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tiny_vm.rs
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tiny_vm.rs
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//! TinyVm example.
//!
//! This example introduces a simple 16 bit virtual machine the [`TinyVm`]. The VM consists of
//! three registers defined in [`TinyReg`], a separate _data_ and _instruction_ memory and a small
//! set of instructions [`TinyInsn`], sufficient to implement a guest program to compute the
//! Fibonacci sequence.
//!
//! The `TinyVm` implements a simple _just-in-time (JIT)_ compiler to demonstrate the
//! [`juicebox_asm`] crate. Additionally, it implements a reference _interpreter_.
//!
//! ```
//! fn main() {
//! let mut prog = Vec::new();
//! prog.push(TinyInsn::LoadImm(TinyReg::A, 100));
//! prog.push(TinyInsn::Add(TinyReg::B, TinyReg::A));
//! prog.push(TinyInsn::Addi(TinyReg::C, 100));
//! prog.push(TinyInsn::Halt);
//!
//! let mut vm = TinyVm::new(prog);
//! vm.interp();
//!
//! assert_eq!(100, vm.read_reg(TinyReg::A));
//! assert_eq!(100, vm.read_reg(TinyReg::B));
//! assert_eq!(100, vm.read_reg(TinyReg::C));
//! assert_eq!(4, vm.icnt);
//! assert_eq!(4, vm.pc);
//!
//! vm.pc = 0;
//! vm.jit();
//!
//! assert_eq!(100, vm.read_reg(TinyReg::A));
//! assert_eq!(200, vm.read_reg(TinyReg::B));
//! assert_eq!(200, vm.read_reg(TinyReg::C));
//! assert_eq!(8, vm.icnt);
//! assert_eq!(4, vm.pc);
//! }
//! ```
use juicebox_asm::insn::*;
use juicebox_asm::Runtime;
use juicebox_asm::{Asm, Imm16, Imm64, MemOp, Reg16, Reg64};
/// A guest physical address.
pub struct PhysAddr(pub u16);
impl Into<usize> for PhysAddr {
fn into(self) -> usize {
self.0 as usize
}
}
/// The registers for the [`TinyVm`].
#[derive(Debug, PartialEq, Clone, Copy)]
pub enum TinyReg {
A,
B,
C,
}
impl TinyReg {
#[inline]
fn idx(&self) -> usize {
*self as usize
}
}
/// The instructions for the [`TinyVm`].
#[derive(Debug, PartialEq, Clone, Copy)]
pub enum TinyInsn {
/// Halt the VM.
Halt,
/// Load the immediate value into the register `reg = imm`.
LoadImm(TinyReg, u16),
/// Load a value from the memory (absolute addressing) into the register `reg = mem[imm]`.
Load(TinyReg, u16),
/// Store a value from the register into the memory (absolute addressing) `mem[imm] = reg`.
Store(TinyReg, u16),
/// Add the register to the register `reg1 += reg2`.
Add(TinyReg, TinyReg),
/// Add the immediate to the register `reg += imm`.
Addi(TinyReg, i16),
/// Jump unconditional (absolute addressing) `pc = disp`.
Branch(usize),
/// Jump if the register is zero (absolute addressing) `pc = (reg == 0) ? disp : pc++`.
BranchZero(TinyReg, usize),
}
/// Value returned from a [`JitFn`].
#[repr(C)]
struct JitRet(u64, u64);
/// Function signature defining the simple JIT ABI used in this example.
/// A `JitFn` represents the entry point to a jit compiled _basic block_ of the guest software.
///
/// ```text
/// JIT entry:
/// arg0: pointer to guest registers
/// arg1: pointer to guest data memory
///
/// JIT exit:
/// JitRet(0, N): Halt instruction, executed N instructions.
/// JitRet(N, R): N!=0
/// End of basic block, executed N instructions,
/// must re-enter at `pc = R`.
/// ```
type JitFn = extern "C" fn(*mut u16, *mut u8) -> JitRet;
/// The `TinyVm` virtual machine state.
pub struct TinyVm {
/// Data memory, covering full 16 bit guest address space.
///
/// For simplicity add additional trailing 1 byte to support an unaligned access to 0xffff
/// without any special handling.
dmem: [u8; 0x1_0000 + 1],
/// Instruction memory.
imem: Vec<TinyInsn>,
/// VM registers.
regs: [u16; 3],
/// VM program counter.
pc: usize,
/// VM executed instruction counter (perf counter).
icnt: usize,
// -- JIT state.
/// Mapping of guest PCs to jitted host code (`JitFn`). This mapping is filled when guest
/// _basic blocks_ are jitted.
jit_cache: Vec<Option<JitFn>>,
/// JIT runtime maintaining the host pages containing the jitted guest code.
rt: Runtime,
}
impl TinyVm {
/// Create a new [`TinyVm`] and initialize the instruction memory from `code`.
pub fn new(code: Vec<TinyInsn>) -> Self {
let mut jit_cache = Vec::with_capacity(code.len());
jit_cache.resize(code.len(), None);
TinyVm {
dmem: [0; 0x1_0000 + 1],
imem: code,
regs: [0; 3],
pc: 0,
icnt: 0,
// -- JIT state.
jit_cache,
rt: Runtime::new(),
// Confifigure the runtime to generates perf meta data.
//rt: Runtime::with_profile(),
}
}
/// Read guest register.
#[inline]
pub fn read_reg(&self, reg: TinyReg) -> u16 {
self.regs[reg.idx()]
}
/// Write guest register.
#[inline]
pub fn write_reg(&mut self, reg: TinyReg, val: u16) {
self.regs[reg.idx()] = val;
}
/// Read guest data memory.
#[inline]
pub fn read_mem(&self, paddr: PhysAddr) -> u16 {
// dmem covers whole 16 bit address space + 1 byte for unaligned access at 0xffff.
let bytes = self.dmem[paddr.into()..][..2].try_into().unwrap();
u16::from_le_bytes(bytes)
}
/// Write guest data memory.
#[inline]
pub fn write_mem(&mut self, paddr: PhysAddr, val: u16) {
let bytes = val.to_le_bytes();
self.dmem[paddr.into()..][..2].copy_from_slice(&bytes);
}
/// Dump the VM state to stdout.
pub fn dump(&self) {
println!("-- TinyVm state --");
println!(" ICNT: {}", self.icnt);
println!(" PC : {:02x}", self.pc - 1);
println!(
" A:{:04x} B:{:04x} C:{:04x}",
self.read_reg(TinyReg::A),
self.read_reg(TinyReg::B),
self.read_reg(TinyReg::C),
);
}
/// Run in interpreter mode until the next [`TinyInsn::Halt`] instruction is hit.
pub fn interp(&mut self) {
'outer: loop {
let insn = self.imem[self.pc];
//println!("[0x{:02x}] {:?}", self.pc, insn);
self.pc = self.pc.wrapping_add(1);
self.icnt += 1;
match insn {
TinyInsn::Halt => {
break 'outer;
}
TinyInsn::LoadImm(a, imm) => {
self.write_reg(a, imm);
}
TinyInsn::Load(a, addr) => {
let val = self.read_mem(PhysAddr(addr));
self.write_reg(a, val);
}
TinyInsn::Store(a, addr) => {
let val = self.read_reg(a);
self.write_mem(PhysAddr(addr), val);
}
TinyInsn::Add(a, b) => {
let res = self.read_reg(a).wrapping_add(self.read_reg(b));
self.write_reg(a, res);
}
TinyInsn::Addi(a, imm) => {
let res = self.read_reg(a).wrapping_add(imm as u16);
self.write_reg(a, res);
}
TinyInsn::Branch(disp) => {
self.pc = disp;
}
TinyInsn::BranchZero(a, disp) => {
if self.read_reg(a) == 0 {
self.pc = disp;
}
}
}
}
}
/// Run in JIT mode until the next [`TinyInsn::Halt`] instruction is hit. Translate guest
/// _basic blocks_ on demand.
pub fn jit(&mut self) {
'outer: loop {
let bb_fn = if let Some(bb_fn) = self.jit_cache[self.pc] {
bb_fn
} else {
let bb_fn = self.translate_next_bb();
self.jit_cache[self.pc] = Some(bb_fn);
//println!("[0x{:02x}] translated bb at {:p}", self.pc, bb_fn);
bb_fn
};
match bb_fn(self.regs.as_mut_ptr(), self.dmem.as_mut_ptr()) {
// HALT instruction hit.
JitRet(0, insn) => {
self.pc += insn as usize;
self.icnt += insn as usize;
break 'outer;
}
// End of basic block, re-enter.
JitRet(insn, reenter_pc) => {
self.pc = reenter_pc as usize;
self.icnt += insn as usize;
}
}
}
}
#[cfg(all(any(target_arch = "x86_64", target_os = "linux")))]
/// Translate the bb at the current pc and return a JitFn pointer to it.
fn translate_next_bb(&mut self) -> JitFn {
let mut bb = Asm::new();
let mut pc = self.pc;
'outer: loop {
let insn = self.imem[pc];
pc = pc.wrapping_add(1);
// JIT abi: JitFn -> JitRet
//
// According to SystemV abi:
// enter
// rdi => regs
// rsi => dmem
// exit
// rax => JitRet.0
// rdx => JitRet.1
// Generate memory operand into regs for guest register.
let reg_op = |r: TinyReg| {
MemOp::IndirectDisp(Reg64::rdi, (r.idx() * 2).try_into().expect("only 3 regs"))
};
// Generate memory operand into dmem for guest phys address.
let mem_op = |paddr: u16| MemOp::IndirectDisp(Reg64::rsi, paddr.into());
// Compute instructions in translated basic block.
let bb_icnt = || -> u64 { (pc - self.pc).try_into().unwrap() };
let reenter_pc = |pc: usize| -> u64 { pc.try_into().unwrap() };
match insn {
TinyInsn::Halt => {
bb.mov(Reg64::rax, Imm64::from(0));
bb.mov(Reg64::rdx, Imm64::from(bb_icnt()));
bb.ret();
break 'outer;
}
TinyInsn::LoadImm(a, imm) => {
bb.mov(reg_op(a), Imm16::from(imm));
}
TinyInsn::Load(a, addr) => {
bb.mov(Reg16::ax, mem_op(addr));
bb.mov(reg_op(a), Reg16::ax);
}
TinyInsn::Store(a, addr) => {
bb.mov(Reg16::ax, reg_op(a));
bb.mov(mem_op(addr), Reg16::ax);
}
TinyInsn::Add(a, b) => {
bb.mov(Reg16::ax, reg_op(b));
bb.add(reg_op(a), Reg16::ax);
}
TinyInsn::Addi(a, imm) => {
bb.add(reg_op(a), Imm16::from(imm));
}
TinyInsn::Branch(disp) => {
bb.mov(Reg64::rax, Imm64::from(bb_icnt()));
bb.mov(Reg64::rdx, Imm64::from(reenter_pc(disp)));
bb.ret();
break 'outer;
}
TinyInsn::BranchZero(a, disp) => {
bb.cmp(reg_op(a), Imm16::from(0u16));
bb.mov(Reg64::rax, Imm64::from(bb_icnt()));
// Default fall-through PC (branch not taken).
bb.mov(Reg64::rdx, Imm64::from(reenter_pc(pc)));
// Conditionally update PC if condition is ZERO (branch taken).
bb.mov(Reg64::r11, Imm64::from(reenter_pc(disp)));
bb.cmovz(Reg64::rdx, Reg64::r11);
bb.ret();
break 'outer;
}
}
}
unsafe { self.rt.add_code::<JitFn>(bb.into_code()) }
}
}
/// A minial fixup utility to implement jump labels when constructing guest programs.
pub struct Fixup {
pc: usize,
}
impl Fixup {
/// Create a new `Fixup` at the current pc.
pub fn new(pc: usize) -> Self {
Fixup { pc }
}
/// Bind the `Fixup` to the current location of `prog` and resolve the `Fixup`.
pub fn bind(self, prog: &mut Vec<TinyInsn>) {
let plen = prog.len();
let insn = prog.get_mut(self.pc).expect(&format!(
"Trying to apply Fixup, but Fixup is out of range pc={} prog.len={}",
self.pc, plen
));
match insn {
TinyInsn::Branch(disp) | TinyInsn::BranchZero(_, disp) => {
*disp = plen;
}
_ => {
unimplemented!("Trying to fixup non-branch instruction '{:?}'", *insn);
}
}
}
}
/// Generate a guest program to compute the fiibonacci sequence for `n`.
pub fn make_tinyvm_fib(start_n: u16) -> Vec<TinyInsn> {
// Reference implementation:
//
// int fib(int n)
// int tmp = 0;
// int prv = 1;
// int sum = 0;
// loop:
// if (n == 0) goto end;
// tmp = sum;
// sum += prv;
// prv = tmp;
// --n;
// goto loop;
// end:
// return sum;
// Variables live in memory, bin to fixed addresses.
let tmp = 0u16;
let prv = 2u16;
let sum = 4u16;
// Loop counter mapped to register.
let n = TinyReg::C;
let mut prog = Vec::with_capacity(32);
// n = start_n
prog.push(TinyInsn::LoadImm(n, start_n));
// tmp = sum = 0
prog.push(TinyInsn::LoadImm(TinyReg::A, 0));
prog.push(TinyInsn::Store(TinyReg::A, tmp));
prog.push(TinyInsn::Store(TinyReg::A, sum));
// prv = 1
prog.push(TinyInsn::LoadImm(TinyReg::A, 1));
prog.push(TinyInsn::Store(TinyReg::A, prv));
// Create loop_start label.
let loop_start = prog.len();
// Create fixup to capture PC that need to be patched later.
let end_fixup = Fixup::new(prog.len());
// if (n == 0) goto end
prog.push(TinyInsn::BranchZero(n, 0xdead));
// tmp = sum
prog.push(TinyInsn::Load(TinyReg::A, sum));
prog.push(TinyInsn::Store(TinyReg::A, tmp));
// sum += prv
prog.push(TinyInsn::Load(TinyReg::B, prv));
prog.push(TinyInsn::Add(TinyReg::A, TinyReg::B));
prog.push(TinyInsn::Store(TinyReg::A, sum));
// prv = tmp
prog.push(TinyInsn::Load(TinyReg::A, tmp));
prog.push(TinyInsn::Store(TinyReg::A, prv));
// --n
prog.push(TinyInsn::Addi(n, -1));
// goto loop_start
prog.push(TinyInsn::Branch(loop_start));
// Bind end fixup to current PC, to patch branch to jump to here.
end_fixup.bind(&mut prog);
// TinyReg::A = sum
prog.push(TinyInsn::Load(TinyReg::A, sum));
// Halt the VM.
prog.push(TinyInsn::Halt);
prog
}
/// Generate a test program for the jit.
pub fn make_tinyvm_jit_test() -> Vec<TinyInsn> {
let mut prog = Vec::with_capacity(32);
prog.push(TinyInsn::Branch(1));
prog.push(TinyInsn::LoadImm(TinyReg::A, 0x0010));
prog.push(TinyInsn::LoadImm(TinyReg::B, 0x0));
let start = prog.len();
let end = Fixup::new(prog.len());
prog.push(TinyInsn::BranchZero(TinyReg::A, 0xdead));
prog.push(TinyInsn::LoadImm(TinyReg::C, 0x1));
prog.push(TinyInsn::Add(TinyReg::B, TinyReg::C));
prog.push(TinyInsn::Addi(TinyReg::A, -1));
prog.push(TinyInsn::Branch(start));
end.bind(&mut prog);
prog.push(TinyInsn::LoadImm(TinyReg::A, 0xabcd));
prog.push(TinyInsn::Store(TinyReg::A, 0xffff));
prog.push(TinyInsn::Load(TinyReg::C, 0xffff));
prog.push(TinyInsn::Halt);
prog.push(TinyInsn::Halt);
prog.push(TinyInsn::Halt);
prog.push(TinyInsn::Halt);
prog
}
/// Generate a simple count down loop to crunch some instructions.
pub fn make_tinyvm_jit_perf() -> Vec<TinyInsn> {
let mut prog = Vec::with_capacity(32);
prog.push(TinyInsn::Halt);
prog.push(TinyInsn::LoadImm(TinyReg::A, 0xffff));
prog.push(TinyInsn::LoadImm(TinyReg::B, 1));
prog.push(TinyInsn::LoadImm(TinyReg::C, 2));
prog.push(TinyInsn::Addi(TinyReg::A, -1));
prog.push(TinyInsn::BranchZero(TinyReg::A, 0));
prog.push(TinyInsn::Branch(2));
prog
}
fn main() {
let use_jit = match std::env::args().nth(1) {
Some(a) if a == "-h" || a == "--help" => {
println!("Usage: tiny_vm [mode]");
println!("");
println!("Options:");
println!(" mode if mode is 'jit' then run in jit mode, else in interpreter mode");
std::process::exit(0);
}
Some(a) if a == "jit" => true,
_ => false,
};
let mut vm = TinyVm::new(make_tinyvm_fib(42));
if use_jit {
println!("Run in jit mode..");
vm.jit();
} else {
println!("Run in interpreter mode..");
vm.interp();
}
vm.dump();
}
#[cfg(test)]
mod test {
use super::*;
fn fib_rs(n: u64) -> u64 {
if n < 2 {
n
} else {
let mut fib_n_m1 = 0;
let mut fib_n = 1;
for _ in 1..n {
let tmp = fib_n + fib_n_m1;
fib_n_m1 = fib_n;
fib_n = tmp;
}
fib_n
}
}
#[test]
fn test_fib_interp() {
for n in 0..92 {
let mut vm = TinyVm::new(make_tinyvm_fib(n));
vm.interp();
assert_eq!((fib_rs(n as u64) & 0xffff) as u16, vm.read_reg(TinyReg::A));
}
}
#[test]
fn test_fib_jit() {
for n in 0..92 {
let mut vm = TinyVm::new(make_tinyvm_fib(n));
vm.jit();
assert_eq!((fib_rs(n as u64) & 0xffff) as u16, vm.read_reg(TinyReg::A));
}
}
#[test]
fn test_fib_icnt() {
let mut vm1 = TinyVm::new(make_tinyvm_fib(91));
vm1.interp();
let mut vm2 = TinyVm::new(make_tinyvm_fib(91));
vm2.jit();
assert_eq!(vm1.icnt, vm2.icnt);
assert_eq!(vm1.pc, vm2.pc);
}
#[test]
fn test_jit_load_imm() {
let mut prog = Vec::new();
prog.push(TinyInsn::LoadImm(TinyReg::A, 0x1111));
prog.push(TinyInsn::LoadImm(TinyReg::B, 0x2222));
prog.push(TinyInsn::LoadImm(TinyReg::C, 0x3333));
prog.push(TinyInsn::Halt);
let mut vm = TinyVm::new(prog);
vm.jit();
assert_eq!(0x1111, vm.read_reg(TinyReg::A));
assert_eq!(0x2222, vm.read_reg(TinyReg::B));
assert_eq!(0x3333, vm.read_reg(TinyReg::C));
assert_eq!(4, vm.icnt);
assert_eq!(4, vm.pc);
}
#[test]
fn test_jit_add() {
let mut prog = Vec::new();
prog.push(TinyInsn::LoadImm(TinyReg::A, 0));
prog.push(TinyInsn::Addi(TinyReg::A, 123));
prog.push(TinyInsn::LoadImm(TinyReg::B, 100));
prog.push(TinyInsn::LoadImm(TinyReg::C, 200));
prog.push(TinyInsn::Add(TinyReg::B, TinyReg::C));
prog.push(TinyInsn::Halt);
let mut vm = TinyVm::new(prog);
vm.jit();
assert_eq!(123, vm.read_reg(TinyReg::A));
assert_eq!(300, vm.read_reg(TinyReg::B));
assert_eq!(200, vm.read_reg(TinyReg::C));
assert_eq!(6, vm.icnt);
assert_eq!(6, vm.pc);
}
#[test]
fn test_jit_load_store() {
let mut prog = Vec::new();
prog.push(TinyInsn::Load(TinyReg::A, 0xffff));
prog.push(TinyInsn::LoadImm(TinyReg::B, 0xf00d));
prog.push(TinyInsn::Store(TinyReg::B, 0x8000));
prog.push(TinyInsn::Halt);
let mut vm = TinyVm::new(prog);
vm.write_mem(PhysAddr(0xffff), 0xaabb);
vm.jit();
assert_eq!(0xaabb, vm.read_reg(TinyReg::A));
assert_eq!(0xf00d, vm.read_mem(PhysAddr(0x8000)));
assert_eq!(4, vm.icnt);
assert_eq!(4, vm.pc);
}
#[test]
fn test_jit_branch() {
let mut prog = Vec::new();
prog.push(TinyInsn::Branch(2));
prog.push(TinyInsn::Halt);
prog.push(TinyInsn::Branch(6));
prog.push(TinyInsn::LoadImm(TinyReg::A, 1));
prog.push(TinyInsn::LoadImm(TinyReg::B, 2));
prog.push(TinyInsn::LoadImm(TinyReg::C, 3));
prog.push(TinyInsn::Branch(1));
let mut vm = TinyVm::new(prog);
vm.jit();
assert_eq!(0, vm.read_reg(TinyReg::A));
assert_eq!(0, vm.read_reg(TinyReg::B));
assert_eq!(0, vm.read_reg(TinyReg::C));
assert_eq!(4, vm.icnt);
assert_eq!(2, vm.pc);
}
#[test]
fn test_jit_branch_zero() {
let mut prog = Vec::new();
prog.push(TinyInsn::LoadImm(TinyReg::A, 1));
prog.push(TinyInsn::BranchZero(TinyReg::A, 5));
prog.push(TinyInsn::LoadImm(TinyReg::A, 0));
prog.push(TinyInsn::BranchZero(TinyReg::A, 5));
prog.push(TinyInsn::LoadImm(TinyReg::B, 22));
prog.push(TinyInsn::Halt);
let mut vm = TinyVm::new(prog);
vm.jit();
assert_eq!(0, vm.read_reg(TinyReg::A));
assert_eq!(0, vm.read_reg(TinyReg::B));
assert_eq!(0, vm.read_reg(TinyReg::C));
assert_eq!(5, vm.icnt);
assert_eq!(6, vm.pc);
}
#[test]
fn test_mixed() {
let mut prog = Vec::new();
prog.push(TinyInsn::LoadImm(TinyReg::A, 100));
prog.push(TinyInsn::Add(TinyReg::B, TinyReg::A));
prog.push(TinyInsn::Addi(TinyReg::C, 100));
prog.push(TinyInsn::Halt);
let mut vm = TinyVm::new(prog);
vm.interp();
assert_eq!(100, vm.read_reg(TinyReg::A));
assert_eq!(100, vm.read_reg(TinyReg::B));
assert_eq!(100, vm.read_reg(TinyReg::C));
assert_eq!(4, vm.icnt);
assert_eq!(4, vm.pc);
vm.pc = 0;
vm.jit();
assert_eq!(100, vm.read_reg(TinyReg::A));
assert_eq!(200, vm.read_reg(TinyReg::B));
assert_eq!(200, vm.read_reg(TinyReg::C));
assert_eq!(8, vm.icnt);
assert_eq!(4, vm.pc);
}
}