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mlokr 2024-09-20 08:20:48 +02:00
parent 4d163a2313
commit 9e69e53e24
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10 changed files with 538 additions and 524 deletions
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7
.gitignore vendored
View file

@ -1,7 +1,4 @@
/target /target
/hbbytecode/src/opcode.rs /hbbytecode/src/instrs.rs
/hbbytecode/src/ops.rs
/hblang/src/instrs.rs
/hblang/src/disasm.rs
/.rgignore /.rgignore
rust-ice-* rustc-ice-*

1
Cargo.lock generated
View file

@ -20,6 +20,7 @@ version = "0.1.0"
name = "hblang" name = "hblang"
version = "0.1.0" version = "0.1.0"
dependencies = [ dependencies = [
"hbbytecode",
"hbvm", "hbvm",
"regalloc2", "regalloc2",
] ]

5
hbbytecode/Cargo.toml
View file

@ -2,3 +2,8 @@
name = "hbbytecode" name = "hbbytecode"
version = "0.1.0" version = "0.1.0"
edition = "2018" edition = "2018"
[features]
default = ["disasm"]
std = []
disasm = ["std"]

212
hbbytecode/build.rs
View file

@ -1,58 +1,208 @@
#![feature(iter_next_chunk)] #![feature(iter_next_chunk)]
use std::{collections::HashSet, fmt::Write};
fn main() -> Result<(), Box<dyn std::error::Error>> { fn main() -> Result<(), Box<dyn std::error::Error>> {
println!("cargo:rerun-if-changed=build.rs"); println!("cargo:rerun-if-changed=build.rs");
println!("cargo:rerun-if-changed=instructions.in"); println!("cargo:rerun-if-changed=instructions.in");
let mut generated = String::new(); let mut generated = String::new();
gen_op_structs(&mut generated)?; gen_instrs(&mut generated)?;
std::fs::write("src/ops.rs", generated)?; std::fs::write("src/instrs.rs", generated)?;
let mut generated = String::new();
gen_op_codes(&mut generated)?;
std::fs::write("src/opcode.rs", generated)?;
Ok(()) Ok(())
} }
fn gen_op_structs(generated: &mut String) -> std::fmt::Result { fn gen_instrs(generated: &mut String) -> Result<(), Box<dyn std::error::Error>> {
use std::fmt::Write; writeln!(generated, "#![allow(dead_code)] #![allow(clippy::upper_case_acronyms)]")?;
let mut seen = std::collections::HashSet::new();
writeln!(generated, "use crate::*;")?; writeln!(generated, "use crate::*;")?;
for [.., args, _] in instructions() {
if !seen.insert(args) {
continue;
}
writeln!(generated, "#[derive(Clone, Copy, Debug)]")?; '_opcode_structs: {
writeln!(generated, "#[repr(packed)]")?; let mut seen = HashSet::new();
write!(generated, "pub struct Ops{args}(")?; for [.., args, _] in instructions() {
let mut first = true; if !seen.insert(args) {
for ch in args.chars().filter(|&ch| ch != 'N') { continue;
if !std::mem::take(&mut first) {
write!(generated, ",")?;
} }
write!(generated, "pub Op{ch}")?;
writeln!(generated, "#[derive(Clone, Copy, Debug)]")?;
writeln!(generated, "#[repr(packed)]")?;
write!(generated, "pub struct Ops{args}(")?;
let mut first = true;
for ch in args.chars().filter(|&ch| ch != 'N') {
if !std::mem::take(&mut first) {
write!(generated, ",")?;
}
write!(generated, "pub Op{ch}")?;
}
writeln!(generated, ");")?;
writeln!(generated, "unsafe impl BytecodeItem for Ops{args} {{}}")?;
} }
writeln!(generated, ");")?;
writeln!(generated, "unsafe impl BytecodeItem for Ops{args} {{}}")?;
} }
'_max_size: {
let max = instructions()
.map(
|[_, _, ty, _]| {
if ty == "N" {
1
} else {
iter_args(ty).map(arg_to_width).sum::<usize>() + 1
}
},
)
.max()
.unwrap();
writeln!(generated, "pub const MAX_SIZE: usize = {max};")?;
}
'_encoders: {
for [op, name, ty, doc] in instructions() {
writeln!(generated, "/// {}", doc.trim_matches('"'))?;
let name = name.to_lowercase();
let args = comma_sep(
iter_args(ty)
.enumerate()
.map(|(i, c)| format!("{}{i}: {}", arg_to_name(c), arg_to_type(c))),
);
writeln!(generated, "pub fn {name}({args}) -> (usize, [u8; MAX_SIZE]) {{")?;
let arg_names =
comma_sep(iter_args(ty).enumerate().map(|(i, c)| format!("{}{i}", arg_to_name(c))));
writeln!(generated, " unsafe {{ crate::encode({ty}({op}, {arg_names})) }}")?;
writeln!(generated, "}}")?;
}
}
'_structs: {
let mut seen = std::collections::HashSet::new();
for [_, _, ty, _] in instructions() {
if !seen.insert(ty) {
continue;
}
let types = comma_sep(iter_args(ty).map(arg_to_type).map(|s| s.to_string()));
writeln!(generated, "#[repr(packed)] pub struct {ty}(u8, {types});")?;
}
}
'_name_list: {
writeln!(generated, "pub const NAMES: [&str; {}] = [", instructions().count())?;
for [_, name, _, _] in instructions() {
writeln!(generated, " \"{}\",", name.to_lowercase())?;
}
writeln!(generated, "];")?;
}
let instr = "Instr";
let oper = "Oper";
'_instr_enum: {
writeln!(generated, "#[derive(Debug, Clone, Copy, PartialEq, Eq)] #[repr(u8)]")?;
writeln!(generated, "pub enum {instr} {{")?;
for [id, name, ..] in instructions() {
writeln!(generated, " {name} = {id},")?;
}
writeln!(generated, "}}")?;
}
'_arg_kind: {
writeln!(generated, "#[derive(Debug, Clone, Copy, PartialEq, Eq)]")?;
writeln!(generated, "pub enum {oper} {{")?;
let mut seen = HashSet::new();
for ty in instructions().flat_map(|[.., ty, _]| iter_args(ty)) {
if !seen.insert(ty) {
continue;
}
writeln!(generated, " {ty}({}),", arg_to_type(ty))?;
}
writeln!(generated, "}}")?;
}
'_parse_opers: {
writeln!(
generated,
"/// This assumes the instruction byte is still at the beginning of the buffer"
)?;
writeln!(generated, "#[cfg(feature = \"disasm\")]")?;
writeln!(generated, "pub fn parse_args(bytes: &mut &[u8], kind: {instr}, buf: &mut std::vec::Vec<{oper}>) -> Option<()> {{")?;
writeln!(generated, " match kind {{")?;
let mut instrs = instructions().collect::<Vec<_>>();
instrs.sort_unstable_by_key(|&[.., ty, _]| ty);
for group in instrs.chunk_by(|[.., a, _], [.., b, _]| a == b) {
let ty = group[0][2];
for &[_, name, ..] in group {
writeln!(generated, " | {instr}::{name}")?;
}
generated.pop();
writeln!(generated, " => {{")?;
if iter_args(ty).count() != 0 {
writeln!(generated, " let data = crate::decode::<{ty}>(bytes)?;")?;
writeln!(
generated,
" buf.extend([{}]);",
comma_sep(
iter_args(ty).zip(1u32..).map(|(t, i)| format!("{oper}::{t}(data.{i})"))
)
)?;
} else {
writeln!(generated, " crate::decode::<{ty}>(bytes)?;")?;
}
writeln!(generated, " }}")?;
}
writeln!(generated, " }}")?;
writeln!(generated, " Some(())")?;
writeln!(generated, "}}")?;
}
std::fs::write("src/instrs.rs", generated)?;
Ok(()) Ok(())
} }
fn gen_op_codes(generated: &mut String) -> std::fmt::Result { fn comma_sep(items: impl Iterator<Item = String>) -> String {
use std::fmt::Write; items.map(|item| item.to_string()).collect::<Vec<_>>().join(", ")
for [op, name, _, comment] in instructions() {
writeln!(generated, "#[doc = {comment}]")?;
writeln!(generated, "pub const {name}: u8 = {op};")?;
}
Ok(())
} }
fn instructions() -> impl Iterator<Item = [&'static str; 4]> { fn instructions() -> impl Iterator<Item = [&'static str; 4]> {
include_str!("../hbbytecode/instructions.in") include_str!("../hbbytecode/instructions.in")
.lines() .lines()
.map(|line| line.strip_suffix(';').unwrap()) .filter_map(|line| line.strip_suffix(';'))
.map(|line| line.splitn(4, ',').map(str::trim).next_chunk().unwrap()) .map(|line| line.splitn(4, ',').map(str::trim).next_chunk().unwrap())
} }
fn arg_to_type(arg: char) -> &'static str {
match arg {
'R' | 'B' => "u8",
'H' => "u16",
'W' => "u32",
'D' | 'A' => "u64",
'P' => "i16",
'O' => "i32",
_ => panic!("unknown type: {}", arg),
}
}
fn arg_to_width(arg: char) -> usize {
match arg {
'R' | 'B' => 1,
'H' => 2,
'W' => 4,
'D' | 'A' => 8,
'P' => 2,
'O' => 4,
_ => panic!("unknown type: {}", arg),
}
}
fn arg_to_name(arg: char) -> &'static str {
match arg {
'R' => "reg",
'B' | 'H' | 'W' | 'D' => "imm",
'P' | 'O' => "offset",
'A' => "addr",
_ => panic!("unknown type: {}", arg),
}
}
fn iter_args(ty: &'static str) -> impl Iterator<Item = char> {
ty.chars().filter(|c| *c != 'N')
}

218
hbbytecode/src/lib.rs
View file

@ -1,10 +1,12 @@
#![no_std] #![no_std]
pub use crate::ops::*; #[cfg(feature = "std")]
extern crate std;
pub use crate::instrs::*;
use core::convert::TryFrom; use core::convert::TryFrom;
pub mod opcode; mod instrs;
mod ops;
type OpR = u8; type OpR = u8;
@ -22,6 +24,38 @@ type OpD = u64;
pub unsafe trait BytecodeItem {} pub unsafe trait BytecodeItem {}
unsafe impl BytecodeItem for u8 {} unsafe impl BytecodeItem for u8 {}
impl TryFrom<u8> for Instr {
type Error = u8;
#[inline]
fn try_from(value: u8) -> Result<Self, Self::Error> {
#[cold]
fn failed(value: u8) -> Result<Instr, u8> {
Err(value)
}
if value < NAMES.len() as u8 {
unsafe { Ok(std::mem::transmute::<u8, Instr>(value)) }
} else {
failed(value)
}
}
}
#[inline]
unsafe fn encode<T>(instr: T) -> (usize, [u8; instrs::MAX_SIZE]) {
let mut buf = [0; instrs::MAX_SIZE];
core::ptr::write(buf.as_mut_ptr() as *mut T, instr);
(core::mem::size_of::<T>(), buf)
}
#[inline]
fn decode<T>(binary: &mut &[u8]) -> Option<T> {
let (front, rest) = std::mem::take(binary).split_at_checked(core::mem::size_of::<T>())?;
*binary = rest;
unsafe { Some(core::ptr::read(front.as_ptr() as *const T)) }
}
/// Rounding mode /// Rounding mode
#[derive(Clone, Copy, Debug, PartialEq, Eq)] #[derive(Clone, Copy, Debug, PartialEq, Eq)]
#[repr(u8)] #[repr(u8)]
@ -39,3 +73,181 @@ impl TryFrom<u8> for RoundingMode {
(value <= 3).then(|| unsafe { core::mem::transmute(value) }).ok_or(()) (value <= 3).then(|| unsafe { core::mem::transmute(value) }).ok_or(())
} }
} }
#[cfg(feature = "disasm")]
#[derive(Clone, Copy)]
pub enum DisasmItem {
Func,
Global,
}
#[cfg(feature = "disasm")]
pub fn disasm(
binary: &mut &[u8],
functions: &std::collections::BTreeMap<u32, (&str, u32, DisasmItem)>,
out: &mut impl std::io::Write,
mut eca_handler: impl FnMut(&mut &[u8]),
) -> std::io::Result<()> {
use {
self::instrs::Instr,
std::{
collections::{hash_map::Entry, HashMap},
convert::TryInto,
vec::Vec,
},
};
fn instr_from_byte(b: u8) -> std::io::Result<Instr> {
if b as usize >= instrs::NAMES.len() {
return Err(std::io::ErrorKind::InvalidData.into());
}
Ok(unsafe { std::mem::transmute::<u8, Instr>(b) })
}
let mut labels = HashMap::<u32, u32>::default();
let mut buf = Vec::<instrs::Oper>::new();
let mut has_cycle = false;
let mut has_oob = false;
'_offset_pass: for (&off, &(_name, len, kind)) in functions.iter() {
if matches!(kind, DisasmItem::Global) {
continue;
}
let prev = *binary;
*binary = &binary[..off as usize];
let mut label_count = 0;
while let Some(&byte) = binary.first() {
let offset: i32 = (prev.len() - binary.len()).try_into().unwrap();
if offset as u32 == off + len {
break;
}
let Ok(inst) = instr_from_byte(byte) else { break };
instrs::parse_args(binary, inst, &mut buf).ok_or(std::io::ErrorKind::OutOfMemory)?;
for op in buf.drain(..) {
let rel = match op {
instrs::Oper::O(rel) => rel,
instrs::Oper::P(rel) => rel.into(),
_ => continue,
};
has_cycle |= rel == 0;
let global_offset: u32 = (offset + rel).try_into().unwrap();
if functions.get(&global_offset).is_some() {
continue;
}
label_count += match labels.entry(global_offset) {
Entry::Occupied(_) => 0,
Entry::Vacant(entry) => {
entry.insert(label_count);
1
}
}
}
if matches!(inst, Instr::ECA) {
eca_handler(binary);
}
}
*binary = prev;
}
let mut ordered = functions.iter().collect::<Vec<_>>();
ordered.sort_unstable_by_key(|(_, (name, _, _))| name);
'_dump: for (&off, &(name, len, kind)) in ordered {
if matches!(kind, DisasmItem::Global) {
continue;
}
let prev = *binary;
writeln!(out, "{name}:")?;
*binary = &binary[..off as usize];
while let Some(&byte) = binary.first() {
let offset: i32 = (prev.len() - binary.len()).try_into().unwrap();
if offset as u32 == off + len {
break;
}
let Ok(inst) = instr_from_byte(byte) else {
writeln!(out, "invalid instr {byte}")?;
break;
};
instrs::parse_args(binary, inst, &mut buf).unwrap();
if let Some(label) = labels.get(&offset.try_into().unwrap()) {
write!(out, "{:>2}: ", label)?;
} else {
write!(out, " ")?;
}
write!(out, "{inst:<8?} ")?;
'a: for (i, op) in buf.drain(..).enumerate() {
if i != 0 {
write!(out, ", ")?;
}
let rel = 'b: {
match op {
instrs::Oper::O(rel) => break 'b rel,
instrs::Oper::P(rel) => break 'b rel.into(),
instrs::Oper::R(r) => write!(out, "r{r}")?,
instrs::Oper::B(b) => write!(out, "{b}b")?,
instrs::Oper::H(h) => write!(out, "{h}h")?,
instrs::Oper::W(w) => write!(out, "{w}w")?,
instrs::Oper::D(d) if (d as i64) < 0 => write!(out, "{}d", d as i64)?,
instrs::Oper::D(d) => write!(out, "{d}d")?,
instrs::Oper::A(a) => write!(out, "{a}a")?,
}
continue 'a;
};
let global_offset: u32 = (offset + rel).try_into().unwrap();
if let Some(&(name, ..)) = functions.get(&global_offset) {
if name.contains('\0') {
write!(out, ":{name:?}")?;
} else {
write!(out, ":{name}")?;
}
} else {
let local_has_oob = global_offset < off
|| global_offset > off + len
|| instr_from_byte(prev[global_offset as usize]).is_err()
|| prev[global_offset as usize] == 0;
has_oob |= local_has_oob;
let label = labels.get(&global_offset).unwrap();
if local_has_oob {
write!(out, "!!!!!!!!!{rel}")?;
} else {
write!(out, ":{label}")?;
}
}
}
writeln!(out)?;
if matches!(inst, Instr::ECA) {
eca_handler(binary);
}
}
*binary = prev;
}
if has_oob {
return Err(std::io::ErrorKind::InvalidInput.into());
}
if has_cycle {
return Err(std::io::ErrorKind::TimedOut.into());
}
Ok(())
}

1
hblang/Cargo.toml
View file

@ -8,5 +8,6 @@ name = "hbc"
path = "src/main.rs" path = "src/main.rs"
[dependencies] [dependencies]
hbbytecode = { version = "0.1.0", path = "../hbbytecode" }
hbvm = { path = "../hbvm", features = ["nightly"] } hbvm = { path = "../hbvm", features = ["nightly"] }
regalloc2 = { git = "https://github.com/jakubDoka/regalloc2" } regalloc2 = { git = "https://github.com/jakubDoka/regalloc2" }

183
hblang/build.rs
View file

@ -1,183 +0,0 @@
#![feature(iter_next_chunk)]
use std::{collections::HashSet, fmt::Write};
fn main() -> Result<(), Box<dyn std::error::Error>> {
println!("cargo:rerun-if-changed=build.rs");
println!("cargo:rerun-if-changed=../hbbytecode/instructions.in");
gen_instrs()?;
Ok(())
}
fn gen_instrs() -> Result<(), Box<dyn std::error::Error>> {
let mut generated = String::new();
writeln!(generated, "#![allow(dead_code)] #![allow(clippy::upper_case_acronyms)]")?;
'_max_size: {
let max = instructions()
.map(
|[_, _, ty, _]| {
if ty == "N" {
1
} else {
iter_args(ty).map(arg_to_width).sum::<usize>() + 1
}
},
)
.max()
.unwrap();
writeln!(generated, "pub const MAX_SIZE: usize = {max};")?;
}
'_encoders: {
for [op, name, ty, doc] in instructions() {
writeln!(generated, "/// {}", doc.trim_matches('"'))?;
let name = name.to_lowercase();
let args = comma_sep(
iter_args(ty)
.enumerate()
.map(|(i, c)| format!("{}{i}: {}", arg_to_name(c), arg_to_type(c))),
);
writeln!(generated, "pub fn {name}({args}) -> (usize, [u8; MAX_SIZE]) {{")?;
let arg_names =
comma_sep(iter_args(ty).enumerate().map(|(i, c)| format!("{}{i}", arg_to_name(c))));
writeln!(generated, " unsafe {{ crate::encode({ty}({op}, {arg_names})) }}")?;
writeln!(generated, "}}")?;
}
}
'_structs: {
let mut seen = std::collections::HashSet::new();
for [_, _, ty, _] in instructions() {
if !seen.insert(ty) {
continue;
}
let types = comma_sep(iter_args(ty).map(arg_to_type).map(|s| s.to_string()));
writeln!(generated, "#[repr(packed)] pub struct {ty}(u8, {types});")?;
}
}
'_name_list: {
writeln!(generated, "pub const NAMES: [&str; {}] = [", instructions().count())?;
for [_, name, _, _] in instructions() {
writeln!(generated, " \"{}\",", name.to_lowercase())?;
}
writeln!(generated, "];")?;
}
let instr = "Instr";
let oper = "Oper";
'_instr_enum: {
writeln!(generated, "#[derive(Debug, Clone, Copy, PartialEq, Eq)] #[repr(u8)]")?;
writeln!(generated, "pub enum {instr} {{")?;
for [id, name, ..] in instructions() {
writeln!(generated, " {name} = {id},")?;
}
writeln!(generated, "}}")?;
}
'_arg_kind: {
writeln!(generated, "#[derive(Debug, Clone, Copy, PartialEq, Eq)]")?;
writeln!(generated, "pub enum {oper} {{")?;
let mut seen = HashSet::new();
for ty in instructions().flat_map(|[.., ty, _]| iter_args(ty)) {
if !seen.insert(ty) {
continue;
}
writeln!(generated, " {ty}({}),", arg_to_type(ty))?;
}
writeln!(generated, "}}")?;
}
'_parse_opers: {
writeln!(
generated,
"/// This assumes the instruction byte is still at the beginning of the buffer"
)?;
writeln!(generated, "pub fn parse_args(bytes: &mut &[u8], kind: {instr}, buf: &mut Vec<{oper}>) -> Option<()> {{")?;
writeln!(generated, " match kind {{")?;
let mut instrs = instructions().collect::<Vec<_>>();
instrs.sort_unstable_by_key(|&[.., ty, _]| ty);
for group in instrs.chunk_by(|[.., a, _], [.., b, _]| a == b) {
let ty = group[0][2];
for &[_, name, ..] in group {
writeln!(generated, " | {instr}::{name}")?;
}
generated.pop();
writeln!(generated, " => {{")?;
if iter_args(ty).count() != 0 {
writeln!(generated, " let data = crate::decode::<{ty}>(bytes)?;")?;
writeln!(
generated,
" buf.extend([{}]);",
comma_sep(
iter_args(ty).zip(1u32..).map(|(t, i)| format!("{oper}::{t}(data.{i})"))
)
)?;
} else {
writeln!(generated, " crate::decode::<{ty}>(bytes)?;")?;
}
writeln!(generated, " }}")?;
}
writeln!(generated, " }}")?;
writeln!(generated, " Some(())")?;
writeln!(generated, "}}")?;
}
std::fs::write("src/instrs.rs", generated)?;
Ok(())
}
fn comma_sep(items: impl Iterator<Item = String>) -> String {
items.map(|item| item.to_string()).collect::<Vec<_>>().join(", ")
}
fn instructions() -> impl Iterator<Item = [&'static str; 4]> {
include_str!("../hbbytecode/instructions.in")
.lines()
.filter_map(|line| line.strip_suffix(';'))
.map(|line| line.splitn(4, ',').map(str::trim).next_chunk().unwrap())
}
fn arg_to_type(arg: char) -> &'static str {
match arg {
'R' | 'B' => "u8",
'H' => "u16",
'W' => "u32",
'D' | 'A' => "u64",
'P' => "i16",
'O' => "i32",
_ => panic!("unknown type: {}", arg),
}
}
fn arg_to_width(arg: char) -> usize {
match arg {
'R' | 'B' => 1,
'H' => 2,
'W' => 4,
'D' | 'A' => 8,
'P' => 2,
'O' => 4,
_ => panic!("unknown type: {}", arg),
}
}
fn arg_to_name(arg: char) -> &'static str {
match arg {
'R' => "reg",
'B' | 'H' | 'W' | 'D' => "imm",
'P' | 'O' => "offset",
'A' => "addr",
_ => panic!("unknown type: {}", arg),
}
}
fn iter_args(ty: &'static str) -> impl Iterator<Item = char> {
ty.chars().filter(|c| *c != 'N')
}

181
hblang/src/lib.rs
View file

@ -27,6 +27,7 @@ use {
son::reg, son::reg,
ty::ArrayLen, ty::ArrayLen,
}, },
hbbytecode as instrs,
parser::Ast, parser::Ast,
std::{ std::{
collections::{hash_map, BTreeMap, VecDeque}, collections::{hash_map, BTreeMap, VecDeque},
@ -52,7 +53,6 @@ pub mod codegen;
pub mod parser; pub mod parser;
pub mod son; pub mod son;
mod instrs;
mod lexer; mod lexer;
mod task { mod task {
@ -715,7 +715,7 @@ impl Types {
output: &mut impl std::io::Write, output: &mut impl std::io::Write,
eca_handler: impl FnMut(&mut &[u8]), eca_handler: impl FnMut(&mut &[u8]),
) -> std::io::Result<()> { ) -> std::io::Result<()> {
use crate::DisasmItem; use instrs::DisasmItem;
let functions = self let functions = self
.funcs .funcs
.iter() .iter()
@ -744,7 +744,7 @@ impl Types {
(g.offset, (name, g.data.len() as Size, DisasmItem::Global)) (g.offset, (name, g.data.len() as Size, DisasmItem::Global))
})) }))
.collect::<BTreeMap<_, _>>(); .collect::<BTreeMap<_, _>>();
crate::disasm(&mut sluce, &functions, output, eca_handler) instrs::disasm(&mut sluce, &functions, output, eca_handler)
} }
fn parama(&self, ret: impl Into<ty::Id>) -> ParamAlloc { fn parama(&self, ret: impl Into<ty::Id>) -> ParamAlloc {
@ -857,181 +857,6 @@ impl Types {
} }
} }
#[inline]
unsafe fn encode<T>(instr: T) -> (usize, [u8; instrs::MAX_SIZE]) {
let mut buf = [0; instrs::MAX_SIZE];
std::ptr::write(buf.as_mut_ptr() as *mut T, instr);
(std::mem::size_of::<T>(), buf)
}
#[inline]
fn decode<T>(binary: &mut &[u8]) -> Option<T> {
unsafe { Some(std::ptr::read(binary.take(..std::mem::size_of::<T>())?.as_ptr() as *const T)) }
}
#[derive(Clone, Copy)]
enum DisasmItem {
Func,
Global,
}
fn disasm(
binary: &mut &[u8],
functions: &BTreeMap<u32, (&str, u32, DisasmItem)>,
out: &mut impl std::io::Write,
mut eca_handler: impl FnMut(&mut &[u8]),
) -> std::io::Result<()> {
use self::instrs::Instr;
fn instr_from_byte(b: u8) -> std::io::Result<Instr> {
if b as usize >= instrs::NAMES.len() {
return Err(std::io::ErrorKind::InvalidData.into());
}
Ok(unsafe { std::mem::transmute::<u8, Instr>(b) })
}
let mut labels = HashMap::<u32, u32>::default();
let mut buf = Vec::<instrs::Oper>::new();
let mut has_cycle = false;
let mut has_oob = false;
'_offset_pass: for (&off, &(_name, len, kind)) in functions.iter() {
if matches!(kind, DisasmItem::Global) {
continue;
}
let prev = *binary;
binary.take(..off as usize).unwrap();
let mut label_count = 0;
while let Some(&byte) = binary.first() {
let offset: i32 = (prev.len() - binary.len()).try_into().unwrap();
if offset as u32 == off + len {
break;
}
let Ok(inst) = instr_from_byte(byte) else { break };
instrs::parse_args(binary, inst, &mut buf).ok_or(std::io::ErrorKind::OutOfMemory)?;
for op in buf.drain(..) {
let rel = match op {
instrs::Oper::O(rel) => rel,
instrs::Oper::P(rel) => rel.into(),
_ => continue,
};
has_cycle |= rel == 0;
let global_offset: u32 = (offset + rel).try_into().unwrap();
if functions.get(&global_offset).is_some() {
continue;
}
label_count += labels.try_insert(global_offset, label_count).is_ok() as u32;
}
if matches!(inst, Instr::ECA) {
eca_handler(binary);
}
}
*binary = prev;
}
let mut ordered = functions.iter().collect::<Vec<_>>();
ordered.sort_unstable_by_key(|(_, (name, _, _))| name);
'_dump: for (&off, &(name, len, kind)) in ordered {
if matches!(kind, DisasmItem::Global) {
continue;
}
let prev = *binary;
writeln!(out, "{name}:")?;
binary.take(..off as usize).unwrap();
while let Some(&byte) = binary.first() {
let offset: i32 = (prev.len() - binary.len()).try_into().unwrap();
if offset as u32 == off + len {
break;
}
let Ok(inst) = instr_from_byte(byte) else {
writeln!(out, "invalid instr {byte}")?;
break;
};
instrs::parse_args(binary, inst, &mut buf).unwrap();
if let Some(label) = labels.get(&offset.try_into().unwrap()) {
write!(out, "{:>2}: ", label)?;
} else {
write!(out, " ")?;
}
write!(out, "{inst:<8?} ")?;
'a: for (i, op) in buf.drain(..).enumerate() {
if i != 0 {
write!(out, ", ")?;
}
let rel = 'b: {
match op {
instrs::Oper::O(rel) => break 'b rel,
instrs::Oper::P(rel) => break 'b rel.into(),
instrs::Oper::R(r) => write!(out, "r{r}")?,
instrs::Oper::B(b) => write!(out, "{b}b")?,
instrs::Oper::H(h) => write!(out, "{h}h")?,
instrs::Oper::W(w) => write!(out, "{w}w")?,
instrs::Oper::D(d) if (d as i64) < 0 => write!(out, "{}d", d as i64)?,
instrs::Oper::D(d) => write!(out, "{d}d")?,
instrs::Oper::A(a) => write!(out, "{a}a")?,
}
continue 'a;
};
let global_offset: u32 = (offset + rel).try_into().unwrap();
if let Some(&(name, ..)) = functions.get(&global_offset) {
if name.contains('\0') {
write!(out, ":{name:?}")?;
} else {
write!(out, ":{name}")?;
}
} else {
let local_has_oob = global_offset < off
|| global_offset > off + len
|| instr_from_byte(prev[global_offset as usize]).is_err()
|| prev[global_offset as usize] == 0;
has_oob |= local_has_oob;
let label = labels.get(&global_offset).unwrap();
if local_has_oob {
write!(out, "!!!!!!!!!{rel}")?;
} else {
write!(out, ":{label}")?;
}
}
}
writeln!(out)?;
if matches!(inst, Instr::ECA) {
eca_handler(binary);
}
}
*binary = prev;
}
if has_oob {
return Err(std::io::ErrorKind::InvalidInput.into());
}
if has_cycle {
return Err(std::io::ErrorKind::TimedOut.into());
}
Ok(())
}
struct TaskQueue<T> { struct TaskQueue<T> {
inner: Mutex<TaskQueueInner<T>>, inner: Mutex<TaskQueueInner<T>>,
} }

2
hbvm/Cargo.toml
View file

@ -9,4 +9,4 @@ alloc = []
nightly = [] nightly = []
[dependencies] [dependencies]
hbbytecode = { path = "../hbbytecode" } hbbytecode = { path = "../hbbytecode", default-features = false }

252
hbvm/src/vmrun.rs
View file

@ -34,7 +34,7 @@ where
/// Program can return [`VmRunError`] if a trap handling failed /// Program can return [`VmRunError`] if a trap handling failed
#[cfg_attr(feature = "nightly", repr(align(4096)))] #[cfg_attr(feature = "nightly", repr(align(4096)))]
pub fn run(&mut self) -> Result<VmRunOk, VmRunError> { pub fn run(&mut self) -> Result<VmRunOk, VmRunError> {
use hbbytecode::opcode::*; use hbbytecode::Instr as I;
loop { loop {
// Big match // Big match
// //
@ -56,105 +56,112 @@ where
// - Yes, we assume you run 64 bit CPU. Else ?conradluget a better CPU // - Yes, we assume you run 64 bit CPU. Else ?conradluget a better CPU
// sorry 8 bit fans, HBVM won't run on your Speccy :( // sorry 8 bit fans, HBVM won't run on your Speccy :(
unsafe { unsafe {
match self.memory.prog_read::<u8>(self.pc as _) { match self
UN => { .memory
.prog_read::<u8>(self.pc as _)
.try_into()
.map_err(VmRunError::InvalidOpcode)?
{
I::UN => {
self.bump_pc::<OpsN>(); self.bump_pc::<OpsN>();
return Err(VmRunError::Unreachable); return Err(VmRunError::Unreachable);
} }
TX => { I::TX => {
self.bump_pc::<OpsN>(); self.bump_pc::<OpsN>();
return Ok(VmRunOk::End); return Ok(VmRunOk::End);
} }
NOP => handler!(self, |OpsN()| ()), I::NOP => handler!(self, |OpsN()| ()),
ADD8 => self.binary_op(u8::wrapping_add), I::ADD8 => self.binary_op(u8::wrapping_add),
ADD16 => self.binary_op(u16::wrapping_add), I::ADD16 => self.binary_op(u16::wrapping_add),
ADD32 => self.binary_op(u32::wrapping_add), I::ADD32 => self.binary_op(u32::wrapping_add),
ADD64 => self.binary_op(u64::wrapping_add), I::ADD64 => self.binary_op(u64::wrapping_add),
SUB8 => self.binary_op(u8::wrapping_sub), I::SUB8 => self.binary_op(u8::wrapping_sub),
SUB16 => self.binary_op(u16::wrapping_sub), I::SUB16 => self.binary_op(u16::wrapping_sub),
SUB32 => self.binary_op(u32::wrapping_sub), I::SUB32 => self.binary_op(u32::wrapping_sub),
SUB64 => self.binary_op(u64::wrapping_sub), I::SUB64 => self.binary_op(u64::wrapping_sub),
MUL8 => self.binary_op(u8::wrapping_mul), I::MUL8 => self.binary_op(u8::wrapping_mul),
MUL16 => self.binary_op(u16::wrapping_mul), I::MUL16 => self.binary_op(u16::wrapping_mul),
MUL32 => self.binary_op(u32::wrapping_mul), I::MUL32 => self.binary_op(u32::wrapping_mul),
MUL64 => self.binary_op(u64::wrapping_mul), I::MUL64 => self.binary_op(u64::wrapping_mul),
AND => self.binary_op::<u64>(ops::BitAnd::bitand), I::AND => self.binary_op::<u64>(ops::BitAnd::bitand),
OR => self.binary_op::<u64>(ops::BitOr::bitor), I::OR => self.binary_op::<u64>(ops::BitOr::bitor),
XOR => self.binary_op::<u64>(ops::BitXor::bitxor), I::XOR => self.binary_op::<u64>(ops::BitXor::bitxor),
SLU8 => self.binary_op_shift::<u8>(u8::wrapping_shl), I::SLU8 => self.binary_op_shift::<u8>(u8::wrapping_shl),
SLU16 => self.binary_op_shift::<u16>(u16::wrapping_shl), I::SLU16 => self.binary_op_shift::<u16>(u16::wrapping_shl),
SLU32 => self.binary_op_shift::<u32>(u32::wrapping_shl), I::SLU32 => self.binary_op_shift::<u32>(u32::wrapping_shl),
SLU64 => self.binary_op_shift::<u64>(u64::wrapping_shl), I::SLU64 => self.binary_op_shift::<u64>(u64::wrapping_shl),
SRU8 => self.binary_op_shift::<u8>(u8::wrapping_shr), I::SRU8 => self.binary_op_shift::<u8>(u8::wrapping_shr),
SRU16 => self.binary_op_shift::<u16>(u16::wrapping_shr), I::SRU16 => self.binary_op_shift::<u16>(u16::wrapping_shr),
SRU32 => self.binary_op_shift::<u32>(u32::wrapping_shr), I::SRU32 => self.binary_op_shift::<u32>(u32::wrapping_shr),
SRU64 => self.binary_op_shift::<u64>(u64::wrapping_shr), I::SRU64 => self.binary_op_shift::<u64>(u64::wrapping_shr),
SRS8 => self.binary_op_shift::<i8>(i8::wrapping_shr), I::SRS8 => self.binary_op_shift::<i8>(i8::wrapping_shr),
SRS16 => self.binary_op_shift::<i16>(i16::wrapping_shr), I::SRS16 => self.binary_op_shift::<i16>(i16::wrapping_shr),
SRS32 => self.binary_op_shift::<i32>(i32::wrapping_shr), I::SRS32 => self.binary_op_shift::<i32>(i32::wrapping_shr),
SRS64 => self.binary_op_shift::<i64>(i64::wrapping_shr), I::SRS64 => self.binary_op_shift::<i64>(i64::wrapping_shr),
CMPU => handler!(self, |OpsRRR(tg, a0, a1)| self.cmp( I::CMPU => handler!(self, |OpsRRR(tg, a0, a1)| self.cmp(
tg, tg,
a0, a0,
self.read_reg(a1).cast::<u64>() self.read_reg(a1).cast::<u64>()
)), )),
CMPS => handler!(self, |OpsRRR(tg, a0, a1)| self.cmp( I::CMPS => handler!(self, |OpsRRR(tg, a0, a1)| self.cmp(
tg, tg,
a0, a0,
self.read_reg(a1).cast::<i64>() self.read_reg(a1).cast::<i64>()
)), )),
DIRU8 => self.dir::<u8>(), I::DIRU8 => self.dir::<u8>(),
DIRU16 => self.dir::<u16>(), I::DIRU16 => self.dir::<u16>(),
DIRU32 => self.dir::<u32>(), I::DIRU32 => self.dir::<u32>(),
DIRU64 => self.dir::<u64>(), I::DIRU64 => self.dir::<u64>(),
DIRS8 => self.dir::<i8>(), I::DIRS8 => self.dir::<i8>(),
DIRS16 => self.dir::<i16>(), I::DIRS16 => self.dir::<i16>(),
DIRS32 => self.dir::<i32>(), I::DIRS32 => self.dir::<i32>(),
DIRS64 => self.dir::<i64>(), I::DIRS64 => self.dir::<i64>(),
NEG => handler!(self, |OpsRR(tg, a0)| { I::NEG => handler!(self, |OpsRR(tg, a0)| {
// Bit negation // Bit negation
self.write_reg(tg, self.read_reg(a0).cast::<u64>().wrapping_neg()) self.write_reg(tg, self.read_reg(a0).cast::<u64>().wrapping_neg())
}), }),
NOT => handler!(self, |OpsRR(tg, a0)| { I::NOT => handler!(self, |OpsRR(tg, a0)| {
// Logical negation // Logical negation
self.write_reg(tg, u64::from(self.read_reg(a0).cast::<u64>() == 0)); self.write_reg(tg, u64::from(self.read_reg(a0).cast::<u64>() == 0));
}), }),
SXT8 => handler!(self, |OpsRR(tg, a0)| { I::SXT8 => handler!(self, |OpsRR(tg, a0)| {
self.write_reg(tg, self.read_reg(a0).cast::<i8>() as i64) self.write_reg(tg, self.read_reg(a0).cast::<i8>() as i64)
}), }),
SXT16 => handler!(self, |OpsRR(tg, a0)| { I::SXT16 => handler!(self, |OpsRR(tg, a0)| {
self.write_reg(tg, self.read_reg(a0).cast::<i16>() as i64) self.write_reg(tg, self.read_reg(a0).cast::<i16>() as i64)
}), }),
SXT32 => handler!(self, |OpsRR(tg, a0)| { I::SXT32 => handler!(self, |OpsRR(tg, a0)| {
self.write_reg(tg, self.read_reg(a0).cast::<i32>() as i64) self.write_reg(tg, self.read_reg(a0).cast::<i32>() as i64)
}), }),
ADDI8 => self.binary_op_imm(u8::wrapping_add), I::ADDI8 => self.binary_op_imm(u8::wrapping_add),
ADDI16 => self.binary_op_imm(u16::wrapping_add), I::ADDI16 => self.binary_op_imm(u16::wrapping_add),
ADDI32 => self.binary_op_imm(u32::wrapping_add), I::ADDI32 => self.binary_op_imm(u32::wrapping_add),
ADDI64 => self.binary_op_imm(u64::wrapping_add), I::ADDI64 => self.binary_op_imm(u64::wrapping_add),
MULI8 => self.binary_op_imm(u8::wrapping_mul), I::MULI8 => self.binary_op_imm(u8::wrapping_mul),
MULI16 => self.binary_op_imm(u16::wrapping_mul), I::MULI16 => self.binary_op_imm(u16::wrapping_mul),
MULI32 => self.binary_op_imm(u32::wrapping_mul), I::MULI32 => self.binary_op_imm(u32::wrapping_mul),
MULI64 => self.binary_op_imm(u64::wrapping_mul), I::MULI64 => self.binary_op_imm(u64::wrapping_mul),
ANDI => self.binary_op_imm::<u64>(ops::BitAnd::bitand), I::ANDI => self.binary_op_imm::<u64>(ops::BitAnd::bitand),
ORI => self.binary_op_imm::<u64>(ops::BitOr::bitor), I::ORI => self.binary_op_imm::<u64>(ops::BitOr::bitor),
XORI => self.binary_op_imm::<u64>(ops::BitXor::bitxor), I::XORI => self.binary_op_imm::<u64>(ops::BitXor::bitxor),
SLUI8 => self.binary_op_ims::<u8>(u8::wrapping_shl), I::SLUI8 => self.binary_op_ims::<u8>(u8::wrapping_shl),
SLUI16 => self.binary_op_ims::<u16>(u16::wrapping_shl), I::SLUI16 => self.binary_op_ims::<u16>(u16::wrapping_shl),
SLUI32 => self.binary_op_ims::<u32>(u32::wrapping_shl), I::SLUI32 => self.binary_op_ims::<u32>(u32::wrapping_shl),
SLUI64 => self.binary_op_ims::<u64>(u64::wrapping_shl), I::SLUI64 => self.binary_op_ims::<u64>(u64::wrapping_shl),
SRUI8 => self.binary_op_ims::<u8>(u8::wrapping_shr), I::SRUI8 => self.binary_op_ims::<u8>(u8::wrapping_shr),
SRUI16 => self.binary_op_ims::<u16>(u16::wrapping_shr), I::SRUI16 => self.binary_op_ims::<u16>(u16::wrapping_shr),
SRUI32 => self.binary_op_ims::<u32>(u32::wrapping_shr), I::SRUI32 => self.binary_op_ims::<u32>(u32::wrapping_shr),
SRUI64 => self.binary_op_ims::<u64>(u64::wrapping_shr), I::SRUI64 => self.binary_op_ims::<u64>(u64::wrapping_shr),
SRSI8 => self.binary_op_ims::<i8>(i8::wrapping_shr), I::SRSI8 => self.binary_op_ims::<i8>(i8::wrapping_shr),
SRSI16 => self.binary_op_ims::<i16>(i16::wrapping_shr), I::SRSI16 => self.binary_op_ims::<i16>(i16::wrapping_shr),
SRSI32 => self.binary_op_ims::<i32>(i32::wrapping_shr), I::SRSI32 => self.binary_op_ims::<i32>(i32::wrapping_shr),
SRSI64 => self.binary_op_ims::<i64>(i64::wrapping_shr), I::SRSI64 => self.binary_op_ims::<i64>(i64::wrapping_shr),
CMPUI => handler!(self, |OpsRRD(tg, a0, imm)| { self.cmp(tg, a0, imm) }), I::CMPUI => handler!(self, |OpsRRD(tg, a0, imm)| { self.cmp(tg, a0, imm) }),
CMPSI => handler!(self, |OpsRRD(tg, a0, imm)| { self.cmp(tg, a0, imm as i64) }), I::CMPSI => {
CP => handler!(self, |OpsRR(tg, a0)| self.write_reg(tg, self.read_reg(a0))), handler!(self, |OpsRRD(tg, a0, imm)| { self.cmp(tg, a0, imm as i64) })
SWA => handler!(self, |OpsRR(r0, r1)| { }
I::CP => handler!(self, |OpsRR(tg, a0)| self.write_reg(tg, self.read_reg(a0))),
I::SWA => handler!(self, |OpsRR(r0, r1)| {
// Swap registers // Swap registers
match (r0, r1) { match (r0, r1) {
(0, 0) => (), (0, 0) => (),
@ -167,33 +174,33 @@ where
} }
} }
}), }),
LI8 => handler!(self, |OpsRB(tg, imm)| self.write_reg(tg, imm)), I::LI8 => handler!(self, |OpsRB(tg, imm)| self.write_reg(tg, imm)),
LI16 => handler!(self, |OpsRH(tg, imm)| self.write_reg(tg, imm)), I::LI16 => handler!(self, |OpsRH(tg, imm)| self.write_reg(tg, imm)),
LI32 => handler!(self, |OpsRW(tg, imm)| self.write_reg(tg, imm)), I::LI32 => handler!(self, |OpsRW(tg, imm)| self.write_reg(tg, imm)),
LI64 => handler!(self, |OpsRD(tg, imm)| self.write_reg(tg, imm)), I::LI64 => handler!(self, |OpsRD(tg, imm)| self.write_reg(tg, imm)),
LRA => handler!(self, |OpsRRO(tg, reg, off)| self.write_reg( I::LRA => handler!(self, |OpsRRO(tg, reg, off)| self.write_reg(
tg, tg,
self.pcrel(off).wrapping_add(self.read_reg(reg).cast::<i64>()).get(), self.pcrel(off).wrapping_add(self.read_reg(reg).cast::<i64>()).get(),
)), )),
// Load. If loading more than register size, continue on adjecent registers // Load. If loading more than register size, continue on adjecent registers
LD => handler!(self, |OpsRRAH(dst, base, off, count)| self I::LD => handler!(self, |OpsRRAH(dst, base, off, count)| self
.load(dst, base, off, count)?), .load(dst, base, off, count)?),
// Store. Same rules apply as to LD // Store. Same rules apply as to LD
ST => handler!(self, |OpsRRAH(dst, base, off, count)| self I::ST => handler!(self, |OpsRRAH(dst, base, off, count)| self
.store(dst, base, off, count)?), .store(dst, base, off, count)?),
LDR => handler!(self, |OpsRROH(dst, base, off, count)| self.load( I::LDR => handler!(self, |OpsRROH(dst, base, off, count)| self.load(
dst, dst,
base, base,
self.pcrel(off).get(), self.pcrel(off).get(),
count count
)?), )?),
STR => handler!(self, |OpsRROH(dst, base, off, count)| self.store( I::STR => handler!(self, |OpsRROH(dst, base, off, count)| self.store(
dst, dst,
base, base,
self.pcrel(off).get(), self.pcrel(off).get(),
count count
)?), )?),
BMC => { I::BMC => {
// Block memory copy // Block memory copy
match if let Some(copier) = &mut self.copier { match if let Some(copier) = &mut self.copier {
// There is some copier, poll. // There is some copier, poll.
@ -227,7 +234,7 @@ where
core::task::Poll::Pending => (), core::task::Poll::Pending => (),
} }
} }
BRC => handler!(self, |OpsRRB(src, dst, count)| { I::BRC => handler!(self, |OpsRRB(src, dst, count)| {
// Block register copy // Block register copy
if src.checked_add(count).is_none() || dst.checked_add(count).is_none() { if src.checked_add(count).is_none() || dst.checked_add(count).is_none() {
return Err(VmRunError::RegOutOfBounds); return Err(VmRunError::RegOutOfBounds);
@ -239,11 +246,11 @@ where
usize::from(count), usize::from(count),
); );
}), }),
JMP => { I::JMP => {
let OpsO(off) = self.decode(); let OpsO(off) = self.decode();
self.pc = self.pc.wrapping_add(off); self.pc = self.pc.wrapping_add(off);
} }
JAL => { I::JAL => {
// Jump and link. Save PC after this instruction to // Jump and link. Save PC after this instruction to
// specified register and jump to reg + relative offset. // specified register and jump to reg + relative offset.
let OpsRRO(save, reg, offset) = self.decode(); let OpsRRO(save, reg, offset) = self.decode();
@ -251,7 +258,7 @@ where
self.write_reg(save, self.pc.next::<OpsRRO>()); self.write_reg(save, self.pc.next::<OpsRRO>());
self.pc = self.pcrel(offset).wrapping_add(self.read_reg(reg).cast::<i64>()); self.pc = self.pcrel(offset).wrapping_add(self.read_reg(reg).cast::<i64>());
} }
JALA => { I::JALA => {
// Jump and link. Save PC after this instruction to // Jump and link. Save PC after this instruction to
// specified register and jump to reg // specified register and jump to reg
let OpsRRA(save, reg, offset) = self.decode(); let OpsRRA(save, reg, offset) = self.decode();
@ -261,8 +268,8 @@ where
Address::new(self.read_reg(reg).cast::<u64>().wrapping_add(offset)); Address::new(self.read_reg(reg).cast::<u64>().wrapping_add(offset));
} }
// Conditional jumps, jump only to immediates // Conditional jumps, jump only to immediates
JEQ => self.cond_jmp::<u64>(Ordering::Equal), I::JEQ => self.cond_jmp::<u64>(Ordering::Equal),
JNE => { I::JNE => {
let OpsRRP(a0, a1, ja) = self.decode(); let OpsRRP(a0, a1, ja) = self.decode();
if self.read_reg(a0).cast::<u64>() != self.read_reg(a1).cast::<u64>() { if self.read_reg(a0).cast::<u64>() != self.read_reg(a1).cast::<u64>() {
self.pc = self.pcrel(ja); self.pc = self.pcrel(ja);
@ -270,11 +277,11 @@ where
self.bump_pc::<OpsRRP>(); self.bump_pc::<OpsRRP>();
} }
} }
JLTS => self.cond_jmp::<i64>(Ordering::Less), I::JLTS => self.cond_jmp::<i64>(Ordering::Less),
JGTS => self.cond_jmp::<i64>(Ordering::Greater), I::JGTS => self.cond_jmp::<i64>(Ordering::Greater),
JLTU => self.cond_jmp::<u64>(Ordering::Less), I::JLTU => self.cond_jmp::<u64>(Ordering::Less),
JGTU => self.cond_jmp::<u64>(Ordering::Greater), I::JGTU => self.cond_jmp::<u64>(Ordering::Greater),
ECA => { I::ECA => {
// So we don't get timer interrupt after ECALL // So we don't get timer interrupt after ECALL
if TIMER_QUOTIENT != 0 { if TIMER_QUOTIENT != 0 {
self.timer = self.timer.wrapping_add(1); self.timer = self.timer.wrapping_add(1);
@ -283,33 +290,33 @@ where
self.bump_pc::<OpsN>(); self.bump_pc::<OpsN>();
return Ok(VmRunOk::Ecall); return Ok(VmRunOk::Ecall);
} }
EBP => { I::EBP => {
self.bump_pc::<OpsN>(); self.bump_pc::<OpsN>();
return Ok(VmRunOk::Breakpoint); return Ok(VmRunOk::Breakpoint);
} }
FADD32 => self.binary_op::<f32>(ops::Add::add), I::FADD32 => self.binary_op::<f32>(ops::Add::add),
FADD64 => self.binary_op::<f64>(ops::Add::add), I::FADD64 => self.binary_op::<f64>(ops::Add::add),
FSUB32 => self.binary_op::<f32>(ops::Sub::sub), I::FSUB32 => self.binary_op::<f32>(ops::Sub::sub),
FSUB64 => self.binary_op::<f64>(ops::Sub::sub), I::FSUB64 => self.binary_op::<f64>(ops::Sub::sub),
FMUL32 => self.binary_op::<f32>(ops::Mul::mul), I::FMUL32 => self.binary_op::<f32>(ops::Mul::mul),
FMUL64 => self.binary_op::<f64>(ops::Mul::mul), I::FMUL64 => self.binary_op::<f64>(ops::Mul::mul),
FDIV32 => self.binary_op::<f32>(ops::Div::div), I::FDIV32 => self.binary_op::<f32>(ops::Div::div),
FDIV64 => self.binary_op::<f64>(ops::Div::div), I::FDIV64 => self.binary_op::<f64>(ops::Div::div),
FMA32 => self.fma::<f32>(), I::FMA32 => self.fma::<f32>(),
FMA64 => self.fma::<f64>(), I::FMA64 => self.fma::<f64>(),
FINV32 => handler!(self, |OpsRR(tg, reg)| self I::FINV32 => handler!(self, |OpsRR(tg, reg)| self
.write_reg(tg, 1. / self.read_reg(reg).cast::<f32>())), .write_reg(tg, 1. / self.read_reg(reg).cast::<f32>())),
FINV64 => handler!(self, |OpsRR(tg, reg)| self I::FINV64 => handler!(self, |OpsRR(tg, reg)| self
.write_reg(tg, 1. / self.read_reg(reg).cast::<f64>())), .write_reg(tg, 1. / self.read_reg(reg).cast::<f64>())),
FCMPLT32 => self.fcmp::<f32>(Ordering::Less), I::FCMPLT32 => self.fcmp::<f32>(Ordering::Less),
FCMPLT64 => self.fcmp::<f64>(Ordering::Less), I::FCMPLT64 => self.fcmp::<f64>(Ordering::Less),
FCMPGT32 => self.fcmp::<f32>(Ordering::Greater), I::FCMPGT32 => self.fcmp::<f32>(Ordering::Greater),
FCMPGT64 => self.fcmp::<f64>(Ordering::Greater), I::FCMPGT64 => self.fcmp::<f64>(Ordering::Greater),
ITF32 => handler!(self, |OpsRR(tg, reg)| self I::ITF32 => handler!(self, |OpsRR(tg, reg)| self
.write_reg(tg, self.read_reg(reg).cast::<i64>() as f32)), .write_reg(tg, self.read_reg(reg).cast::<i64>() as f32)),
ITF64 => handler!(self, |OpsRR(tg, reg)| self I::ITF64 => handler!(self, |OpsRR(tg, reg)| self
.write_reg(tg, self.read_reg(reg).cast::<i64>() as f64)), .write_reg(tg, self.read_reg(reg).cast::<i64>() as f64)),
FTI32 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg( I::FTI32 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg(
tg, tg,
crate::float::f32toint( crate::float::f32toint(
self.read_reg(reg).cast::<f32>(), self.read_reg(reg).cast::<f32>(),
@ -317,7 +324,7 @@ where
.map_err(|()| VmRunError::InvalidOperand)?, .map_err(|()| VmRunError::InvalidOperand)?,
), ),
)), )),
FTI64 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg( I::FTI64 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg(
tg, tg,
crate::float::f64toint( crate::float::f64toint(
self.read_reg(reg).cast::<f64>(), self.read_reg(reg).cast::<f64>(),
@ -325,9 +332,9 @@ where
.map_err(|()| VmRunError::InvalidOperand)?, .map_err(|()| VmRunError::InvalidOperand)?,
), ),
)), )),
FC32T64 => handler!(self, |OpsRR(tg, reg)| self I::FC32T64 => handler!(self, |OpsRR(tg, reg)| self
.write_reg(tg, self.read_reg(reg).cast::<f32>() as f64)), .write_reg(tg, self.read_reg(reg).cast::<f32>() as f64)),
FC64T32 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg( I::FC64T32 => handler!(self, |OpsRRB(tg, reg, mode)| self.write_reg(
tg, tg,
crate::float::conv64to32( crate::float::conv64to32(
self.read_reg(reg).cast(), self.read_reg(reg).cast(),
@ -335,27 +342,26 @@ where
.map_err(|()| VmRunError::InvalidOperand)?, .map_err(|()| VmRunError::InvalidOperand)?,
), ),
)), )),
LRA16 => handler!(self, |OpsRRP(tg, reg, imm)| self.write_reg( I::LRA16 => handler!(self, |OpsRRP(tg, reg, imm)| self.write_reg(
tg, tg,
(self.pc + self.read_reg(reg).cast::<u64>() + imm + 3_u16).get(), (self.pc + self.read_reg(reg).cast::<u64>() + imm + 3_u16).get(),
)), )),
LDR16 => handler!(self, |OpsRRPH(dst, base, off, count)| self.load( I::LDR16 => handler!(self, |OpsRRPH(dst, base, off, count)| self.load(
dst, dst,
base, base,
self.pcrel(off).get(), self.pcrel(off).get(),
count count
)?), )?),
STR16 => handler!(self, |OpsRRPH(dst, base, off, count)| self.store( I::STR16 => handler!(self, |OpsRRPH(dst, base, off, count)| self.store(
dst, dst,
base, base,
self.pcrel(off).get(), self.pcrel(off).get(),
count count
)?), )?),
JMP16 => { I::JMP16 => {
let OpsP(off) = self.decode(); let OpsP(off) = self.decode();
self.pc = self.pcrel(off); self.pc = self.pcrel(off);
} }
op => return Err(VmRunError::InvalidOpcode(op)),
} }
} }