in sourcelib/c.c
forvar_arg
. - The C front-end is a bit dirty because there is no effective AST.
shecc
is freely redistributable under the BSD 2 clause license.
Use of this source code is governed by a BSD-style license that can be found in the LICENSE
file.