use std::io::Write;
use std::ops::{Index, IndexMut};
use crate::opcode::{CodeIdx, ConstantIdx, OpCode};
use crate::value::Value;
use crate::SourceCode;
/// Represents a source location from which one or more operations
/// were compiled.
///
/// The span itself is an index into a [codemap::CodeMap], and the
/// structure tracks the number of operations that were yielded from
/// the same span.
///
/// At error reporting time, it becomes possible to either just fetch
/// the textual representation of that span from the codemap, or to
/// even re-parse the AST using rnix to create more semantically
/// interesting errors.
#[derive(Clone, Debug, PartialEq)]
struct SourceSpan {
/// Span into the [codemap::CodeMap].
span: codemap::Span,
/// Index of the first operation covered by this span.
start: usize,
}
/// A chunk is a representation of a sequence of bytecode
/// instructions, associated constants and additional metadata as
/// emitted by the compiler.
#[derive(Debug, Default)]
pub struct Chunk {
pub code: Vec<OpCode>,
pub constants: Vec<Value>,
spans: Vec<SourceSpan>,
}
impl Index<ConstantIdx> for Chunk {
type Output = Value;
fn index(&self, index: ConstantIdx) -> &Self::Output {
&self.constants[index.0]
}
}
impl Index<CodeIdx> for Chunk {
type Output = OpCode;
fn index(&self, index: CodeIdx) -> &Self::Output {
&self.code[index.0]
}
}
impl IndexMut<CodeIdx> for Chunk {
fn index_mut(&mut self, index: CodeIdx) -> &mut Self::Output {
&mut self.code[index.0]
}
}
impl Chunk {
pub fn push_op(&mut self, data: OpCode, span: codemap::Span) -> CodeIdx {
let idx = self.code.len();
self.code.push(data);
self.push_span(span, idx);
CodeIdx(idx)
}
/// Get the first span of a chunk, no questions asked.
pub fn first_span(&self) -> codemap::Span {
self.spans[0].span
}
/// Return a reference to the last op in the chunk, if any
pub fn last_op(&self) -> Option<&OpCode> {
self.code.last()
}
/// Pop the last operation from the chunk and clean up its tracked
/// span. Used when the compiler backtracks.
pub fn pop_op(&mut self) {
// Simply drop the last op.
self.code.pop();
if let Some(span) = self.spans.last() {
// If the last span started at this op, drop it.
if span.start == self.code.len() {
self.spans.pop();
}
}
}
pub fn push_constant(&mut self, data: Value) -> ConstantIdx {
let idx = self.constants.len();
self.constants.push(data);
ConstantIdx(idx)
}
/// Return a reference to the constant at the given [`ConstantIdx`]
pub fn get_constant(&self, constant: ConstantIdx) -> Option<&Value> {
self.constants.get(constant.0)
}
// Span tracking implementation
fn push_span(&mut self, span: codemap::Span, start: usize) {
match self.spans.last_mut() {
// We do not need to insert the same span again, as this
// instruction was compiled from the same span as the last
// one.
Some(last) if last.span == span => {}
// In all other cases, this is a new source span.
_ => self.spans.push(SourceSpan { span, start }),
}
}
/// Retrieve the [codemap::Span] from which the instruction at
/// `offset` was compiled.
pub fn get_span(&self, offset: CodeIdx) -> codemap::Span {
let position = self
.spans
.binary_search_by(|span| span.start.cmp(&offset.0));
let span = match position {
Ok(index) => &self.spans[index],
Err(index) => {
if index == 0 {
&self.spans[0]
} else {
&self.spans[index - 1]
}
}
};
span.span
}
/// Write the disassembler representation of the operation at
/// `idx` to the specified writer.
pub fn disassemble_op<W: Write>(
&self,
writer: &mut W,
source: &SourceCode,
width: usize,
idx: CodeIdx,
) -> Result<(), std::io::Error> {
write!(writer, "{:#width$x}\t ", idx.0, width = width)?;
// Print continuation character if the previous operation was at
// the same line, otherwise print the line.
let line = source.get_line(self.get_span(idx));
if idx.0 > 0 && source.get_line(self.get_span(CodeIdx(idx.0 - 1))) == line {
write!(writer, " |\t")?;
} else {
write!(writer, "{:4}\t", line)?;
}
let a = |idx| {
match &self[idx] {
Value::Thunk(t) => t.debug_repr(),
Value::Closure(c) => format!("closure({:p})", c.lambda),
Value::Blueprint(b) => format!("blueprint({:p})", b),
val => format!("{}", val),
}
};
match self[idx] {
OpCode::OpConstant(idx) => {
writeln!(writer, "OpConstant({}@{})", a(idx), idx.0)
}
OpCode::OpClosure(idx) => {
writeln!(writer, "OpClosure({}@{})", a(idx), idx.0)
}
OpCode::OpThunkClosure(idx) => {
writeln!(writer, "OpThunkClosure({}@{})", a(idx), idx.0)
}
OpCode::OpThunkSuspended(idx) => {
writeln!(writer, "OpThunkSuspended({}@{})", a(idx), idx.0)
}
op => writeln!(writer, "{:?}", op),
}?;
Ok(())
}
/// Extend this chunk with the content of another, moving out of the other
/// in the process.
///
/// This is used by the compiler when it detects that it unnecessarily
/// thunked a nested expression.
pub fn extend(&mut self, other: Self) {
// Some operations need to be modified in certain ways before being
// valid as part of the new chunk.
let const_count = self.constants.len();
for (idx, op) in other.code.iter().enumerate() {
let span = other.get_span(CodeIdx(idx));
match op {
// As the constants shift, the index needs to be moved relatively.
OpCode::OpConstant(ConstantIdx(idx)) => {
self.push_op(OpCode::OpConstant(ConstantIdx(idx + const_count)), span)
}
// Other operations either operate on relative offsets, or no
// offsets, and are safe to keep as-is.
_ => self.push_op(*op, span),
};
}
self.constants.extend(other.constants);
self.spans.extend(other.spans);
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::test_utils::dummy_span;
// Note: These tests are about the functionality of the `Chunk` type, the
// opcodes used below do *not* represent valid, executable Tvix code (and
// don't need to).
#[test]
fn push_op() {
let mut chunk = Chunk::default();
chunk.push_op(OpCode::OpAdd, dummy_span());
assert_eq!(chunk.code.last().unwrap(), &OpCode::OpAdd);
}
#[test]
fn extend_empty() {
let mut chunk = Chunk::default();
chunk.push_op(OpCode::OpAdd, dummy_span());
let other = Chunk::default();
chunk.extend(other);
assert_eq!(
chunk.code,
vec![OpCode::OpAdd],
"code should not have changed"
);
}
#[test]
fn extend_simple() {
let span = dummy_span();
let mut chunk = Chunk::default();
chunk.push_op(OpCode::OpAdd, span);
let mut other = Chunk::default();
other.push_op(OpCode::OpSub, span);
other.push_op(OpCode::OpMul, span);
let expected_code = vec![OpCode::OpAdd, OpCode::OpSub, OpCode::OpMul];
chunk.extend(other);
assert_eq!(chunk.code, expected_code, "code should have been extended");
}
#[test]
fn extend_with_constant() {
let span = dummy_span();
let mut chunk = Chunk::default();
chunk.push_op(OpCode::OpAdd, span);
let cidx = chunk.push_constant(Value::Integer(0));
assert_eq!(
cidx.0, 0,
"first constant in main chunk should have index 0"
);
chunk.push_op(OpCode::OpConstant(cidx), span);
let mut other = Chunk::default();
other.push_op(OpCode::OpSub, span);
let other_cidx = other.push_constant(Value::Integer(1));
assert_eq!(
other_cidx.0, 0,
"first constant in other chunk should have index 0"
);
other.push_op(OpCode::OpConstant(other_cidx), span);
chunk.extend(other);
let expected_code = vec![
OpCode::OpAdd,
OpCode::OpConstant(ConstantIdx(0)),
OpCode::OpSub,
OpCode::OpConstant(ConstantIdx(1)), // <- note: this was rewritten
];
assert_eq!(
chunk.code, expected_code,
"code should have been extended and rewritten"
);
assert_eq!(chunk.constants.len(), 2);
assert!(matches!(chunk.constants[0], Value::Integer(0)));
assert!(matches!(chunk.constants[1], Value::Integer(1)));
}
}