Template Assembly (tasm)
Uses C++ templates to embed x86 assembly code directly in normal C++ at compile-time using a domain specific language.
#include <tasm/asm.h>
#include <tasm/isa/x86.h>
using namespace tasm;
// A simple loop with labels.
Asm<int>(
MOV(ecx, 5_d),
MOV(eax, 0_d),
"start"_label,
CMP(ecx, 0_d),
JE("done"_rel8),
ADD(eax, 6_d),
DEC(ecx),
JMP("start"_rel8),
"done"_label,
RET());
// Accessing c++ args.
Asm<int>(
MOV(eax, _[ebp - 0xc_b]),
RET()
)(1, 2, 3); // 2
// Index memory addressing.
Asm<int>(
MOV(ecx, 2_d),
MOV(eax, _[ebp + 0x14_b + ecx * 2]),
RET()
)(1, 2, 3); // 2
About
This project uses C++ template metaprogramming to express simplified x86 assembly directly within C++. The actual "compilation" of the assembly happens at compiletime by constructing a static byte-string of machine code that can be invoked like a normal function.
By expressing assembly in C++ directly, we get type checking of instructions for free. We can also generate meaningful compiletime error messages for missing labels and other programmer errors within the assembly.
Limitations
This project is for demonstration purposes and only supports a super limited subset of x86 assembly. Many instructions are currently not available and many assembly language features are missing or broken.
Usage
asm.h
the core logic, while isa/x86.h
includes instructions for x86 assembly.
#include <tasm/asm.h>
#include <tasm/isa/x86.h>
using namespace tasm;
You can add tasm to your project using the 'Addtasm.cmake' file, just download the file and then add this in you CMakeLists.txt
# Includes tasm in the project:
include(Addtasm)
include_directories(${TASM_INCLUDE_DIR})
add_executable(
# executable name
yourbinary
# source files
main.cpp
)
add_dependencies(yourbinary tasm)
Basics
Asm
is the top level function that creates assembly code. This code acts like a functor with its implementation written in assembly language. Asm
takes a single parmeter specifying the expected result type of the assembly code.
auto assembly_program = Asm<int>(
MOV(eax, 4_d),
RET());
assembly_program() == 4
The assembly directives are provided in the body of Asm
. Instructions are in intel style syntax.
All the normal registers are available for use directly by name: eax, esp, ...
. Immediate values are specified with user defined literals: _b
for byte, _w
for word, and _d
for dword.
Asm<int>(
MOV(ecx, 4_d)
MOV(eax, ecx)
)();
The size of the immediate must match the expected size of the operation (register size for example).
Labels
You can also define labels and use labels with jump instructions.
auto jump_program = Asm<int>(
MOV(eax, 4_d),
JMP("a"_rel8),
ADD(eax, 2_d),
"a"_label,
RET());
jump_program() == 4
It is a compile time error if you try to use a label that does not exist.
Memory
A few of the x86 addressing modes are supported in a syntax that emulates normal assembly as much as reasonable:
C++ ASSEMBLY
_[eax] [eax]
_[4_b] [4]
_[eax + 4_b] [eax + 4]
_[eax + ecx] [eax + ecx]
_[eax + 4_b + ecx] [eax + 4 + ecx]
_[eax + ecx * 2_b] [eax + ecx * 2]
_[eax + 4_b + ecx * 2_b] [eax + 4 + ecx * 2]
In general, _
converts a register to a memory address with the []
operator. Memory addresses are overloaded to use the +
operator for displacements. Multiplication creates a scaled index. All displacements and scales must use user defined literals (_b
, _w
, _d
) instead of raw literals.
Macro-ish
Because the assembly is written directly in normal C++, you can use metaprogramming to construct simple assembly macros for instructions or groups of instructions:
template <typename Count, typename... Body>
constexpr auto do_x_times(Count count, Body... body) {
return block(
MOV(ecx, count),
"start"_label,
CMP(ecx, 0_d),
JE("done"_rel8),
body...,
DEC(ecx),
JMP("start"_rel8),
"done"_label);
}
Asm<int>(
MOV(eax, 0_d),
do_x_times(5_d,
ADD(eax, 6_d)),
RET()
)();
Any C++ syntax can be used to extend the embedded language.
Contributing
Any and all contributions to the project are welcome.
The best way to fix a bug or add support for a new feature is by submitting a pull request. Be sure to checkout the CONTRIBUTING.md guide which details how to run some simple tests and how to regenerate the instruction files.
If you run into any bugs, be sure to open an issue. Please make sure to provide a description of the expected behavior compared to the current behavior.
Acknowledgments
x86 / x86_64 instruction xml specification is copied from Opcodes.