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Continue Value/VM overhaul

This commit is contained in:
Jeff 2024-11-15 19:18:00 -05:00
parent 73247446c7
commit 302bc9ce6c
11 changed files with 809 additions and 1424 deletions

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@ -8,18 +8,18 @@ use std::fmt::{self, Debug, Display, Formatter};
use serde::{Deserialize, Serialize}; use serde::{Deserialize, Serialize};
use crate::{value::ConcreteValue, Disassembler, FunctionType, Instruction, Scope, Span, Type}; use crate::{value::Value, Disassembler, FunctionType, Instruction, Scope, Span, Type};
/// In-memory representation of a Dust program or function. /// In-memory representation of a Dust program or function.
/// ///
/// See the [module-level documentation](index.html) for more information. /// See the [module-level documentation](index.html) for more information.
#[derive(Clone, PartialOrd, Ord, Serialize, Deserialize)] #[derive(Clone, PartialOrd, Serialize, Deserialize)]
pub struct Chunk { pub struct Chunk {
name: Option<String>, // TODO: Use a bool indicating whether the chunk is named. If it is, get name: Option<String>,
r#type: FunctionType, // the name from C0. r#type: FunctionType,
instructions: Vec<(Instruction, Span)>, instructions: Vec<(Instruction, Span)>,
constants: Vec<ConcreteValue>, constants: Vec<Value>,
locals: Vec<Local>, locals: Vec<Local>,
} }
@ -41,7 +41,7 @@ impl Chunk {
pub fn with_data( pub fn with_data(
name: Option<String>, name: Option<String>,
instructions: Vec<(Instruction, Span)>, instructions: Vec<(Instruction, Span)>,
constants: Vec<ConcreteValue>, constants: Vec<Value>,
locals: Vec<Local>, locals: Vec<Local>,
) -> Self { ) -> Self {
Self { Self {
@ -77,15 +77,15 @@ impl Chunk {
self.instructions.is_empty() self.instructions.is_empty()
} }
pub fn constants(&self) -> &Vec<ConcreteValue> { pub fn constants(&self) -> &Vec<Value> {
&self.constants &self.constants
} }
pub fn constants_mut(&mut self) -> &mut Vec<ConcreteValue> { pub fn constants_mut(&mut self) -> &mut Vec<Value> {
&mut self.constants &mut self.constants
} }
pub fn get_constant(&self, index: u8) -> Result<&ConcreteValue, ChunkError> { pub fn get_constant(&self, index: u8) -> Result<&Value, ChunkError> {
self.constants self.constants
.get(index as usize) .get(index as usize)
.ok_or(ChunkError::ConstantIndexOutOfBounds { .ok_or(ChunkError::ConstantIndexOutOfBounds {
@ -93,7 +93,7 @@ impl Chunk {
}) })
} }
pub fn push_or_get_constant(&mut self, value: ConcreteValue) -> u8 { pub fn push_or_get_constant(&mut self, value: Value) -> u8 {
if let Some(index) = self if let Some(index) = self
.constants .constants
.iter() .iter()

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@ -13,7 +13,7 @@ use std::{
use colored::Colorize; use colored::Colorize;
use crate::{ use crate::{
value::ConcreteValue, AnnotatedError, Chunk, ChunkError, DustError, FunctionType, Instruction, value::Value, AnnotatedError, Chunk, ChunkError, DustError, FunctionType, Instruction,
LexError, Lexer, Local, NativeFunction, Operation, Optimizer, Scope, Span, Token, TokenKind, LexError, Lexer, Local, NativeFunction, Operation, Optimizer, Scope, Span, Token, TokenKind,
TokenOwned, Type, TypeConflict, TokenOwned, Type, TypeConflict,
}; };
@ -44,7 +44,7 @@ pub fn compile(source: &str) -> Result<Chunk, DustError> {
/// Low-level tool for compiling the input a token at a time while assembling a chunk. /// Low-level tool for compiling the input a token at a time while assembling a chunk.
/// ///
/// See the [`compile`] function an example of how to create and use a Compiler. /// See the [`compile`] function an example of how to create and use a Compiler.
#[derive(Debug, Eq, PartialEq, PartialOrd, Ord)] #[derive(Debug, Eq, PartialEq, PartialOrd)]
pub struct Compiler<'src> { pub struct Compiler<'src> {
chunk: Chunk, chunk: Chunk,
lexer: Lexer<'src>, lexer: Lexer<'src>,
@ -158,7 +158,7 @@ impl<'src> Compiler<'src> {
.chunk .chunk
.constants() .constants()
.get(local.identifier_index as usize)?; .get(local.identifier_index as usize)?;
let identifier = if let ConcreteValue::String(identifier) = constant { let identifier = if let Value::String(identifier) = constant {
identifier identifier
} else { } else {
return None; return None;
@ -186,7 +186,7 @@ impl<'src> Compiler<'src> {
) -> (u8, u8) { ) -> (u8, u8) {
log::debug!("Declare local {identifier}"); log::debug!("Declare local {identifier}");
let identifier = ConcreteValue::string(identifier); let identifier = Value::string(identifier);
let identifier_index = self.chunk.push_or_get_constant(identifier); let identifier_index = self.chunk.push_or_get_constant(identifier);
self.chunk self.chunk
@ -368,11 +368,7 @@ impl<'src> Compiler<'src> {
self.chunk.instructions_mut().push((instruction, position)); self.chunk.instructions_mut().push((instruction, position));
} }
fn emit_constant( fn emit_constant(&mut self, constant: Value, position: Span) -> Result<(), CompileError> {
&mut self,
constant: ConcreteValue,
position: Span,
) -> Result<(), CompileError> {
let constant_index = self.chunk.push_or_get_constant(constant); let constant_index = self.chunk.push_or_get_constant(constant);
let register = self.next_register(); let register = self.next_register();
@ -418,7 +414,7 @@ impl<'src> Compiler<'src> {
let byte = u8::from_str_radix(&text[2..], 16) let byte = u8::from_str_radix(&text[2..], 16)
.map_err(|error| CompileError::ParseIntError { error, position })?; .map_err(|error| CompileError::ParseIntError { error, position })?;
let value = ConcreteValue::byte(byte); let value = Value::byte(byte);
self.emit_constant(value, position)?; self.emit_constant(value, position)?;
@ -440,7 +436,7 @@ impl<'src> Compiler<'src> {
if let Token::Character(character) = self.current_token { if let Token::Character(character) = self.current_token {
self.advance()?; self.advance()?;
let value = ConcreteValue::character(character); let value = Value::character(character);
self.emit_constant(value, position)?; self.emit_constant(value, position)?;
@ -468,7 +464,7 @@ impl<'src> Compiler<'src> {
error, error,
position: self.previous_position, position: self.previous_position,
})?; })?;
let value = ConcreteValue::float(float); let value = Value::float(float);
self.emit_constant(value, position)?; self.emit_constant(value, position)?;
@ -496,7 +492,7 @@ impl<'src> Compiler<'src> {
error, error,
position: self.previous_position, position: self.previous_position,
})?; })?;
let value = ConcreteValue::integer(integer); let value = Value::integer(integer);
self.emit_constant(value, position)?; self.emit_constant(value, position)?;
@ -518,7 +514,7 @@ impl<'src> Compiler<'src> {
if let Token::String(text) = self.current_token { if let Token::String(text) = self.current_token {
self.advance()?; self.advance()?;
let value = ConcreteValue::string(text); let value = Value::string(text);
self.emit_constant(value, position)?; self.emit_constant(value, position)?;
@ -1476,7 +1472,7 @@ impl<'src> Compiler<'src> {
value_parameters, value_parameters,
return_type, return_type,
}; };
let function = ConcreteValue::function(function_compiler.finish()); let function = Value::function(function_compiler.finish());
let constant_index = self.chunk.push_or_get_constant(function); let constant_index = self.chunk.push_or_get_constant(function);
let function_end = self.current_position.1; let function_end = self.current_position.1;
let register = self.next_register(); let register = self.next_register();

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@ -45,7 +45,7 @@ use std::env::current_exe;
use colored::Colorize; use colored::Colorize;
use crate::{value::ConcreteValue, Chunk, Local}; use crate::{value::Value, Chunk, Local};
const INSTRUCTION_HEADER: [&str; 4] = [ const INSTRUCTION_HEADER: [&str; 4] = [
"Instructions", "Instructions",
@ -313,9 +313,8 @@ impl<'a> Disassembler<'a> {
} }
for (index, value) in self.chunk.constants().iter().enumerate() { for (index, value) in self.chunk.constants().iter().enumerate() {
if let ConcreteValue::Function(function) = value { if let Value::Function(chunk) = value {
let function_disassembly = function let function_disassembly = chunk
.chunk()
.disassembler() .disassembler()
.styled(self.styled) .styled(self.styled)
.indent(self.indent + 1) .indent(self.indent + 1)

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@ -1,63 +0,0 @@
use std::fmt::{self, Display, Formatter};
use serde::{Deserialize, Serialize};
use crate::{Chunk, Type};
#[derive(Clone, Debug, Eq, PartialEq, PartialOrd, Ord, Serialize, Deserialize)]
pub struct Function {
chunk: Chunk,
}
impl Function {
pub fn new(chunk: Chunk) -> Self {
Self { chunk }
}
pub fn chunk(&self) -> &Chunk {
&self.chunk
}
pub fn r#type(&self) -> Type {
Type::Function(self.chunk.r#type().clone())
}
pub fn as_borrowed(&self) -> FunctionBorrowed {
FunctionBorrowed::new(&self.chunk)
}
}
impl Display for Function {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "{}", self.chunk.r#type())
}
}
#[derive(Clone, Copy, Debug, Eq, PartialEq, PartialOrd, Ord)]
pub struct FunctionBorrowed<'a> {
chunk: &'a Chunk,
}
impl<'a> FunctionBorrowed<'a> {
pub fn new(chunk: &'a Chunk) -> Self {
Self { chunk }
}
pub fn chunk(&self) -> &Chunk {
self.chunk
}
pub fn r#type(&self) -> Type {
Type::Function(self.chunk.r#type().clone())
}
pub fn to_owned(&self) -> Function {
Function::new(self.chunk.clone())
}
}
impl<'a> Display for FunctionBorrowed<'a> {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
write!(f, "{}", self.chunk.r#type())
}
}

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@ -5,7 +5,6 @@ pub mod compiler;
pub mod disassembler; pub mod disassembler;
pub mod dust_error; pub mod dust_error;
pub mod formatter; pub mod formatter;
pub mod function;
pub mod instruction; pub mod instruction;
pub mod lexer; pub mod lexer;
pub mod native_function; pub mod native_function;
@ -22,7 +21,6 @@ pub use crate::compiler::{compile, CompileError, Compiler};
pub use crate::disassembler::Disassembler; pub use crate::disassembler::Disassembler;
pub use crate::dust_error::{AnnotatedError, DustError}; pub use crate::dust_error::{AnnotatedError, DustError};
pub use crate::formatter::{format, Formatter}; pub use crate::formatter::{format, Formatter};
pub use crate::function::{Function, FunctionBorrowed};
pub use crate::instruction::Instruction; pub use crate::instruction::Instruction;
pub use crate::lexer::{lex, LexError, Lexer}; pub use crate::lexer::{lex, LexError, Lexer};
pub use crate::native_function::{NativeFunction, NativeFunctionError}; pub use crate::native_function::{NativeFunction, NativeFunctionError};
@ -31,7 +29,7 @@ pub use crate::optimizer::Optimizer;
pub use crate::r#type::{EnumType, FunctionType, StructType, Type, TypeConflict}; pub use crate::r#type::{EnumType, FunctionType, StructType, Type, TypeConflict};
pub use crate::scope::Scope; pub use crate::scope::Scope;
pub use crate::token::{output_token_list, Token, TokenKind, TokenOwned}; pub use crate::token::{output_token_list, Token, TokenKind, TokenOwned};
pub use crate::value::{ConcreteValue, Value, ValueError}; pub use crate::value::{Value, ValueError};
pub use crate::vm::{run, Vm, VmError}; pub use crate::vm::{run, Vm, VmError};
use std::fmt::Display; use std::fmt::Display;

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@ -1,12 +1,8 @@
use std::io::{self, stdout, Write}; use std::io::{self, stdout, Write};
use crate::{ConcreteValue, Instruction, NativeFunctionError, Span, Value, Vm, VmError}; use crate::{Instruction, NativeFunctionError, Span, Value, Vm, VmError};
pub fn panic( pub fn panic(vm: &Vm, instruction: Instruction) -> Result<Option<Value>, VmError> {
vm: &Vm,
instruction: Instruction,
position: Span,
) -> Result<Option<ConcreteValue>, VmError> {
let argument_count = instruction.c(); let argument_count = instruction.c();
let message = if argument_count == 0 { let message = if argument_count == 0 {
None None
@ -18,7 +14,7 @@ pub fn panic(
message.push(' '); message.push(' ');
} }
let argument = vm.open_register(argument_index, position)?; let argument = vm.open_register(argument_index)?;
message.push_str(&argument.to_string()); message.push_str(&argument.to_string());
} }
@ -28,15 +24,11 @@ pub fn panic(
Err(VmError::NativeFunction(NativeFunctionError::Panic { Err(VmError::NativeFunction(NativeFunctionError::Panic {
message, message,
position, position: vm.current_position(),
})) }))
} }
pub fn to_string( pub fn to_string(vm: &Vm, instruction: Instruction) -> Result<Option<Value>, VmError> {
vm: &Vm,
instruction: Instruction,
position: Span,
) -> Result<Option<ConcreteValue>, VmError> {
let argument_count = instruction.c(); let argument_count = instruction.c();
if argument_count != 1 { if argument_count != 1 {
@ -44,7 +36,7 @@ pub fn to_string(
NativeFunctionError::ExpectedArgumentCount { NativeFunctionError::ExpectedArgumentCount {
expected: 1, expected: 1,
found: argument_count as usize, found: argument_count as usize,
position, position: vm.current_position(),
}, },
)); ));
} }
@ -52,19 +44,15 @@ pub fn to_string(
let mut string = String::new(); let mut string = String::new();
for argument_index in 0..argument_count { for argument_index in 0..argument_count {
let argument = vm.open_register(argument_index, position)?; let argument = vm.open_register(argument_index)?;
string.push_str(&argument.to_string()); string.push_str(&argument.to_string());
} }
Ok(Some(ConcreteValue::String(string))) Ok(Some(Value::String(string)))
} }
pub fn read_line( pub fn read_line(vm: &Vm, instruction: Instruction) -> Result<Option<Value>, VmError> {
_: &Vm,
instruction: Instruction,
position: Span,
) -> Result<Option<ConcreteValue>, VmError> {
let argument_count = instruction.c(); let argument_count = instruction.c();
if argument_count != 0 { if argument_count != 0 {
@ -72,7 +60,7 @@ pub fn read_line(
NativeFunctionError::ExpectedArgumentCount { NativeFunctionError::ExpectedArgumentCount {
expected: 0, expected: 0,
found: argument_count as usize, found: argument_count as usize,
position, position: vm.current_position(),
}, },
)); ));
} }
@ -80,28 +68,24 @@ pub fn read_line(
let mut buffer = String::new(); let mut buffer = String::new();
match io::stdin().read_line(&mut buffer) { match io::stdin().read_line(&mut buffer) {
Ok(_) => Ok(Some(ConcreteValue::String( Ok(_) => Ok(Some(Value::String(
buffer.trim_end_matches('\n').to_string(), buffer.trim_end_matches('\n').to_string(),
))), ))),
Err(error) => Err(VmError::NativeFunction(NativeFunctionError::Io { Err(error) => Err(VmError::NativeFunction(NativeFunctionError::Io {
error: error.kind(), error: error.kind(),
position, position: vm.current_position(),
})), })),
} }
} }
pub fn write( pub fn write(vm: &Vm, instruction: Instruction) -> Result<Option<Value>, VmError> {
vm: &Vm,
instruction: Instruction,
position: Span,
) -> Result<Option<ConcreteValue>, VmError> {
let to_register = instruction.a(); let to_register = instruction.a();
let argument_count = instruction.c(); let argument_count = instruction.c();
let mut stdout = stdout(); let mut stdout = stdout();
let map_err = |io_error: io::Error| { let map_err = |io_error: io::Error| {
VmError::NativeFunction(NativeFunctionError::Io { VmError::NativeFunction(NativeFunctionError::Io {
error: io_error.kind(), error: io_error.kind(),
position, position: vm.current_position(),
}) })
}; };
@ -112,7 +96,7 @@ pub fn write(
stdout.write(b" ").map_err(map_err)?; stdout.write(b" ").map_err(map_err)?;
} }
let argument_string = vm.open_register(argument_index, position)?.to_string(); let argument_string = vm.open_register(argument_index)?.to_string();
stdout stdout
.write_all(argument_string.as_bytes()) .write_all(argument_string.as_bytes())
@ -122,18 +106,14 @@ pub fn write(
Ok(None) Ok(None)
} }
pub fn write_line( pub fn write_line(vm: &Vm, instruction: Instruction) -> Result<Option<Value>, VmError> {
vm: &Vm,
instruction: Instruction,
position: Span,
) -> Result<Option<ConcreteValue>, VmError> {
let to_register = instruction.a(); let to_register = instruction.a();
let argument_count = instruction.c(); let argument_count = instruction.c();
let mut stdout = stdout(); let mut stdout = stdout();
let map_err = |io_error: io::Error| { let map_err = |io_error: io::Error| {
VmError::NativeFunction(NativeFunctionError::Io { VmError::NativeFunction(NativeFunctionError::Io {
error: io_error.kind(), error: io_error.kind(),
position, position: vm.current_position(),
}) })
}; };
@ -144,7 +124,7 @@ pub fn write_line(
stdout.write(b" ").map_err(map_err)?; stdout.write(b" ").map_err(map_err)?;
} }
let argument_string = vm.open_register(argument_index, position)?.to_string(); let argument_string = vm.open_register(argument_index)?.to_string();
stdout stdout
.write_all(argument_string.as_bytes()) .write_all(argument_string.as_bytes())

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@ -12,7 +12,7 @@ use std::{
use serde::{Deserialize, Serialize}; use serde::{Deserialize, Serialize};
use crate::{AnnotatedError, ConcreteValue, FunctionType, Instruction, Span, Type, Vm, VmError}; use crate::{AnnotatedError, FunctionType, Instruction, Span, Type, Value, Vm, VmError};
macro_rules! define_native_function { macro_rules! define_native_function {
($(($name:ident, $byte:literal, $str:expr, $type:expr, $function:expr)),*) => { ($(($name:ident, $byte:literal, $str:expr, $type:expr, $function:expr)),*) => {
@ -31,11 +31,10 @@ macro_rules! define_native_function {
&self, &self,
vm: &mut Vm, vm: &mut Vm,
instruction: Instruction, instruction: Instruction,
span: Span ) -> Result<Option<Value>, VmError> {
) -> Result<Option<ConcreteValue>, VmError> {
match self { match self {
$( $(
NativeFunction::$name => $function(vm, instruction, span), NativeFunction::$name => $function(vm, instruction),
)* )*
} }
} }

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@ -1,983 +0,0 @@
//! Runtime values used by the VM.
use std::{
cmp::Ordering,
fmt::{self, Debug, Display, Formatter},
ops::{Range, RangeInclusive},
};
use serde::{Deserialize, Serialize};
use crate::{function::Function, Chunk, FunctionBorrowed, Type};
#[derive(Clone, Copy, Debug, PartialEq)]
pub enum ReferenceValue<'a> {
Concrete(&'a ConcreteValue),
Function(FunctionBorrowed<'a>),
List(&'a Vec<&'a ConcreteValue>),
}
impl<'a> ReferenceValue<'a> {
pub fn to_value(self) -> Value<'a> {
Value::Reference(self)
}
pub fn r#type(&self) -> Type {
match self {
ReferenceValue::Concrete(concrete) => concrete.r#type(),
ReferenceValue::Function(function) => function.r#type(),
ReferenceValue::List(list) => {
let item_type = list
.first()
.map(|value| value.r#type())
.unwrap_or(Type::Any);
Type::List {
item_type: Box::new(item_type),
length: list.len(),
}
}
}
}
pub fn into_concrete(self) -> ConcreteValue {
match self {
ReferenceValue::Concrete(concrete) => concrete.clone(),
ReferenceValue::Function(function) => {
ConcreteValue::Function(Function::new(function.chunk().clone()))
}
ReferenceValue::List(list) => {
let mut items = Vec::new();
for value in list {
items.push((*value).clone());
}
ConcreteValue::List(items)
}
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub enum Value<'a> {
Concrete(ConcreteValue),
Reference(ReferenceValue<'a>),
}
impl<'a> Value<'a> {
pub fn r#type(&self) -> Type {
match self {
Value::Concrete(concrete) => concrete.r#type(),
Value::Reference(reference) => reference.r#type(),
}
}
pub fn into_concrete(self) -> ConcreteValue {
match self {
Value::Concrete(concrete) => concrete,
Value::Reference(reference) => reference.into_concrete(),
}
}
pub fn as_boolean(&self) -> Option<bool> {
match self {
Value::Concrete(ConcreteValue::Boolean(boolean)) => Some(*boolean),
Value::Reference(ReferenceValue::Concrete(ConcreteValue::Boolean(boolean))) => {
Some(*boolean)
}
_ => None,
}
}
pub fn as_function(&self) -> Option<FunctionBorrowed> {
match self {
Value::Concrete(ConcreteValue::Function(function)) => Some(function.as_borrowed()),
Value::Reference(ReferenceValue::Concrete(ConcreteValue::Function(function))) => {
Some(function.as_borrowed())
}
_ => None,
}
}
pub fn add(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => left.add(right),
(Value::Reference(ReferenceValue::Concrete(left)), Value::Concrete(right)) => {
left.add(right)
}
(Value::Concrete(left), Value::Reference(ReferenceValue::Concrete(right))) => {
left.add(right)
}
(
Value::Reference(ReferenceValue::Concrete(left)),
Value::Reference(ReferenceValue::Concrete(right)),
) => left.add(right),
_ => Err(ValueError::CannotAdd(
self.clone().into_concrete(),
other.clone().into_concrete(),
)),
}
}
pub fn subtract(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotSubtract(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.subtract(right)
}
pub fn multiply(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotMultiply(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.multiply(right)
}
pub fn divide(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotDivide(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.divide(right)
}
pub fn modulo(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotModulo(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.modulo(right)
}
pub fn negate(&self) -> Result<ConcreteValue, ValueError> {
match self {
Value::Concrete(concrete) => concrete.negate(),
Value::Reference(reference) => reference.negate(),
_ => Err(ValueError::CannotNegate(self.clone().into_concrete())),
}
}
pub fn not(&self) -> Result<ConcreteValue, ValueError> {
match self {
Value::Concrete(concrete) => concrete.not(),
Value::Reference(reference) => reference.not(),
_ => Err(ValueError::CannotNot(self.clone().into_concrete())),
}
}
pub fn equal(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotCompare(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.equal(right)
}
pub fn less_than(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotCompare(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.less_than(right)
}
pub fn less_than_or_equal(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
let (left, right) = match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => (left, right),
(Value::Reference(left), Value::Reference(right)) => (*left, *right),
_ => {
return Err(ValueError::CannotCompare(
self.clone().into_concrete(),
other.clone().into_concrete(),
));
}
};
left.less_than_or_equal(right)
}
}
impl<'a> Display for Value<'a> {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
Value::Concrete(concrete) => write!(f, "{}", concrete),
Value::List(list) => {
write!(f, "[")?;
for (index, value) in list.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{}", value)?;
}
write!(f, "]")
}
Value::Reference(reference) => write!(f, "{}", reference),
Value::FunctionBorrowed(function_reference) => {
write!(f, "{}", function_reference.chunk().r#type())
}
}
}
}
impl<'a> Eq for Value<'a> {}
impl<'a> PartialOrd for Value<'a> {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl<'a> Ord for Value<'a> {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(Value::Concrete(left), Value::Concrete(right)) => left.cmp(right),
(Value::Concrete(_), _) => Ordering::Greater,
(Value::List(left), Value::List(right)) => left.cmp(right),
(Value::List(_), _) => Ordering::Greater,
(Value::Reference(left), Value::Reference(right)) => left.cmp(right),
(Value::Reference(_), _) => Ordering::Greater,
(Value::FunctionBorrowed(left), Value::FunctionBorrowed(right)) => left.cmp(right),
(Value::FunctionBorrowed(_), _) => Ordering::Greater,
}
}
}
#[derive(Debug, PartialEq, Serialize, Deserialize)]
pub enum ConcreteValue {
Boolean(bool),
Byte(u8),
Character(char),
Float(f64),
Function(Function),
Integer(i64),
List(Vec<ConcreteValue>),
Range(RangeValue),
String(String),
}
impl ConcreteValue {
pub fn boolean(value: bool) -> Self {
ConcreteValue::Boolean(value)
}
pub fn byte(value: u8) -> Self {
ConcreteValue::Byte(value)
}
pub fn character(value: char) -> Self {
ConcreteValue::Character(value)
}
pub fn float(value: f64) -> Self {
ConcreteValue::Float(value)
}
pub fn function(chunk: Chunk) -> Self {
ConcreteValue::Function(Function::new(chunk))
}
pub fn integer<T: Into<i64>>(into_i64: T) -> Self {
ConcreteValue::Integer(into_i64.into())
}
pub fn list<T: Into<Vec<ConcreteValue>>>(into_list: T) -> Self {
ConcreteValue::List(into_list.into())
}
pub fn range(range: RangeValue) -> Self {
ConcreteValue::Range(range)
}
pub fn string<T: ToString>(to_string: T) -> Self {
ConcreteValue::String(to_string.to_string())
}
pub fn as_string(&self) -> Option<&String> {
if let ConcreteValue::String(string) = self {
Some(string)
} else {
None
}
}
pub fn to_owned_value<'a>(self) -> Value<'a> {
Value::Concrete(self)
}
pub fn as_reference_value(&self) -> Value {
Value::Reference(self)
}
pub fn r#type(&self) -> Type {
match self {
ConcreteValue::Boolean(_) => Type::Boolean,
ConcreteValue::Byte(_) => Type::Byte,
ConcreteValue::Character(_) => Type::Character,
ConcreteValue::Float(_) => Type::Float,
ConcreteValue::Function(function) => function.r#type(),
ConcreteValue::Integer(_) => Type::Integer,
ConcreteValue::List(list) => {
let item_type = list.first().map_or(Type::Any, |item| item.r#type());
Type::List {
item_type: Box::new(item_type),
length: list.len(),
}
}
ConcreteValue::Range(range) => range.r#type(),
ConcreteValue::String(string) => Type::String {
length: Some(string.len()),
},
}
}
pub fn add(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let sum = match (self, other) {
(Byte(left), Byte(right)) => ConcreteValue::byte(left.saturating_add(*right)),
(Float(left), Float(right)) => ConcreteValue::float(*left + *right),
(Integer(left), Integer(right)) => ConcreteValue::integer(left.saturating_add(*right)),
(String(left), String(right)) => ConcreteValue::string(format!("{}{}", left, right)),
_ => return Err(ValueError::CannotAdd(self.clone(), other.clone())),
};
Ok(sum)
}
pub fn subtract(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let difference = match (self, other) {
(Byte(left), Byte(right)) => ConcreteValue::byte(left.saturating_sub(*right)),
(Float(left), Float(right)) => ConcreteValue::float(left - right),
(Integer(left), Integer(right)) => ConcreteValue::integer(left.saturating_sub(*right)),
_ => return Err(ValueError::CannotSubtract(self.clone(), other.clone())),
};
Ok(difference)
}
pub fn multiply(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let product = match (self, other) {
(Byte(left), Byte(right)) => ConcreteValue::byte(left.saturating_mul(*right)),
(Float(left), Float(right)) => ConcreteValue::float(left * right),
(Integer(left), Integer(right)) => ConcreteValue::integer(left.saturating_mul(*right)),
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(product)
}
pub fn divide(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let quotient = match (self, other) {
(Byte(left), Byte(right)) => ConcreteValue::byte(left.saturating_div(*right)),
(Float(left), Float(right)) => ConcreteValue::float(left / right),
(Integer(left), Integer(right)) => ConcreteValue::integer(left.saturating_div(*right)),
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(quotient)
}
pub fn modulo(&self, other: &Self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let product = match (self, other) {
(Byte(left), Byte(right)) => ConcreteValue::byte(left.wrapping_rem(*right)),
(Float(left), Float(right)) => ConcreteValue::float(left % right),
(Integer(left), Integer(right)) => {
ConcreteValue::integer(left.wrapping_rem_euclid(*right))
}
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(product)
}
pub fn negate(&self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let negated = match self {
Boolean(value) => ConcreteValue::boolean(!value),
Byte(value) => ConcreteValue::byte(value.wrapping_neg()),
Float(value) => ConcreteValue::float(-value),
Integer(value) => ConcreteValue::integer(value.wrapping_neg()),
_ => return Err(ValueError::CannotNegate(self.clone())),
};
Ok(negated)
}
pub fn not(&self) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let not = match self {
Boolean(value) => ConcreteValue::boolean(!value),
_ => return Err(ValueError::CannotNot(self.clone())),
};
Ok(not)
}
pub fn equal(&self, other: &ConcreteValue) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let equal = match (self, other) {
(Boolean(left), Boolean(right)) => ConcreteValue::boolean(left == right),
(Byte(left), Byte(right)) => ConcreteValue::boolean(left == right),
(Character(left), Character(right)) => ConcreteValue::boolean(left == right),
(Float(left), Float(right)) => ConcreteValue::boolean(left == right),
(Function(left), Function(right)) => ConcreteValue::boolean(left == right),
(Integer(left), Integer(right)) => ConcreteValue::boolean(left == right),
(List(left), List(right)) => ConcreteValue::boolean(left == right),
(Range(left), Range(right)) => ConcreteValue::boolean(left == right),
(String(left), String(right)) => ConcreteValue::boolean(left == right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(equal)
}
pub fn less_than(&self, other: &ConcreteValue) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let less_than = match (self, other) {
(Boolean(left), Boolean(right)) => ConcreteValue::boolean(left < right),
(Byte(left), Byte(right)) => ConcreteValue::boolean(left < right),
(Character(left), Character(right)) => ConcreteValue::boolean(left < right),
(Float(left), Float(right)) => ConcreteValue::boolean(left < right),
(Function(left), Function(right)) => ConcreteValue::boolean(left < right),
(Integer(left), Integer(right)) => ConcreteValue::boolean(left < right),
(List(left), List(right)) => ConcreteValue::boolean(left < right),
(Range(left), Range(right)) => ConcreteValue::boolean(left < right),
(String(left), String(right)) => ConcreteValue::boolean(left < right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(less_than)
}
pub fn less_than_or_equal(&self, other: &ConcreteValue) -> Result<ConcreteValue, ValueError> {
use ConcreteValue::*;
let less_than_or_equal = match (self, other) {
(Boolean(left), Boolean(right)) => ConcreteValue::boolean(left <= right),
(Byte(left), Byte(right)) => ConcreteValue::boolean(left <= right),
(Character(left), Character(right)) => ConcreteValue::boolean(left <= right),
(Float(left), Float(right)) => ConcreteValue::boolean(left <= right),
(Function(left), Function(right)) => ConcreteValue::boolean(left <= right),
(Integer(left), Integer(right)) => ConcreteValue::boolean(left <= right),
(List(left), List(right)) => ConcreteValue::boolean(left <= right),
(Range(left), Range(right)) => ConcreteValue::boolean(left <= right),
(String(left), String(right)) => ConcreteValue::boolean(left <= right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(less_than_or_equal)
}
}
impl Clone for ConcreteValue {
fn clone(&self) -> Self {
log::trace!("Cloning concrete value {}", self);
match self {
ConcreteValue::Boolean(boolean) => ConcreteValue::Boolean(*boolean),
ConcreteValue::Byte(byte) => ConcreteValue::Byte(*byte),
ConcreteValue::Character(character) => ConcreteValue::Character(*character),
ConcreteValue::Float(float) => ConcreteValue::Float(*float),
ConcreteValue::Function(function) => ConcreteValue::Function(function.clone()),
ConcreteValue::Integer(integer) => ConcreteValue::Integer(*integer),
ConcreteValue::List(list) => ConcreteValue::List(list.clone()),
ConcreteValue::Range(range) => ConcreteValue::Range(range.clone()),
ConcreteValue::String(string) => ConcreteValue::String(string.clone()),
}
}
}
impl Eq for ConcreteValue {}
impl PartialOrd for ConcreteValue {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for ConcreteValue {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(ConcreteValue::Boolean(left), ConcreteValue::Boolean(right)) => left.cmp(right),
(ConcreteValue::Boolean(_), _) => Ordering::Greater,
(ConcreteValue::Byte(left), ConcreteValue::Byte(right)) => left.cmp(right),
(ConcreteValue::Byte(_), _) => Ordering::Greater,
(ConcreteValue::Character(left), ConcreteValue::Character(right)) => left.cmp(right),
(ConcreteValue::Character(_), _) => Ordering::Greater,
(ConcreteValue::Float(left), ConcreteValue::Float(right)) => {
left.to_bits().cmp(&right.to_bits())
}
(ConcreteValue::Float(_), _) => Ordering::Greater,
(ConcreteValue::Function(left), ConcreteValue::Function(right)) => left.cmp(right),
(ConcreteValue::Function(_), _) => Ordering::Greater,
(ConcreteValue::Integer(left), ConcreteValue::Integer(right)) => left.cmp(right),
(ConcreteValue::Integer(_), _) => Ordering::Greater,
(ConcreteValue::List(left), ConcreteValue::List(right)) => left.cmp(right),
(ConcreteValue::List(_), _) => Ordering::Greater,
(ConcreteValue::Range(left), ConcreteValue::Range(right)) => left.cmp(right),
(ConcreteValue::Range(_), _) => Ordering::Greater,
(ConcreteValue::String(left), ConcreteValue::String(right)) => left.cmp(right),
(ConcreteValue::String(_), _) => Ordering::Greater,
}
}
}
impl Display for ConcreteValue {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
ConcreteValue::Boolean(boolean) => write!(f, "{boolean}"),
ConcreteValue::Byte(byte) => write!(f, "0x{byte:02x}"),
ConcreteValue::Character(character) => write!(f, "{character}"),
ConcreteValue::Float(float) => {
write!(f, "{float}")?;
if float.fract() == 0.0 {
write!(f, ".0")?;
}
Ok(())
}
ConcreteValue::Function(function) => write!(f, "{function}"),
ConcreteValue::Integer(integer) => write!(f, "{integer}"),
ConcreteValue::List(list) => {
write!(f, "[")?;
for (index, element) in list.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{element}")?;
}
write!(f, "]")
}
ConcreteValue::Range(range_value) => {
write!(f, "{range_value}")
}
ConcreteValue::String(string) => write!(f, "{string}"),
}
}
}
#[derive(Clone, Copy, Debug, PartialEq, Serialize, Deserialize)]
pub enum RangeValue {
ByteRange { start: u8, end: u8 },
ByteRangeInclusive { start: u8, end: u8 },
CharacterRange { start: char, end: char },
CharacterRangeInclusive { start: char, end: char },
FloatRange { start: f64, end: f64 },
FloatRangeInclusive { start: f64, end: f64 },
IntegerRange { start: i64, end: i64 },
IntegerRangeInclusive { start: i64, end: i64 },
}
impl RangeValue {
pub fn r#type(&self) -> Type {
let inner_type = match self {
RangeValue::ByteRange { .. } | RangeValue::ByteRangeInclusive { .. } => Type::Byte,
RangeValue::CharacterRange { .. } | RangeValue::CharacterRangeInclusive { .. } => {
Type::Character
}
RangeValue::FloatRange { .. } | RangeValue::FloatRangeInclusive { .. } => Type::Float,
RangeValue::IntegerRange { .. } | RangeValue::IntegerRangeInclusive { .. } => {
Type::Integer
}
};
Type::Range {
r#type: Box::new(inner_type),
}
}
}
impl From<Range<u8>> for RangeValue {
fn from(range: Range<u8>) -> Self {
RangeValue::ByteRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<u8>> for RangeValue {
fn from(range: RangeInclusive<u8>) -> Self {
RangeValue::ByteRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<char>> for RangeValue {
fn from(range: Range<char>) -> Self {
RangeValue::CharacterRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<char>> for RangeValue {
fn from(range: RangeInclusive<char>) -> Self {
RangeValue::CharacterRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<f64>> for RangeValue {
fn from(range: Range<f64>) -> Self {
RangeValue::FloatRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<f64>> for RangeValue {
fn from(range: RangeInclusive<f64>) -> Self {
RangeValue::FloatRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<i32>> for RangeValue {
fn from(range: Range<i32>) -> Self {
RangeValue::IntegerRange {
start: range.start as i64,
end: range.end as i64,
}
}
}
impl From<RangeInclusive<i32>> for RangeValue {
fn from(range: RangeInclusive<i32>) -> Self {
RangeValue::IntegerRangeInclusive {
start: *range.start() as i64,
end: *range.end() as i64,
}
}
}
impl From<Range<i64>> for RangeValue {
fn from(range: Range<i64>) -> Self {
RangeValue::IntegerRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<i64>> for RangeValue {
fn from(range: RangeInclusive<i64>) -> Self {
RangeValue::IntegerRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl Display for RangeValue {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
RangeValue::ByteRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::ByteRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::CharacterRange { start, end } => {
write!(f, "{}..{}", start, end)
}
RangeValue::CharacterRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::FloatRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::FloatRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::IntegerRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::IntegerRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
}
}
}
impl Eq for RangeValue {}
impl PartialOrd for RangeValue {
fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
Some(self.cmp(other))
}
}
impl Ord for RangeValue {
fn cmp(&self, other: &Self) -> Ordering {
match (self, other) {
(
RangeValue::ByteRange {
start: left_start,
end: left_end,
},
RangeValue::ByteRange {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(right_end)
}
}
(RangeValue::ByteRange { .. }, _) => Ordering::Greater,
(
RangeValue::ByteRangeInclusive {
start: left_start,
end: left_end,
},
RangeValue::ByteRangeInclusive {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(&right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(&right_end)
}
}
(RangeValue::ByteRangeInclusive { .. }, _) => Ordering::Greater,
(
RangeValue::CharacterRange {
start: left_start,
end: left_end,
},
RangeValue::CharacterRange {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(right_end)
}
}
(RangeValue::CharacterRange { .. }, _) => Ordering::Greater,
(
RangeValue::CharacterRangeInclusive {
start: left_start,
end: left_end,
},
RangeValue::CharacterRangeInclusive {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(right_end)
}
}
(RangeValue::CharacterRangeInclusive { .. }, _) => Ordering::Greater,
(
RangeValue::FloatRange {
start: left_start,
end: left_end,
},
RangeValue::FloatRange {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.partial_cmp(right_start).unwrap();
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.partial_cmp(right_end).unwrap()
}
}
(RangeValue::FloatRange { .. }, _) => Ordering::Greater,
(
RangeValue::FloatRangeInclusive {
start: left_start,
end: left_end,
},
RangeValue::FloatRangeInclusive {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.partial_cmp(right_start).unwrap();
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.partial_cmp(right_end).unwrap()
}
}
(RangeValue::FloatRangeInclusive { .. }, _) => Ordering::Greater,
(
RangeValue::IntegerRange {
start: left_start,
end: left_end,
},
RangeValue::IntegerRange {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(right_end)
}
}
(RangeValue::IntegerRange { .. }, _) => Ordering::Greater,
(
RangeValue::IntegerRangeInclusive {
start: left_start,
end: left_end,
},
RangeValue::IntegerRangeInclusive {
start: right_start,
end: right_end,
},
) => {
let start_cmp = left_start.cmp(right_start);
if start_cmp != Ordering::Equal {
start_cmp
} else {
left_end.cmp(right_end)
}
}
(RangeValue::IntegerRangeInclusive { .. }, _) => Ordering::Greater,
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub enum ValueError {
CannotAdd(ConcreteValue, ConcreteValue),
CannotAnd(ConcreteValue, ConcreteValue),
CannotCompare(ConcreteValue, ConcreteValue),
CannotDivide(ConcreteValue, ConcreteValue),
CannotModulo(ConcreteValue, ConcreteValue),
CannotMultiply(ConcreteValue, ConcreteValue),
CannotNegate(ConcreteValue),
CannotNot(ConcreteValue),
CannotSubtract(ConcreteValue, ConcreteValue),
CannotOr(ConcreteValue, ConcreteValue),
}
impl Display for ValueError {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
ValueError::CannotAdd(left, right) => {
write!(f, "Cannot add {left} and {right}")
}
ValueError::CannotAnd(left, right) => {
write!(f, "Cannot use logical AND operation on {left} and {right}")
}
ValueError::CannotCompare(left, right) => {
write!(f, "Cannot compare {left} and {right}")
}
ValueError::CannotDivide(left, right) => {
write!(f, "Cannot divide {left} by {right}")
}
ValueError::CannotModulo(left, right) => {
write!(f, "Cannot use modulo operation on {left} and {right}")
}
ValueError::CannotMultiply(left, right) => {
write!(f, "Cannot multiply {left} by {right}")
}
ValueError::CannotNegate(value) => {
write!(f, "Cannot negate {value}")
}
ValueError::CannotNot(value) => {
write!(f, "Cannot use logical NOT operation on {value}")
}
ValueError::CannotSubtract(left, right) => {
write!(f, "Cannot subtract {right} from {left}")
}
ValueError::CannotOr(left, right) => {
write!(f, "Cannot use logical OR operation on {left} and {right}")
}
}
}
}

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dust-lang/src/value/mod.rs Normal file
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//! Runtime values used by the VM.
mod range;
pub use range::RangeValue;
use std::fmt::{self, Debug, Display, Formatter};
use serde::{Deserialize, Serialize};
use crate::{Chunk, Type};
#[derive(Debug, PartialEq, PartialOrd, Serialize, Deserialize)]
pub enum Value {
Boolean(bool),
Byte(u8),
Character(char),
Float(f64),
Function(Chunk),
Integer(i64),
List(Vec<Value>),
Range(RangeValue),
String(String),
}
impl Value {
pub fn boolean(value: bool) -> Self {
Value::Boolean(value)
}
pub fn byte(value: u8) -> Self {
Value::Byte(value)
}
pub fn character(value: char) -> Self {
Value::Character(value)
}
pub fn float(value: f64) -> Self {
Value::Float(value)
}
pub fn function(chunk: Chunk) -> Self {
Value::Function(chunk)
}
pub fn integer<T: Into<i64>>(into_i64: T) -> Self {
Value::Integer(into_i64.into())
}
pub fn list<T: Into<Vec<Value>>>(into_list: T) -> Self {
Value::List(into_list.into())
}
pub fn range(range: RangeValue) -> Self {
Value::Range(range)
}
pub fn string<T: ToString>(to_string: T) -> Self {
Value::String(to_string.to_string())
}
pub fn as_string(&self) -> Option<&String> {
if let Value::String(string) = self {
Some(string)
} else {
None
}
}
pub fn r#type(&self) -> Type {
match self {
Value::Boolean(_) => Type::Boolean,
Value::Byte(_) => Type::Byte,
Value::Character(_) => Type::Character,
Value::Float(_) => Type::Float,
Value::Function(chunk) => Type::Function(chunk.r#type().clone()),
Value::Integer(_) => Type::Integer,
Value::List(list) => {
let item_type = list.first().map_or(Type::Any, |item| item.r#type());
Type::List {
item_type: Box::new(item_type),
length: list.len(),
}
}
Value::Range(range) => range.r#type(),
Value::String(string) => Type::String {
length: Some(string.len()),
},
}
}
pub fn add(&self, other: &Self) -> Result<Value, ValueError> {
use Value::*;
let sum = match (self, other) {
(Byte(left), Byte(right)) => Value::byte(left.saturating_add(*right)),
(Float(left), Float(right)) => Value::float(*left + *right),
(Integer(left), Integer(right)) => Value::integer(left.saturating_add(*right)),
(String(left), String(right)) => Value::string(format!("{}{}", left, right)),
_ => return Err(ValueError::CannotAdd(self.clone(), other.clone())),
};
Ok(sum)
}
pub fn subtract(&self, other: &Self) -> Result<Value, ValueError> {
use Value::*;
let difference = match (self, other) {
(Byte(left), Byte(right)) => Value::byte(left.saturating_sub(*right)),
(Float(left), Float(right)) => Value::float(left - right),
(Integer(left), Integer(right)) => Value::integer(left.saturating_sub(*right)),
_ => return Err(ValueError::CannotSubtract(self.clone(), other.clone())),
};
Ok(difference)
}
pub fn multiply(&self, other: &Self) -> Result<Value, ValueError> {
use Value::*;
let product = match (self, other) {
(Byte(left), Byte(right)) => Value::byte(left.saturating_mul(*right)),
(Float(left), Float(right)) => Value::float(left * right),
(Integer(left), Integer(right)) => Value::integer(left.saturating_mul(*right)),
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(product)
}
pub fn divide(&self, other: &Self) -> Result<Value, ValueError> {
use Value::*;
let quotient = match (self, other) {
(Byte(left), Byte(right)) => Value::byte(left.saturating_div(*right)),
(Float(left), Float(right)) => Value::float(left / right),
(Integer(left), Integer(right)) => Value::integer(left.saturating_div(*right)),
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(quotient)
}
pub fn modulo(&self, other: &Self) -> Result<Value, ValueError> {
use Value::*;
let product = match (self, other) {
(Byte(left), Byte(right)) => Value::byte(left.wrapping_rem(*right)),
(Float(left), Float(right)) => Value::float(left % right),
(Integer(left), Integer(right)) => Value::integer(left.wrapping_rem_euclid(*right)),
_ => return Err(ValueError::CannotMultiply(self.clone(), other.clone())),
};
Ok(product)
}
pub fn negate(&self) -> Result<Value, ValueError> {
use Value::*;
let negated = match self {
Boolean(value) => Value::boolean(!value),
Byte(value) => Value::byte(value.wrapping_neg()),
Float(value) => Value::float(-value),
Integer(value) => Value::integer(value.wrapping_neg()),
_ => return Err(ValueError::CannotNegate(self.clone())),
};
Ok(negated)
}
pub fn not(&self) -> Result<Value, ValueError> {
use Value::*;
let not = match self {
Boolean(value) => Value::boolean(!value),
_ => return Err(ValueError::CannotNot(self.clone())),
};
Ok(not)
}
pub fn equal(&self, other: &Value) -> Result<Value, ValueError> {
use Value::*;
let equal = match (self, other) {
(Boolean(left), Boolean(right)) => Value::boolean(left == right),
(Byte(left), Byte(right)) => Value::boolean(left == right),
(Character(left), Character(right)) => Value::boolean(left == right),
(Float(left), Float(right)) => Value::boolean(left == right),
(Function(left), Function(right)) => Value::boolean(left == right),
(Integer(left), Integer(right)) => Value::boolean(left == right),
(List(left), List(right)) => Value::boolean(left == right),
(Range(left), Range(right)) => Value::boolean(left == right),
(String(left), String(right)) => Value::boolean(left == right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(equal)
}
pub fn less_than(&self, other: &Value) -> Result<Value, ValueError> {
use Value::*;
let less_than = match (self, other) {
(Boolean(left), Boolean(right)) => Value::boolean(left < right),
(Byte(left), Byte(right)) => Value::boolean(left < right),
(Character(left), Character(right)) => Value::boolean(left < right),
(Float(left), Float(right)) => Value::boolean(left < right),
(Function(left), Function(right)) => Value::boolean(left < right),
(Integer(left), Integer(right)) => Value::boolean(left < right),
(List(left), List(right)) => Value::boolean(left < right),
(Range(left), Range(right)) => Value::boolean(left < right),
(String(left), String(right)) => Value::boolean(left < right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(less_than)
}
pub fn less_than_or_equal(&self, other: &Value) -> Result<Value, ValueError> {
use Value::*;
let less_than_or_equal = match (self, other) {
(Boolean(left), Boolean(right)) => Value::boolean(left <= right),
(Byte(left), Byte(right)) => Value::boolean(left <= right),
(Character(left), Character(right)) => Value::boolean(left <= right),
(Float(left), Float(right)) => Value::boolean(left <= right),
(Function(left), Function(right)) => Value::boolean(left <= right),
(Integer(left), Integer(right)) => Value::boolean(left <= right),
(List(left), List(right)) => Value::boolean(left <= right),
(Range(left), Range(right)) => Value::boolean(left <= right),
(String(left), String(right)) => Value::boolean(left <= right),
_ => return Err(ValueError::CannotCompare(self.clone(), other.clone())),
};
Ok(less_than_or_equal)
}
}
impl Clone for Value {
fn clone(&self) -> Self {
log::trace!("Cloning concrete value {}", self);
match self {
Value::Boolean(boolean) => Value::Boolean(*boolean),
Value::Byte(byte) => Value::Byte(*byte),
Value::Character(character) => Value::Character(*character),
Value::Float(float) => Value::Float(*float),
Value::Function(function) => Value::Function(function.clone()),
Value::Integer(integer) => Value::Integer(*integer),
Value::List(list) => Value::List(list.clone()),
Value::Range(range) => Value::Range(range.clone()),
Value::String(string) => Value::String(string.clone()),
}
}
}
impl Display for Value {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
Value::Boolean(boolean) => write!(f, "{boolean}"),
Value::Byte(byte) => write!(f, "0x{byte:02x}"),
Value::Character(character) => write!(f, "{character}"),
Value::Float(float) => {
write!(f, "{float}")?;
if float.fract() == 0.0 {
write!(f, ".0")?;
}
Ok(())
}
Value::Function(function) => write!(f, "{function}"),
Value::Integer(integer) => write!(f, "{integer}"),
Value::List(list) => {
write!(f, "[")?;
for (index, element) in list.iter().enumerate() {
if index > 0 {
write!(f, ", ")?;
}
write!(f, "{element}")?;
}
write!(f, "]")
}
Value::Range(range_value) => {
write!(f, "{range_value}")
}
Value::String(string) => write!(f, "{string}"),
}
}
}
#[derive(Clone, Debug, PartialEq)]
pub enum ValueError {
CannotAdd(Value, Value),
CannotAnd(Value, Value),
CannotCompare(Value, Value),
CannotDivide(Value, Value),
CannotModulo(Value, Value),
CannotMultiply(Value, Value),
CannotNegate(Value),
CannotNot(Value),
CannotSubtract(Value, Value),
CannotOr(Value, Value),
}
impl Display for ValueError {
fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
match self {
ValueError::CannotAdd(left, right) => {
write!(f, "Cannot add {left} and {right}")
}
ValueError::CannotAnd(left, right) => {
write!(f, "Cannot use logical AND operation on {left} and {right}")
}
ValueError::CannotCompare(left, right) => {
write!(f, "Cannot compare {left} and {right}")
}
ValueError::CannotDivide(left, right) => {
write!(f, "Cannot divide {left} by {right}")
}
ValueError::CannotModulo(left, right) => {
write!(f, "Cannot use modulo operation on {left} and {right}")
}
ValueError::CannotMultiply(left, right) => {
write!(f, "Cannot multiply {left} by {right}")
}
ValueError::CannotNegate(value) => {
write!(f, "Cannot negate {value}")
}
ValueError::CannotNot(value) => {
write!(f, "Cannot use logical NOT operation on {value}")
}
ValueError::CannotSubtract(left, right) => {
write!(f, "Cannot subtract {right} from {left}")
}
ValueError::CannotOr(left, right) => {
write!(f, "Cannot use logical OR operation on {left} and {right}")
}
}
}
}

View File

@ -0,0 +1,154 @@
use std::{
fmt::{self, Display, Formatter},
ops::{Range, RangeInclusive},
};
use serde::{Deserialize, Serialize};
use crate::Type;
#[derive(Clone, Copy, Debug, PartialEq, PartialOrd, Serialize, Deserialize)]
pub enum RangeValue {
ByteRange { start: u8, end: u8 },
ByteRangeInclusive { start: u8, end: u8 },
CharacterRange { start: char, end: char },
CharacterRangeInclusive { start: char, end: char },
FloatRange { start: f64, end: f64 },
FloatRangeInclusive { start: f64, end: f64 },
IntegerRange { start: i64, end: i64 },
IntegerRangeInclusive { start: i64, end: i64 },
}
impl RangeValue {
pub fn r#type(&self) -> Type {
let inner_type = match self {
RangeValue::ByteRange { .. } | RangeValue::ByteRangeInclusive { .. } => Type::Byte,
RangeValue::CharacterRange { .. } | RangeValue::CharacterRangeInclusive { .. } => {
Type::Character
}
RangeValue::FloatRange { .. } | RangeValue::FloatRangeInclusive { .. } => Type::Float,
RangeValue::IntegerRange { .. } | RangeValue::IntegerRangeInclusive { .. } => {
Type::Integer
}
};
Type::Range {
r#type: Box::new(inner_type),
}
}
}
impl From<Range<u8>> for RangeValue {
fn from(range: Range<u8>) -> Self {
RangeValue::ByteRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<u8>> for RangeValue {
fn from(range: RangeInclusive<u8>) -> Self {
RangeValue::ByteRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<char>> for RangeValue {
fn from(range: Range<char>) -> Self {
RangeValue::CharacterRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<char>> for RangeValue {
fn from(range: RangeInclusive<char>) -> Self {
RangeValue::CharacterRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<f64>> for RangeValue {
fn from(range: Range<f64>) -> Self {
RangeValue::FloatRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<f64>> for RangeValue {
fn from(range: RangeInclusive<f64>) -> Self {
RangeValue::FloatRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl From<Range<i32>> for RangeValue {
fn from(range: Range<i32>) -> Self {
RangeValue::IntegerRange {
start: range.start as i64,
end: range.end as i64,
}
}
}
impl From<RangeInclusive<i32>> for RangeValue {
fn from(range: RangeInclusive<i32>) -> Self {
RangeValue::IntegerRangeInclusive {
start: *range.start() as i64,
end: *range.end() as i64,
}
}
}
impl From<Range<i64>> for RangeValue {
fn from(range: Range<i64>) -> Self {
RangeValue::IntegerRange {
start: range.start,
end: range.end,
}
}
}
impl From<RangeInclusive<i64>> for RangeValue {
fn from(range: RangeInclusive<i64>) -> Self {
RangeValue::IntegerRangeInclusive {
start: *range.start(),
end: *range.end(),
}
}
}
impl Display for RangeValue {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
RangeValue::ByteRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::ByteRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::CharacterRange { start, end } => {
write!(f, "{}..{}", start, end)
}
RangeValue::CharacterRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::FloatRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::FloatRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
RangeValue::IntegerRange { start, end } => write!(f, "{}..{}", start, end),
RangeValue::IntegerRangeInclusive { start, end } => {
write!(f, "{}..={}", start, end)
}
}
}
}

View File

@ -3,21 +3,28 @@ use std::{
cmp::Ordering, cmp::Ordering,
collections::HashMap, collections::HashMap,
fmt::{self, Display, Formatter}, fmt::{self, Display, Formatter},
mem::replace,
rc::Weak,
}; };
use crate::{ use crate::{
compile, value::ConcreteValue, AnnotatedError, Chunk, ChunkError, DustError, FunctionBorrowed, compile, value::Value, AnnotatedError, Chunk, ChunkError, DustError, Instruction,
Instruction, NativeFunction, NativeFunctionError, Operation, Span, Type, Value, ValueError, NativeFunction, NativeFunctionError, Operation, Span, Type, ValueError,
}; };
pub fn run(source: &str) -> Result<Option<ConcreteValue>, DustError> { pub fn run(source: &str) -> Result<Option<Value>, DustError> {
let chunk = compile(source)?; let chunk = compile(source)?;
let has_return_value = *chunk.r#type().return_type != Type::None;
let mut vm = Vm::new(&chunk, None); let mut vm = Vm::new(&chunk, None);
vm.run() vm.run()
.map_err(|error| DustError::Runtime { error, source }) .map_err(|error| DustError::Runtime { error, source })?;
if has_return_value {
vm.take_top_of_stack_as_value()
.map(Some)
.map_err(|error| DustError::Runtime { error, source })
} else {
Ok(None)
}
} }
pub fn run_and_display_output(source: &str) { pub fn run_and_display_output(source: &str) {
@ -31,36 +38,43 @@ pub fn run_and_display_output(source: &str) {
/// Dust virtual machine. /// Dust virtual machine.
/// ///
/// See the [module-level documentation](index.html) for more information. /// See the [module-level documentation](index.html) for more information.
#[derive(Debug, Eq, PartialEq)] #[derive(Debug, PartialEq)]
pub struct Vm<'chunk, 'parent, 'stack> { pub struct Vm<'a> {
chunk: &'a Chunk,
stack: Vec<Register>,
parent: Option<&'a Vm<'a>>,
ip: usize, ip: usize,
chunk: &'chunk Chunk,
stack: Vec<Register<'stack>>,
local_definitions: HashMap<u8, u8>, local_definitions: HashMap<u8, u8>,
last_assigned_register: Option<u8>, last_assigned_register: Option<u8>,
parent: Option<&'parent Vm<'chunk, 'stack, 'parent>>, current_position: Span,
} }
impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> { impl<'a> Vm<'a> {
const STACK_LIMIT: usize = u16::MAX as usize; const STACK_LIMIT: usize = u16::MAX as usize;
pub fn new(chunk: &'chunk Chunk, parent: Option<&'parent Vm<'chunk, 'parent, 'stack>>) -> Self { pub fn new(chunk: &'a Chunk, parent: Option<&'a Vm<'a>>) -> Self {
Self { Self {
ip: 0,
chunk, chunk,
stack: Vec::new(), stack: Vec::new(),
parent,
ip: 0,
local_definitions: HashMap::new(), local_definitions: HashMap::new(),
last_assigned_register: None, last_assigned_register: None,
parent, current_position: Span(0, 0),
} }
} }
pub fn run(&'stack mut self) -> Result<Option<ConcreteValue>, VmError> { pub fn current_position(&self) -> Span {
while let Ok((instruction, position)) = self.read(Span(0, 0)).copied() { self.current_position
}
pub fn run(&mut self) -> Result<(), VmError> {
while let Ok(instruction) = self.read() {
log::info!( log::info!(
"{} | {} | {} | {}", "{} | {} | {} | {}",
self.ip - 1, self.ip - 1,
position, self.current_position,
instruction.operation(), instruction.operation(),
instruction.disassembly_info(self.chunk) instruction.disassembly_info(self.chunk)
); );
@ -73,13 +87,10 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
.stack .stack
.get(from_register as usize) .get(from_register as usize)
.is_some_and(|register| !matches!(register, Register::Empty)); .is_some_and(|register| !matches!(register, Register::Empty));
let register = Register::Pointer(Pointer::Stack(from_register));
if from_register_has_value { if from_register_has_value {
self.set_register( self.set_register(to_register, register)?;
to_register,
Register::StackPointer(from_register),
position,
)?;
} }
} }
Operation::Close => { Operation::Close => {
@ -87,7 +98,9 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
let to_register = instruction.c(); let to_register = instruction.c();
if self.stack.len() < to_register as usize { if self.stack.len() < to_register as usize {
return Err(VmError::StackUnderflow { position }); return Err(VmError::StackUnderflow {
position: self.current_position,
});
} }
for register_index in from_register..to_register { for register_index in from_register..to_register {
@ -98,9 +111,9 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
let to_register = instruction.a(); let to_register = instruction.a();
let boolean = instruction.b_as_boolean(); let boolean = instruction.b_as_boolean();
let jump = instruction.c_as_boolean(); let jump = instruction.c_as_boolean();
let boolean = ConcreteValue::boolean(boolean); let boolean = Value::boolean(boolean);
self.set_register(to_register, Register::Value(boolean), position)?; self.set_register(to_register, Register::Value(boolean))?;
if jump { if jump {
self.ip += 1; self.ip += 1;
@ -113,8 +126,7 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
self.set_register( self.set_register(
to_register, to_register,
Register::ConstantPointer(from_constant), Register::Pointer(Pointer::Constant(from_constant)),
position,
)?; )?;
if jump { if jump {
@ -127,18 +139,19 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
let mut list = Vec::new(); let mut list = Vec::new();
for register_index in start_register..to_register { for register_index in start_register..to_register {
let value = self.open_register(register_index, position)?; let value = self.open_register(register_index)?;
list.push(value); list.push(value);
} }
self.set_register(to_register, Register::List(list), position)?; // self.set_register(to_register, Register::List(list))?;
todo!()
} }
Operation::LoadSelf => { Operation::LoadSelf => {
let to_register = instruction.a(); let to_register = instruction.a();
let function = Value::FunctionBorrowed(FunctionBorrowed::new(self.chunk));
// self.set_register(to_register, Register::Value(function), position)?; // self.set_register(to_register, Register::Value(function))?;
todo!() todo!()
} }
@ -154,15 +167,12 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
let local_register = self.local_definitions.get(&local_index).copied().ok_or( let local_register = self.local_definitions.get(&local_index).copied().ok_or(
VmError::UndefinedLocal { VmError::UndefinedLocal {
local_index, local_index,
position, position: self.current_position,
}, },
)?; )?;
let register = Register::Pointer(Pointer::Stack(local_register));
self.set_register( self.set_register(to_register, register)?;
to_register,
Register::StackPointer(local_register),
position,
)?;
} }
Operation::SetLocal => { Operation::SetLocal => {
let from_register = instruction.a(); let from_register = instruction.a();
@ -170,71 +180,73 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
let local_register = self.local_definitions.get(&to_local).copied().ok_or( let local_register = self.local_definitions.get(&to_local).copied().ok_or(
VmError::UndefinedLocal { VmError::UndefinedLocal {
local_index: to_local, local_index: to_local,
position, position: self.current_position,
}, },
)?; )?;
let register = Register::Pointer(Pointer::Stack(from_register));
self.set_register( self.set_register(local_register, register)?;
local_register,
Register::StackPointer(from_register),
position,
)?;
} }
Operation::Add => { Operation::Add => {
let to_register = instruction.a(); let to_register = instruction.a();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let sum = left let sum = left.add(right).map_err(|error| VmError::Value {
.add(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
})?;
self.set_register(to_register, Register::Value(sum), position)?; self.set_register(to_register, Register::Value(sum))?;
} }
Operation::Subtract => { Operation::Subtract => {
let to_register = instruction.a(); let to_register = instruction.a();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let difference = left let difference = left.subtract(right).map_err(|error| VmError::Value {
.subtract(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
})?;
self.set_register(to_register, Register::Value(difference), position)?; self.set_register(to_register, Register::Value(difference))?;
} }
Operation::Multiply => { Operation::Multiply => {
let to_register = instruction.a(); let to_register = instruction.a();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let product = left let product = left.multiply(right).map_err(|error| VmError::Value {
.multiply(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
})?;
self.set_register(to_register, Register::Value(product), position)?; self.set_register(to_register, Register::Value(product))?;
} }
Operation::Divide => { Operation::Divide => {
let to_register = instruction.a(); let to_register = instruction.a();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let quotient = left let quotient = left.divide(right).map_err(|error| VmError::Value {
.divide(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
})?;
self.set_register(to_register, Register::Value(quotient), position)?; self.set_register(to_register, Register::Value(quotient))?;
} }
Operation::Modulo => { Operation::Modulo => {
let to_register = instruction.a(); let to_register = instruction.a();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let remainder = left let remainder = left.modulo(right).map_err(|error| VmError::Value {
.modulo(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
})?;
self.set_register(to_register, Register::Value(remainder), position)?; self.set_register(to_register, Register::Value(remainder))?;
} }
Operation::Test => { Operation::Test => {
let register = instruction.a(); let register = instruction.a();
let test_value = instruction.c_as_boolean(); let test_value = instruction.c_as_boolean();
let value = self.open_register(register, position)?; let value = self.open_register(register)?;
let boolean = if let Some(boolean) = value.as_boolean() { let boolean = if let Value::Boolean(boolean) = value {
boolean *boolean
} else { } else {
return Err(VmError::ExpectedBoolean { return Err(VmError::ExpectedBoolean {
found: value.into_concrete(), found: value.clone(),
position, position: self.current_position,
}); });
}; };
@ -245,270 +257,250 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
Operation::TestSet => todo!(), Operation::TestSet => todo!(),
Operation::Equal => { Operation::Equal => {
debug_assert_eq!( debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(), self.get_instruction(self.ip)?.0.operation(),
Operation::Jump Operation::Jump
); );
let compare_to = instruction.a_as_boolean(); let compare_to = instruction.a_as_boolean();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let equal_result = left let equal_result = left.equal(right).map_err(|error| VmError::Value {
.equal(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
let is_equal = if let ConcreteValue::Boolean(boolean) = equal_result { })?;
let is_equal = if let Value::Boolean(boolean) = equal_result {
boolean boolean
} else { } else {
return Err(VmError::ExpectedBoolean { return Err(VmError::ExpectedBoolean {
found: equal_result.clone(), found: equal_result.clone(),
position, position: self.current_position,
}); });
}; };
if is_equal == compare_to { if is_equal == compare_to {
self.ip += 1; self.ip += 1;
} else { } else {
let jump = self.get_instruction(self.ip, position)?.0; let jump = self.get_instruction(self.ip)?.0;
self.jump(jump); self.jump(jump);
} }
} }
Operation::Less => { Operation::Less => {
debug_assert_eq!( debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(), self.get_instruction(self.ip)?.0.operation(),
Operation::Jump Operation::Jump
); );
let compare_to = instruction.a_as_boolean(); let compare_to = instruction.a_as_boolean();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let less_result = left let less_result = left.less_than(right).map_err(|error| VmError::Value {
.less_than(&right) error,
.map_err(|error| VmError::Value { error, position })?; position: self.current_position,
let is_less_than = if let ConcreteValue::Boolean(boolean) = less_result { })?;
let is_less_than = if let Value::Boolean(boolean) = less_result {
boolean boolean
} else { } else {
return Err(VmError::ExpectedBoolean { return Err(VmError::ExpectedBoolean {
found: less_result.clone(), found: less_result.clone(),
position, position: self.current_position,
}); });
}; };
if is_less_than == compare_to { if is_less_than == compare_to {
self.ip += 1; self.ip += 1;
} else { } else {
let jump = self.get_instruction(self.ip, position)?.0; let jump = self.get_instruction(self.ip)?.0;
self.jump(jump); self.jump(jump);
} }
} }
Operation::LessEqual => { Operation::LessEqual => {
debug_assert_eq!( debug_assert_eq!(
self.get_instruction(self.ip, position)?.0.operation(), self.get_instruction(self.ip)?.0.operation(),
Operation::Jump Operation::Jump
); );
let compare_to = instruction.a_as_boolean(); let compare_to = instruction.a_as_boolean();
let (left, right) = self.get_arguments(instruction, position)?; let (left, right) = self.get_arguments(instruction)?;
let less_or_equal_result = left let less_or_equal_result =
.less_than_or_equal(&right) left.less_than_or_equal(right)
.map_err(|error| VmError::Value { error, position })?; .map_err(|error| VmError::Value {
error,
position: self.current_position,
})?;
let is_less_than_or_equal = let is_less_than_or_equal =
if let ConcreteValue::Boolean(boolean) = less_or_equal_result { if let Value::Boolean(boolean) = less_or_equal_result {
boolean boolean
} else { } else {
return Err(VmError::ExpectedBoolean { return Err(VmError::ExpectedBoolean {
found: less_or_equal_result.clone(), found: less_or_equal_result.clone(),
position, position: self.current_position,
}); });
}; };
if is_less_than_or_equal == compare_to { if is_less_than_or_equal == compare_to {
self.ip += 1; self.ip += 1;
} else { } else {
let jump = self.get_instruction(self.ip, position)?.0; let jump = self.get_instruction(self.ip)?.0;
self.jump(jump); self.jump(jump);
} }
} }
Operation::Negate => { Operation::Negate => {
let value = let value = self.get_argument(instruction.b(), instruction.b_is_constant())?;
self.get_argument(instruction.b(), instruction.b_is_constant(), position)?; let negated = value.negate().map_err(|error| VmError::Value {
let negated = value error,
.negate() position: self.current_position,
.map_err(|error| VmError::Value { error, position })?; })?;
self.set_register(instruction.a(), Register::Value(negated), position)?; self.set_register(instruction.a(), Register::Value(negated))?;
} }
Operation::Not => { Operation::Not => {
let value = let value = self.get_argument(instruction.b(), instruction.b_is_constant())?;
self.get_argument(instruction.b(), instruction.b_is_constant(), position)?; let not = value.not().map_err(|error| VmError::Value {
let not = value error,
.not() position: self.current_position,
.map_err(|error| VmError::Value { error, position })?; })?;
self.set_register(instruction.a(), Register::Value(not), position)?; self.set_register(instruction.a(), Register::Value(not))?;
} }
Operation::Jump => self.jump(instruction), Operation::Jump => self.jump(instruction),
Operation::Call => { Operation::Call => {
let to_register = instruction.a(); let to_register = instruction.a();
let function_register = instruction.b(); let function_register = instruction.b();
let argument_count = instruction.c(); let argument_count = instruction.c();
let value = self.open_register(function_register, position)?; let value = self.open_register(function_register)?;
let function = if let Some(function) = value.as_function() { let chunk = if let Value::Function(chunk) = value {
function chunk
} else { } else {
return Err(VmError::ExpectedFunction { return Err(VmError::ExpectedFunction {
found: value.into_concrete(), found: value.clone(),
position, position: self.current_position,
}); });
}; };
let mut function_vm = Vm::new(function.chunk(), Some(self)); let has_return_value = *chunk.r#type().return_type != Type::None;
let mut function_vm = Vm::new(chunk, Some(self));
let first_argument_index = function_register + 1; let first_argument_index = function_register + 1;
let last_argument_index = first_argument_index + argument_count;
for argument_index in for argument_index in first_argument_index..last_argument_index {
first_argument_index..first_argument_index + argument_count
{
let top_of_stack = function_vm.stack.len() as u8; let top_of_stack = function_vm.stack.len() as u8;
function_vm.set_register( function_vm.set_register(
top_of_stack, top_of_stack,
Register::ParentStackPointer(argument_index), Register::Pointer(Pointer::ParentStack(argument_index)),
position,
)? )?
} }
let return_value = function_vm.run()?; function_vm.run()?;
if let Some(value) = return_value { if has_return_value {
self.set_register(to_register, Register::Value(value), position)?; let top_of_stack = function_vm.stack.len() as u8 - 1;
self.set_register(
to_register,
Register::Pointer(Pointer::ParentStack(top_of_stack)),
)?;
} }
} }
Operation::CallNative => { Operation::CallNative => {
let native_function = NativeFunction::from(instruction.b()); let native_function = NativeFunction::from(instruction.b());
let return_value = native_function.call(self, instruction, position)?; let return_value = native_function.call(self, instruction)?;
if let Some(concrete_value) = return_value { if let Some(concrete_value) = return_value {
let to_register = instruction.a(); let to_register = instruction.a();
self.set_register(to_register, Register::Value(concrete_value), position)?; self.set_register(to_register, Register::Value(concrete_value))?;
} }
} }
Operation::Return => { Operation::Return => {
let should_return_value = instruction.b_as_boolean(); let should_return_value = instruction.b_as_boolean();
if !should_return_value { if !should_return_value {
return Ok(None); return Ok(());
} }
return if let Some(register_index) = self.last_assigned_register { return if let Some(register_index) = self.last_assigned_register {
self.open_register(register_index, position) let top_of_stack = self.stack.len() as u8 - 1;
.map(|value| Some(value.into_concrete()))
if register_index != top_of_stack {
self.stack
.push(Register::Pointer(Pointer::Stack(register_index)));
}
Ok(())
} else { } else {
Err(VmError::StackUnderflow { position }) Err(VmError::StackUnderflow {
position: self.current_position,
})
}; };
} }
} }
} }
Ok(None) Ok(())
} }
pub(crate) fn open_register( fn resolve_pointer(&self, pointer: Pointer) -> Result<&Value, VmError> {
&'stack self, match pointer {
register_index: u8, Pointer::Stack(register_index) => self.open_register(register_index),
position: Span, Pointer::Constant(constant_index) => self.get_constant(constant_index),
) -> Result<&'stack ConcreteValue, VmError> { Pointer::ParentStack(register_index) => {
let parent = self
.parent
.as_ref()
.ok_or_else(|| VmError::ExpectedParent {
position: self.current_position,
})?;
parent.open_register(register_index)
}
Pointer::ParentConstant(constant_index) => {
let parent = self
.parent
.as_ref()
.ok_or_else(|| VmError::ExpectedParent {
position: self.current_position,
})?;
parent.get_constant(constant_index)
}
}
}
pub(crate) fn open_register(&self, register_index: u8) -> Result<&Value, VmError> {
let register_index = register_index as usize; let register_index = register_index as usize;
let register = let register =
self.stack self.stack
.get(register_index) .get(register_index)
.ok_or_else(|| VmError::RegisterIndexOutOfBounds { .ok_or_else(|| VmError::RegisterIndexOutOfBounds {
index: register_index, index: register_index,
position, position: self.current_position,
})?; })?;
log::trace!("Open R{register_index} to {register}"); log::trace!("Open R{register_index} to {register}");
match register { match register {
Register::Value(value) => Ok(value), Register::Value(value) => Ok(value),
Register::List(list) => Ok(ConcreteValue::List( Register::Pointer(pointer) => self.resolve_pointer(*pointer),
list.into_iter()
.map(|concrete_value| (*concrete_value).clone())
.collect(),
)),
Register::StackPointer(register_index) => self.open_register(*register_index, position),
Register::ConstantPointer(constant_index) => {
self.get_constant(*constant_index, position)
}
Register::ParentStackPointer(register_index) => {
let parent = self.parent.ok_or(VmError::ExpectedParent { position })?;
parent.open_register(*register_index, position)
}
Register::ParentConstantPointer(constant_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
let constant = parent.get_constant(*constant_index, position)?;
Ok(constant)
}
Register::Empty => Err(VmError::EmptyRegister { Register::Empty => Err(VmError::EmptyRegister {
index: register_index, index: register_index,
position, position: self.current_position,
}), }),
} }
} }
fn get_concrete_from_register( fn take_top_of_stack_as_value(&mut self) -> Result<Value, VmError> {
&'stack self, let top_of_stack = self.stack.pop().ok_or(VmError::StackUnderflow {
register_index: u8, position: self.current_position,
position: Span, })?;
) -> Result<ConcreteValue, VmError> {
let register_index = register_index as usize;
let register =
self.stack
.get(register_index)
.ok_or_else(|| VmError::RegisterIndexOutOfBounds {
index: register_index,
position,
})?;
let value = match register { match top_of_stack {
Register::Value(concrete_value) => concrete_value.clone(), Register::Value(value) => Ok(value),
Register::List(list) => { _ => Err(VmError::ExpectedValue {
let items = list.into_iter().map(|value| (*value).clone()).collect(); found: top_of_stack,
position: self.current_position,
ConcreteValue::List(items) }),
} }
Register::StackPointer(register_index) => {
self.get_concrete_from_register(*register_index, position)?
}
Register::ConstantPointer(constant_pointer) => {
self.get_constant(*constant_pointer, position)?.clone()
}
Register::ParentStackPointer(register_index) => {
let parent = self.parent.ok_or(VmError::ExpectedParent { position })?;
parent.get_concrete_from_register(*register_index, position)?
}
Register::ParentConstantPointer(constant_index) => {
let parent = self
.parent
.as_ref()
.ok_or(VmError::ExpectedParent { position })?;
parent.get_constant(*constant_index, position)?.clone()
}
Register::Empty => {
return Err(VmError::EmptyRegister {
index: register_index,
position,
})
}
};
Ok(value)
} }
/// DRY helper for handling JUMP instructions /// DRY helper for handling JUMP instructions
@ -524,46 +516,34 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
} }
/// DRY helper to get a constant or register values /// DRY helper to get a constant or register values
fn get_argument( fn get_argument(&self, index: u8, is_constant: bool) -> Result<&Value, VmError> {
&'stack self,
index: u8,
is_constant: bool,
position: Span,
) -> Result<Value<'stack>, VmError> {
let argument = if is_constant { let argument = if is_constant {
self.get_constant(index, position)?.as_reference_value() self.get_constant(index)?
} else { } else {
self.open_register(index, position)? self.open_register(index)?
}; };
Ok(argument) Ok(argument)
} }
/// DRY helper to get two arguments for binary operations /// DRY helper to get two arguments for binary operations
fn get_arguments( fn get_arguments(&self, instruction: Instruction) -> Result<(&Value, &Value), VmError> {
&'stack self, let left = self.get_argument(instruction.b(), instruction.b_is_constant())?;
instruction: Instruction, let right = self.get_argument(instruction.c(), instruction.c_is_constant())?;
position: Span,
) -> Result<(Value<'stack>, Value<'stack>), VmError> {
let left = self.get_argument(instruction.b(), instruction.b_is_constant(), position)?;
let right = self.get_argument(instruction.c(), instruction.c_is_constant(), position)?;
Ok((left, right)) Ok((left, right))
} }
fn set_register( fn set_register(&mut self, to_register: u8, register: Register) -> Result<(), VmError> {
&mut self,
to_register: u8,
register: Register<'stack>,
position: Span,
) -> Result<(), VmError> {
self.last_assigned_register = Some(to_register); self.last_assigned_register = Some(to_register);
let length = self.stack.len(); let length = self.stack.len();
let to_register = to_register as usize; let to_register = to_register as usize;
if length == Self::STACK_LIMIT { if length == Self::STACK_LIMIT {
return Err(VmError::StackOverflow { position }); return Err(VmError::StackOverflow {
position: self.current_position,
});
} }
match to_register.cmp(&length) { match to_register.cmp(&length) {
@ -599,28 +579,31 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
} }
} }
fn get_constant(&self, index: u8, position: Span) -> Result<&'chunk ConcreteValue, VmError> { fn get_constant(&self, index: u8) -> Result<&Value, VmError> {
self.chunk self.chunk
.get_constant(index) .get_constant(index)
.map_err(|error| VmError::Chunk { error, position }) .map_err(|error| VmError::Chunk {
error,
position: self.current_position,
})
} }
fn read(&mut self, position: Span) -> Result<&(Instruction, Span), VmError> { fn read(&mut self) -> Result<Instruction, VmError> {
let ip = self.ip; let (instruction, position) = *self.get_instruction(self.ip)?;
self.ip += 1; self.ip += 1;
self.current_position = position;
self.get_instruction(ip, position) Ok(instruction)
} }
fn get_instruction( fn get_instruction(&self, index: usize) -> Result<&(Instruction, Span), VmError> {
&self,
index: usize,
position: Span,
) -> Result<&(Instruction, Span), VmError> {
self.chunk self.chunk
.get_instruction(index) .get_instruction(index)
.map_err(|error| VmError::Chunk { error, position }) .map_err(|error| VmError::Chunk {
error,
position: self.current_position,
})
} }
fn define_local(&mut self, local_index: u8, register_index: u8) -> Result<(), VmError> { fn define_local(&mut self, local_index: u8, register_index: u8) -> Result<(), VmError> {
@ -632,39 +615,38 @@ impl<'chunk, 'parent, 'stack: 'chunk + 'parent> Vm<'chunk, 'parent, 'stack> {
} }
} }
#[derive(Debug, Eq, PartialEq)] #[derive(Clone, Debug, PartialEq)]
enum Register<'stack> { enum Register {
Empty, Empty,
Value(ConcreteValue), Value(Value),
List(Vec<&'stack ConcreteValue>), Pointer(Pointer),
StackPointer(u8),
ConstantPointer(u8),
ParentStackPointer(u8),
ParentConstantPointer(u8),
} }
impl<'stack> Display for Register<'stack> { impl Display for Register {
fn fmt(&self, f: &mut Formatter) -> fmt::Result { fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self { match self {
Self::Empty => write!(f, "empty"), Self::Empty => write!(f, "empty"),
Self::Value(value) => write!(f, "{}", value), Self::Value(value) => write!(f, "{}", value),
Self::List(values) => { Self::Pointer(pointer) => write!(f, "{}", pointer),
write!(f, "[")?; }
}
}
for (index, value) in values.iter().enumerate() { #[derive(Clone, Copy, Debug, Eq, PartialEq, PartialOrd, Ord)]
if index > 0 { pub enum Pointer {
write!(f, ", ")?; Stack(u8),
} Constant(u8),
ParentStack(u8),
ParentConstant(u8),
}
write!(f, "{}", value)?; impl Display for Pointer {
} fn fmt(&self, f: &mut Formatter) -> fmt::Result {
match self {
write!(f, "]") Self::Stack(index) => write!(f, "R{}", index),
} Self::Constant(index) => write!(f, "C{}", index),
Self::StackPointer(index) => write!(f, "R{}", index), Self::ParentStack(index) => write!(f, "PR{}", index),
Self::ConstantPointer(index) => write!(f, "C{}", index), Self::ParentConstant(index) => write!(f, "PC{}", index),
Self::ParentStackPointer(index) => write!(f, "PR{}", index),
Self::ParentConstantPointer(index) => write!(f, "PC{}", index),
} }
} }
} }
@ -672,52 +654,26 @@ impl<'stack> Display for Register<'stack> {
#[derive(Clone, Debug, PartialEq)] #[derive(Clone, Debug, PartialEq)]
pub enum VmError { pub enum VmError {
// Stack errors // Stack errors
StackOverflow { StackOverflow { position: Span },
position: Span, StackUnderflow { position: Span },
},
StackUnderflow {
position: Span,
},
// Register errors // Register errors
EmptyRegister { EmptyRegister { index: usize, position: Span },
index: usize, ExpectedValue { found: Register, position: Span },
position: Span, RegisterIndexOutOfBounds { index: usize, position: Span },
},
RegisterIndexOutOfBounds {
index: usize,
position: Span,
},
// Local errors // Local errors
UndefinedLocal { UndefinedLocal { local_index: u8, position: Span },
local_index: u8,
position: Span,
},
// Execution errors // Execution errors
ExpectedBoolean { ExpectedBoolean { found: Value, position: Span },
found: ConcreteValue, ExpectedFunction { found: Value, position: Span },
position: Span, ExpectedParent { position: Span },
},
ExpectedFunction {
found: ConcreteValue,
position: Span,
},
ExpectedParent {
position: Span,
},
// Wrappers for foreign errors // Wrappers for foreign errors
Chunk { Chunk { error: ChunkError, position: Span },
error: ChunkError,
position: Span,
},
NativeFunction(NativeFunctionError), NativeFunction(NativeFunctionError),
Value { Value { error: ValueError, position: Span },
error: ValueError,
position: Span,
},
} }
impl AnnotatedError for VmError { impl AnnotatedError for VmError {
@ -732,6 +688,7 @@ impl AnnotatedError for VmError {
Self::ExpectedBoolean { .. } => "Expected boolean", Self::ExpectedBoolean { .. } => "Expected boolean",
Self::ExpectedFunction { .. } => "Expected function", Self::ExpectedFunction { .. } => "Expected function",
Self::ExpectedParent { .. } => "Expected parent", Self::ExpectedParent { .. } => "Expected parent",
Self::ExpectedValue { .. } => "Expected value",
Self::NativeFunction(error) => error.description(), Self::NativeFunction(error) => error.description(),
Self::RegisterIndexOutOfBounds { .. } => "Register index out of bounds", Self::RegisterIndexOutOfBounds { .. } => "Register index out of bounds",
Self::StackOverflow { .. } => "Stack overflow", Self::StackOverflow { .. } => "Stack overflow",
@ -763,6 +720,7 @@ impl AnnotatedError for VmError {
Self::ExpectedBoolean { position, .. } => *position, Self::ExpectedBoolean { position, .. } => *position,
Self::ExpectedFunction { position, .. } => *position, Self::ExpectedFunction { position, .. } => *position,
Self::ExpectedParent { position } => *position, Self::ExpectedParent { position } => *position,
Self::ExpectedValue { position, .. } => *position,
Self::NativeFunction(error) => error.position(), Self::NativeFunction(error) => error.position(),
Self::RegisterIndexOutOfBounds { position, .. } => *position, Self::RegisterIndexOutOfBounds { position, .. } => *position,
Self::StackOverflow { position } => *position, Self::StackOverflow { position } => *position,