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react-code-dataset / next.js /turbopack /crates /turbopack-ecmascript /src /analyzer /mod.rs
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 #![allow(clippy::redundant_closure_call)]
use std::{
borrow::Cow,
cmp::Ordering,
fmt::{Display, Formatter, Write},
future::Future,
hash::{BuildHasherDefault, Hash, Hasher},
mem::take,
pin::Pin,
sync::Arc,
};
use anyhow::{Result, bail};
use graph::VarGraph;
use num_bigint::BigInt;
use num_traits::identities::Zero;
use once_cell::sync::Lazy;
use rustc_hash::FxHasher;
use swc_core::{
common::Mark,
ecma::{
ast::{Id, Ident, Lit},
atoms::Atom,
},
};
use turbo_esregex::EsRegex;
use turbo_rcstr::RcStr;
use turbo_tasks::{FxIndexMap, FxIndexSet, Vc};
use turbopack_core::compile_time_info::{
CompileTimeDefineValue, DefinableNameSegment, FreeVarReference,
};
use self::imports::ImportAnnotations;
pub(crate) use self::imports::ImportMap;
use crate::{references::require_context::RequireContextMap, utils::StringifyJs};
pub mod builtin;
pub mod graph;
pub mod imports;
pub mod linker;
pub mod top_level_await;
pub mod well_known;
type PinnedAsyncUntilSettledBox<'a, E> =
Pin<Box<dyn Future<Output = Result<(JsValue, bool), E>> + Send + 'a>>;
type PinnedAsyncBox<'a, E> = Pin<Box<dyn Future<Output = Result<(JsValue, bool), E>> + 'a>>;
#[derive(Debug, Clone, Hash, PartialEq, Eq)]
pub enum ObjectPart {
KeyValue(JsValue, JsValue),
Spread(JsValue),
}
impl Default for ObjectPart {
fn default() -> Self {
ObjectPart::Spread(Default::default())
}
}
#[derive(Debug, Clone)]
pub struct ConstantNumber(pub f64);
fn integer_decode(val: f64) -> (u64, i16, i8) {
let bits: u64 = val.to_bits();
let sign: i8 = if bits >> 63 == 0 { 1 } else { -1 };
let mut exponent: i16 = ((bits >> 52) & 0x7ff) as i16;
let mantissa = if exponent == 0 {
(bits & 0xfffffffffffff) << 1
} else {
(bits & 0xfffffffffffff) | 0x10000000000000
};
exponent -= 1023 + 52;
(mantissa, exponent, sign)
}
impl ConstantNumber {
pub fn as_u32_index(&self) -> Option<usize> {
let index: u32 = self.0 as u32;
(index as f64 == self.0).then_some(index as usize)
}
}
impl Hash for ConstantNumber {
fn hash<H: Hasher>(&self, state: &mut H) {
integer_decode(self.0).hash(state);
}
}
impl PartialEq for ConstantNumber {
fn eq(&self, other: &Self) -> bool {
integer_decode(self.0) == integer_decode(other.0)
}
}
impl Eq for ConstantNumber {}
#[derive(Debug, Clone)]
pub enum ConstantString {
Atom(Atom),
RcStr(RcStr),
}
impl ConstantString {
pub fn as_str(&self) -> &str {
match self {
Self::Atom(s) => s,
Self::RcStr(s) => s,
}
}
pub fn as_rcstr(&self) -> RcStr {
match self {
Self::Atom(s) => RcStr::from(s.as_str()),
Self::RcStr(s) => s.clone(),
}
}
pub fn as_atom(&self) -> Cow<'_, Atom> {
match self {
Self::Atom(s) => Cow::Borrowed(s),
Self::RcStr(s) => Cow::Owned(s.as_str().into()),
}
}
pub fn is_empty(&self) -> bool {
self.as_str().is_empty()
}
}
impl PartialEq for ConstantString {
fn eq(&self, other: &Self) -> bool {
self.as_str() == other.as_str()
}
}
impl Eq for ConstantString {}
impl Hash for ConstantString {
fn hash<H: Hasher>(&self, state: &mut H) {
self.as_str().hash(state);
}
}
impl Display for ConstantString {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
self.as_str().fmt(f)
}
}
impl From<Atom> for ConstantString {
fn from(v: Atom) -> Self {
ConstantString::Atom(v)
}
}
impl From<&'static str> for ConstantString {
fn from(v: &'static str) -> Self {
ConstantString::Atom(v.into())
}
}
impl From<String> for ConstantString {
fn from(v: String) -> Self {
ConstantString::Atom(v.into())
}
}
impl From<RcStr> for ConstantString {
fn from(v: RcStr) -> Self {
ConstantString::RcStr(v)
}
}
#[derive(Debug, Clone, Hash, PartialEq, Eq, Default)]
pub enum ConstantValue {
#[default]
Undefined,
Str(ConstantString),
Num(ConstantNumber),
True,
False,
Null,
BigInt(Box<BigInt>),
Regex(Box<(Atom, Atom)>),
}
impl ConstantValue {
pub fn as_str(&self) -> Option<&str> {
match self {
Self::Str(s) => Some(s.as_str()),
_ => None,
}
}
pub fn as_bool(&self) -> Option<bool> {
match self {
Self::True => Some(true),
Self::False => Some(false),
_ => None,
}
}
pub fn is_truthy(&self) -> bool {
match self {
Self::Undefined | Self::False | Self::Null => false,
Self::True | Self::Regex(..) => true,
Self::Str(s) => !s.is_empty(),
Self::Num(ConstantNumber(n)) => *n != 0.0,
Self::BigInt(n) => !n.is_zero(),
}
}
pub fn is_nullish(&self) -> bool {
match self {
Self::Undefined | Self::Null => true,
Self::Str(..)
| Self::Num(..)
| Self::True
| Self::False
| Self::BigInt(..)
| Self::Regex(..) => false,
}
}
pub fn is_empty_string(&self) -> bool {
match self {
Self::Str(s) => s.is_empty(),
_ => false,
}
}
pub fn is_value_type(&self) -> bool {
!matches!(self, Self::Regex(..))
}
}
impl From<bool> for ConstantValue {
fn from(v: bool) -> Self {
match v {
true => ConstantValue::True,
false => ConstantValue::False,
}
}
}
impl From<&'_ str> for ConstantValue {
fn from(v: &str) -> Self {
ConstantValue::Str(ConstantString::Atom(v.into()))
}
}
impl From<Lit> for ConstantValue {
fn from(v: Lit) -> Self {
match v {
Lit::Str(v) => ConstantValue::Str(ConstantString::Atom(v.value)),
Lit::Bool(v) => {
if v.value {
ConstantValue::True
} else {
ConstantValue::False
}
}
Lit::Null(_) => ConstantValue::Null,
Lit::Num(v) => ConstantValue::Num(ConstantNumber(v.value)),
Lit::BigInt(v) => ConstantValue::BigInt(v.value),
Lit::Regex(v) => ConstantValue::Regex(Box::new((v.exp, v.flags))),
Lit::JSXText(v) => ConstantValue::Str(ConstantString::Atom(v.value)),
}
}
}
impl Display for ConstantValue {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
ConstantValue::Undefined => write!(f, "undefined"),
ConstantValue::Str(str) => write!(f, "{}", StringifyJs(str.as_str())),
ConstantValue::True => write!(f, "true"),
ConstantValue::False => write!(f, "false"),
ConstantValue::Null => write!(f, "null"),
ConstantValue::Num(ConstantNumber(n)) => write!(f, "{n}"),
ConstantValue::BigInt(n) => write!(f, "{n}"),
ConstantValue::Regex(regex) => write!(f, "/{}/{}", regex.0, regex.1),
}
}
}
#[derive(Debug, Clone, Hash, PartialEq, Eq)]
pub struct ModuleValue {
pub module: Atom,
pub annotations: ImportAnnotations,
}
#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
pub enum LogicalOperator {
And,
Or,
NullishCoalescing,
}
impl LogicalOperator {
fn joiner(&self) -> &'static str {
match self {
LogicalOperator::And => " && ",
LogicalOperator::Or => " || ",
LogicalOperator::NullishCoalescing => " ?? ",
}
}
fn multi_line_joiner(&self) -> &'static str {
match self {
LogicalOperator::And => "&& ",
LogicalOperator::Or => "|| ",
LogicalOperator::NullishCoalescing => "?? ",
}
}
}
#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
pub enum BinaryOperator {
Equal,
NotEqual,
StrictEqual,
StrictNotEqual,
}
impl BinaryOperator {
fn joiner(&self) -> &'static str {
match self {
BinaryOperator::Equal => " == ",
BinaryOperator::NotEqual => " != ",
BinaryOperator::StrictEqual => " === ",
BinaryOperator::StrictNotEqual => " !== ",
}
}
fn positive_op(&self) -> (PositiveBinaryOperator, bool) {
match self {
BinaryOperator::Equal => (PositiveBinaryOperator::Equal, false),
BinaryOperator::NotEqual => (PositiveBinaryOperator::Equal, true),
BinaryOperator::StrictEqual => (PositiveBinaryOperator::StrictEqual, false),
BinaryOperator::StrictNotEqual => (PositiveBinaryOperator::StrictEqual, true),
}
}
}
#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
pub enum PositiveBinaryOperator {
Equal,
StrictEqual,
}
#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
pub enum JsValueUrlKind {
Absolute,
Relative,
}
impl Display for JsValueUrlKind {
fn fmt(&self, f: &mut Formatter<'_>) -> std::fmt::Result {
f.write_str(match self {
JsValueUrlKind::Absolute => "absolute",
JsValueUrlKind::Relative => "relative",
})
}
}
/// The four categories of [JsValue]s.
enum JsValueMetaKind {
/// Doesn't contain nested values.
Leaf,
/// Contains nested values. Nested values represent some structure and can't
/// be replaced during linking. They might contain placeholders.
Nested,
/// Contains nested values. Operations are replaced during linking. They
/// might contain placeholders.
Operation,
/// These values are replaced during linking.
Placeholder,
}
#[derive(Debug, Clone, Copy, Hash, PartialEq, Eq)]
pub enum LogicalProperty {
Truthy,
Falsy,
Nullish,
NonNullish,
}
impl Display for LogicalProperty {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
LogicalProperty::Truthy => write!(f, "truthy"),
LogicalProperty::Falsy => write!(f, "falsy"),
LogicalProperty::Nullish => write!(f, "nullish"),
LogicalProperty::NonNullish => write!(f, "non-nullish"),
}
}
}
/// TODO: Use `Arc`
/// There are 4 kinds of values: Leaves, Nested, Operations, and Placeholders
/// (see [JsValueMetaKind] for details). Values are processed in two phases:
/// - Analyze phase: We convert AST into [JsValue]s. We don't have contextual information so we need
/// to insert placeholders to represent that.
/// - Link phase: We try to reduce a value to a constant value. The link phase has 5 substeps that
/// are executed on each node in the graph depth-first. When a value is modified, we need to visit
/// the new children again.
/// - Replace variables with their values. This replaces [JsValue::Variable]. No variable should be
/// remaining after that.
/// - Replace placeholders with contextual information. This usually replaces [JsValue::FreeVar] and
/// [JsValue::Module]. Some [JsValue::Call] on well- known functions might also be replaced. No
/// free vars or modules should be remaining after that.
/// - Replace operations on well-known objects and functions. This handles [JsValue::Call] and
/// [JsValue::Member] on well-known objects and functions.
/// - Replace all built-in functions with their values when they are compile-time constant.
/// - For optimization, any nested operations are replaced with [JsValue::Unknown]. So only one
/// layer of operation remains. Any remaining operation or placeholder can be treated as unknown.
#[derive(Debug, Clone, Hash, PartialEq, Eq)]
pub enum JsValue {
// LEAF VALUES
// ----------------------------
/// A constant primitive value.
Constant(ConstantValue),
/// A constant URL object.
Url(ConstantString, JsValueUrlKind),
/// Some kind of well-known object
/// (must not be an array, otherwise Array.concat needs to be changed)
WellKnownObject(WellKnownObjectKind),
/// Some kind of well-known function
WellKnownFunction(WellKnownFunctionKind),
/// Not-analyzable value. Might contain the original value for additional
/// info. Has a reason string for explanation.
Unknown {
original_value: Option<Arc<JsValue>>,
reason: Cow<'static, str>,
has_side_effects: bool,
},
// NESTED VALUES
// ----------------------------
/// An array of nested values
Array {
total_nodes: u32,
items: Vec<JsValue>,
mutable: bool,
},
/// An object of nested values
Object {
total_nodes: u32,
parts: Vec<ObjectPart>,
mutable: bool,
},
/// A list of alternative values
Alternatives {
total_nodes: u32,
values: Vec<JsValue>,
logical_property: Option<LogicalProperty>,
},
/// A function reference. The return value might contain [JsValue::Argument]
/// placeholders that need to be replaced when calling this function.
/// `(total_node_count, func_ident, return_value)`
Function(u32, u32, Box<JsValue>),
// OPERATIONS
// ----------------------------
/// A string concatenation of values.
/// `foo.${unknownVar}.js` => 'foo' + Unknown + '.js'
Concat(u32, Vec<JsValue>),
/// An addition of values.
/// This can be converted to [JsValue::Concat] if the type of the variable
/// is string.
Add(u32, Vec<JsValue>),
/// Logical negation `!expr`
Not(u32, Box<JsValue>),
/// Logical operator chain e. g. `expr && expr`
Logical(u32, LogicalOperator, Vec<JsValue>),
/// Binary expression e. g. `expr == expr`
Binary(u32, Box<JsValue>, BinaryOperator, Box<JsValue>),
/// A constructor call.
/// `(total_node_count, callee, args)`
New(u32, Box<JsValue>, Vec<JsValue>),
/// A function call without a `this` context.
/// `(total_node_count, callee, args)`
Call(u32, Box<JsValue>, Vec<JsValue>),
/// A super call to the parent constructor.
/// `(total_node_count, args)`
SuperCall(u32, Vec<JsValue>),
/// A function call with a `this` context.
/// `(total_node_count, obj, prop, args)`
MemberCall(u32, Box<JsValue>, Box<JsValue>, Vec<JsValue>),
/// A member access `obj[prop]`
/// `(total_node_count, obj, prop)`
Member(u32, Box<JsValue>, Box<JsValue>),
/// A tenary operator `test ? cons : alt`
/// `(total_node_count, test, cons, alt)`
Tenary(u32, Box<JsValue>, Box<JsValue>, Box<JsValue>),
/// A promise resolving to some value
/// `(total_node_count, value)`
Promise(u32, Box<JsValue>),
/// An await call (potentially) unwrapping a promise.
/// `(total_node_count, value)`
Awaited(u32, Box<JsValue>),
/// A for-of loop
///
/// `(total_node_count, iterable)`
Iterated(u32, Box<JsValue>),
/// A `typeof` expression.
///
/// `(total_node_count, operand)`
TypeOf(u32, Box<JsValue>),
// PLACEHOLDERS
// ----------------------------
/// A reference to a variable.
Variable(Id),
/// A reference to an function argument.
/// (func_ident, arg_index)
Argument(u32, usize),
// TODO no predefined kinds, only Atom
/// A reference to a free variable.
FreeVar(Atom),
/// This is a reference to a imported module.
Module(ModuleValue),
}
impl From<&'_ str> for JsValue {
fn from(v: &str) -> Self {
ConstantValue::Str(ConstantString::Atom(v.into())).into()
}
}
impl From<Atom> for JsValue {
fn from(v: Atom) -> Self {
ConstantValue::Str(ConstantString::Atom(v)).into()
}
}
impl From<BigInt> for JsValue {
fn from(v: BigInt) -> Self {
Self::from(Box::new(v))
}
}
impl From<Box<BigInt>> for JsValue {
fn from(v: Box<BigInt>) -> Self {
ConstantValue::BigInt(v).into()
}
}
impl From<f64> for JsValue {
fn from(v: f64) -> Self {
ConstantValue::Num(ConstantNumber(v)).into()
}
}
impl From<RcStr> for JsValue {
fn from(v: RcStr) -> Self {
ConstantValue::Str(v.into()).into()
}
}
impl From<String> for JsValue {
fn from(v: String) -> Self {
RcStr::from(v).into()
}
}
impl From<swc_core::ecma::ast::Str> for JsValue {
fn from(v: swc_core::ecma::ast::Str) -> Self {
ConstantValue::Str(v.value.into()).into()
}
}
impl From<ConstantValue> for JsValue {
fn from(v: ConstantValue) -> Self {
JsValue::Constant(v)
}
}
impl From<&CompileTimeDefineValue> for JsValue {
fn from(v: &CompileTimeDefineValue) -> Self {
match v {
CompileTimeDefineValue::String(s) => JsValue::Constant(s.as_str().into()),
CompileTimeDefineValue::Bool(b) => JsValue::Constant((*b).into()),
CompileTimeDefineValue::JSON(_) => {
JsValue::unknown_empty(false, "compile time injected JSON")
}
CompileTimeDefineValue::Undefined => JsValue::Constant(ConstantValue::Undefined),
}
}
}
impl From<&FreeVarReference> for JsValue {
fn from(v: &FreeVarReference) -> Self {
match v {
FreeVarReference::Value(v) => v.into(),
FreeVarReference::Ident(_) => {
JsValue::unknown_empty(false, "compile time injected ident")
}
FreeVarReference::Member(_, _) => {
JsValue::unknown_empty(false, "compile time injected member")
}
FreeVarReference::EcmaScriptModule { .. } => {
JsValue::unknown_empty(false, "compile time injected free var module")
}
FreeVarReference::Error(_) => {
JsValue::unknown_empty(false, "compile time injected free var error")
}
FreeVarReference::InputRelative(kind) => {
use turbopack_core::compile_time_info::InputRelativeConstant;
JsValue::unknown_empty(
false,
match kind {
InputRelativeConstant::DirName => {
"compile time injected free var referencing the directory name"
}
InputRelativeConstant::FileName => {
"compile time injected free var referencing the file name"
}
},
)
}
}
}
}
impl Default for JsValue {
fn default() -> Self {
JsValue::unknown_empty(false, "")
}
}
impl Display for ObjectPart {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
ObjectPart::KeyValue(key, value) => write!(f, "{key}: {value}"),
ObjectPart::Spread(value) => write!(f, "...{value}"),
}
}
}
impl Display for JsValue {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
match self {
JsValue::Constant(v) => write!(f, "{v}"),
JsValue::Url(url, kind) => write!(f, "{url} {kind}"),
JsValue::Array { items, mutable, .. } => write!(
f,
"{}[{}]",
if *mutable { "" } else { "frozen " },
items
.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::Object { parts, mutable, .. } => write!(
f,
"{}{{{}}}",
if *mutable { "" } else { "frozen " },
parts
.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::Alternatives {
total_nodes: _,
values: list,
logical_property,
} => {
let list = list
.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(" | ");
if let Some(logical_property) = logical_property {
write!(f, "({list}){{{logical_property}}}")
} else {
write!(f, "({list})")
}
}
JsValue::FreeVar(name) => write!(f, "FreeVar({name:?})"),
JsValue::Variable(name) => write!(f, "Variable({}#{:?})", name.0, name.1),
JsValue::Concat(_, list) => write!(
f,
"`{}`",
list.iter()
.map(|v| v
.as_str()
.map_or_else(|| format!("${{{v}}}"), |str| str.to_string()))
.collect::<Vec<_>>()
.join("")
),
JsValue::Add(_, list) => write!(
f,
"({})",
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(" + ")
),
JsValue::Not(_, value) => write!(f, "!({value})"),
JsValue::Logical(_, op, list) => write!(
f,
"({})",
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(op.joiner())
),
JsValue::Binary(_, a, op, b) => write!(f, "({}{}{})", a, op.joiner(), b),
JsValue::Tenary(_, test, cons, alt) => write!(f, "({test} ? {cons} : {alt})"),
JsValue::New(_, callee, list) => write!(
f,
"new {}({})",
callee,
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::Call(_, callee, list) => write!(
f,
"{}({})",
callee,
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::SuperCall(_, list) => write!(
f,
"super({})",
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::MemberCall(_, obj, prop, list) => write!(
f,
"{}[{}]({})",
obj,
prop,
list.iter()
.map(|v| v.to_string())
.collect::<Vec<_>>()
.join(", ")
),
JsValue::Member(_, obj, prop) => write!(f, "{obj}[{prop}]"),
JsValue::Module(ModuleValue {
module: name,
annotations,
}) => {
write!(f, "Module({name}, {annotations})")
}
JsValue::Unknown { .. } => write!(f, "???"),
JsValue::WellKnownObject(obj) => write!(f, "WellKnownObject({obj:?})"),
JsValue::WellKnownFunction(func) => write!(f, "WellKnownFunction({func:?})"),
JsValue::Function(_, func_ident, return_value) => {
write!(f, "Function#{func_ident}(return = {return_value:?})")
}
JsValue::Argument(func_ident, index) => {
write!(f, "arguments[{index}#{func_ident}]")
}
JsValue::Iterated(_, iterable) => write!(f, "Iterated({iterable})"),
JsValue::TypeOf(_, operand) => write!(f, "typeof({operand})"),
JsValue::Promise(_, operand) => write!(f, "Promise<{operand}>"),
JsValue::Awaited(_, operand) => write!(f, "await({operand})"),
}
}
}
fn pretty_join(
items: &[String],
indent_depth: usize,
single_line_separator: &str,
multi_line_separator_end: &str,
multi_line_separator_start: &str,
) -> String {
let multi_line = items
.iter()
.any(|item| item.len() > 50 || item.contains('\n'))
|| items
.iter()
.map(|item| item.len() + single_line_separator.len())
.sum::<usize>()
> 100;
if !multi_line {
items.join(single_line_separator)
} else if multi_line_separator_start.is_empty() {
format!(
"\n{}{}\n{}",
" ".repeat(indent_depth + 1),
items.join(&format!(
"{multi_line_separator_end}\n{}",
" ".repeat(indent_depth + 1)
)),
" ".repeat(indent_depth)
)
} else {
format!(
"\n{}{multi_line_separator_start}{}\n{}",
" ".repeat(indent_depth * 4 + 4 - multi_line_separator_start.len()),
items.join(&format!(
"{multi_line_separator_end}\n{}{multi_line_separator_start}",
" ".repeat(indent_depth * 4 + 4 - multi_line_separator_start.len())
)),
" ".repeat(indent_depth)
)
}
}
fn total_nodes(vec: &[JsValue]) -> u32 {
vec.iter().map(|v| v.total_nodes()).sum::<u32>()
}
// Private meta methods
impl JsValue {
fn meta_type(&self) -> JsValueMetaKind {
match self {
JsValue::Constant(..)
| JsValue::Url(..)
| JsValue::WellKnownObject(..)
| JsValue::WellKnownFunction(..)
| JsValue::Unknown { .. } => JsValueMetaKind::Leaf,
JsValue::Array { .. }
| JsValue::Object { .. }
| JsValue::Alternatives { .. }
| JsValue::Function(..)
| JsValue::Promise(..)
| JsValue::Member(..) => JsValueMetaKind::Nested,
JsValue::Concat(..)
| JsValue::Add(..)
| JsValue::Not(..)
| JsValue::Logical(..)
| JsValue::Binary(..)
| JsValue::New(..)
| JsValue::Call(..)
| JsValue::SuperCall(..)
| JsValue::Tenary(..)
| JsValue::MemberCall(..)
| JsValue::Iterated(..)
| JsValue::Awaited(..)
| JsValue::TypeOf(..) => JsValueMetaKind::Operation,
JsValue::Variable(..)
| JsValue::Argument(..)
| JsValue::FreeVar(..)
| JsValue::Module(..) => JsValueMetaKind::Placeholder,
}
}
}
// Constructors
impl JsValue {
pub fn alternatives(list: Vec<JsValue>) -> Self {
Self::Alternatives {
total_nodes: 1 + total_nodes(&list),
values: list,
logical_property: None,
}
}
pub fn alternatives_with_additional_property(
list: Vec<JsValue>,
logical_property: LogicalProperty,
) -> Self {
Self::Alternatives {
total_nodes: 1 + total_nodes(&list),
values: list,
logical_property: Some(logical_property),
}
}
pub fn concat(list: Vec<JsValue>) -> Self {
Self::Concat(1 + total_nodes(&list), list)
}
pub fn add(list: Vec<JsValue>) -> Self {
Self::Add(1 + total_nodes(&list), list)
}
pub fn logical_and(list: Vec<JsValue>) -> Self {
Self::Logical(1 + total_nodes(&list), LogicalOperator::And, list)
}
pub fn logical_or(list: Vec<JsValue>) -> Self {
Self::Logical(1 + total_nodes(&list), LogicalOperator::Or, list)
}
pub fn nullish_coalescing(list: Vec<JsValue>) -> Self {
Self::Logical(
1 + total_nodes(&list),
LogicalOperator::NullishCoalescing,
list,
)
}
pub fn tenary(test: Box<JsValue>, cons: Box<JsValue>, alt: Box<JsValue>) -> Self {
Self::Tenary(
1 + test.total_nodes() + cons.total_nodes() + alt.total_nodes(),
test,
cons,
alt,
)
}
pub fn iterated(iterable: Box<JsValue>) -> Self {
Self::Iterated(1 + iterable.total_nodes(), iterable)
}
pub fn equal(a: Box<JsValue>, b: Box<JsValue>) -> Self {
Self::Binary(
1 + a.total_nodes() + b.total_nodes(),
a,
BinaryOperator::Equal,
b,
)
}
pub fn not_equal(a: Box<JsValue>, b: Box<JsValue>) -> Self {
Self::Binary(
1 + a.total_nodes() + b.total_nodes(),
a,
BinaryOperator::NotEqual,
b,
)
}
pub fn strict_equal(a: Box<JsValue>, b: Box<JsValue>) -> Self {
Self::Binary(
1 + a.total_nodes() + b.total_nodes(),
a,
BinaryOperator::StrictEqual,
b,
)
}
pub fn strict_not_equal(a: Box<JsValue>, b: Box<JsValue>) -> Self {
Self::Binary(
1 + a.total_nodes() + b.total_nodes(),
a,
BinaryOperator::StrictNotEqual,
b,
)
}
pub fn logical_not(inner: Box<JsValue>) -> Self {
Self::Not(1 + inner.total_nodes(), inner)
}
pub fn type_of(operand: Box<JsValue>) -> Self {
Self::TypeOf(1 + operand.total_nodes(), operand)
}
pub fn array(items: Vec<JsValue>) -> Self {
Self::Array {
total_nodes: 1 + total_nodes(&items),
items,
mutable: true,
}
}
pub fn frozen_array(items: Vec<JsValue>) -> Self {
Self::Array {
total_nodes: 1 + total_nodes(&items),
items,
mutable: false,
}
}
pub fn function(func_ident: u32, return_value: Box<JsValue>) -> Self {
Self::Function(1 + return_value.total_nodes(), func_ident, return_value)
}
pub fn object(list: Vec<ObjectPart>) -> Self {
Self::Object {
total_nodes: 1 + list
.iter()
.map(|v| match v {
ObjectPart::KeyValue(k, v) => k.total_nodes() + v.total_nodes(),
ObjectPart::Spread(s) => s.total_nodes(),
})
.sum::<u32>(),
parts: list,
mutable: true,
}
}
pub fn frozen_object(list: Vec<ObjectPart>) -> Self {
Self::Object {
total_nodes: 1 + list
.iter()
.map(|v| match v {
ObjectPart::KeyValue(k, v) => k.total_nodes() + v.total_nodes(),
ObjectPart::Spread(s) => s.total_nodes(),
})
.sum::<u32>(),
parts: list,
mutable: false,
}
}
pub fn new(f: Box<JsValue>, args: Vec<JsValue>) -> Self {
Self::New(1 + f.total_nodes() + total_nodes(&args), f, args)
}
pub fn call(f: Box<JsValue>, args: Vec<JsValue>) -> Self {
Self::Call(1 + f.total_nodes() + total_nodes(&args), f, args)
}
pub fn super_call(args: Vec<JsValue>) -> Self {
Self::SuperCall(1 + total_nodes(&args), args)
}
pub fn member_call(o: Box<JsValue>, p: Box<JsValue>, args: Vec<JsValue>) -> Self {
Self::MemberCall(
1 + o.total_nodes() + p.total_nodes() + total_nodes(&args),
o,
p,
args,
)
}
pub fn member(o: Box<JsValue>, p: Box<JsValue>) -> Self {
Self::Member(1 + o.total_nodes() + p.total_nodes(), o, p)
}
pub fn promise(operand: Box<JsValue>) -> Self {
Self::Promise(1 + operand.total_nodes(), operand)
}
pub fn awaited(operand: Box<JsValue>) -> Self {
Self::Awaited(1 + operand.total_nodes(), operand)
}
pub fn unknown(
value: impl Into<Arc<JsValue>>,
side_effects: bool,
reason: impl Into<Cow<'static, str>>,
) -> Self {
Self::Unknown {
original_value: Some(value.into()),
reason: reason.into(),
has_side_effects: side_effects,
}
}
pub fn unknown_empty(side_effects: bool, reason: impl Into<Cow<'static, str>>) -> Self {
Self::Unknown {
original_value: None,
reason: reason.into(),
has_side_effects: side_effects,
}
}
pub fn unknown_if(
is_unknown: bool,
value: JsValue,
side_effects: bool,
reason: impl Into<Cow<'static, str>>,
) -> Self {
if is_unknown {
Self::Unknown {
original_value: Some(value.into()),
reason: reason.into(),
has_side_effects: side_effects,
}
} else {
value
}
}
}
// Methods regarding node count
impl JsValue {
pub fn has_children(&self) -> bool {
self.total_nodes() > 1
}
pub fn total_nodes(&self) -> u32 {
match self {
JsValue::Constant(_)
| JsValue::Url(_, _)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..) => 1,
JsValue::Array { total_nodes: c, .. }
| JsValue::Object { total_nodes: c, .. }
| JsValue::Alternatives { total_nodes: c, .. }
| JsValue::Concat(c, _)
| JsValue::Add(c, _)
| JsValue::Not(c, _)
| JsValue::Logical(c, _, _)
| JsValue::Binary(c, _, _, _)
| JsValue::Tenary(c, _, _, _)
| JsValue::New(c, _, _)
| JsValue::Call(c, _, _)
| JsValue::SuperCall(c, _)
| JsValue::MemberCall(c, _, _, _)
| JsValue::Member(c, _, _)
| JsValue::Function(c, _, _)
| JsValue::Iterated(c, ..)
| JsValue::Promise(c, ..)
| JsValue::Awaited(c, ..)
| JsValue::TypeOf(c, ..) => *c,
}
}
fn update_total_nodes(&mut self) {
match self {
JsValue::Constant(_)
| JsValue::Url(_, _)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..) => {}
JsValue::Array {
total_nodes: c,
items: list,
..
}
| JsValue::Alternatives {
total_nodes: c,
values: list,
..
}
| JsValue::Concat(c, list)
| JsValue::Add(c, list)
| JsValue::Logical(c, _, list) => {
*c = 1 + total_nodes(list);
}
JsValue::Binary(c, a, _, b) => {
*c = 1 + a.total_nodes() + b.total_nodes();
}
JsValue::Tenary(c, test, cons, alt) => {
*c = 1 + test.total_nodes() + cons.total_nodes() + alt.total_nodes();
}
JsValue::Not(c, r) => {
*c = 1 + r.total_nodes();
}
JsValue::Promise(c, r) => {
*c = 1 + r.total_nodes();
}
JsValue::Awaited(c, r) => {
*c = 1 + r.total_nodes();
}
JsValue::Object {
total_nodes: c,
parts,
mutable: _,
} => {
*c = 1 + parts
.iter()
.map(|v| match v {
ObjectPart::KeyValue(k, v) => k.total_nodes() + v.total_nodes(),
ObjectPart::Spread(s) => s.total_nodes(),
})
.sum::<u32>();
}
JsValue::New(c, f, list) => {
*c = 1 + f.total_nodes() + total_nodes(list);
}
JsValue::Call(c, f, list) => {
*c = 1 + f.total_nodes() + total_nodes(list);
}
JsValue::SuperCall(c, list) => {
*c = 1 + total_nodes(list);
}
JsValue::MemberCall(c, o, m, list) => {
*c = 1 + o.total_nodes() + m.total_nodes() + total_nodes(list);
}
JsValue::Member(c, o, p) => {
*c = 1 + o.total_nodes() + p.total_nodes();
}
JsValue::Function(c, _, r) => {
*c = 1 + r.total_nodes();
}
JsValue::Iterated(c, iterable) => {
*c = 1 + iterable.total_nodes();
}
JsValue::TypeOf(c, operand) => {
*c = 1 + operand.total_nodes();
}
}
}
#[cfg(debug_assertions)]
pub fn debug_assert_total_nodes_up_to_date(&mut self) {
let old = self.total_nodes();
self.update_total_nodes();
assert_eq!(
old,
self.total_nodes(),
"total nodes not up to date {self:?}"
);
}
#[cfg(not(debug_assertions))]
pub fn debug_assert_total_nodes_up_to_date(&mut self) {}
pub fn ensure_node_limit(&mut self, limit: u32) {
fn cmp_nodes(a: &JsValue, b: &JsValue) -> Ordering {
a.total_nodes().cmp(&b.total_nodes())
}
fn make_max_unknown<'a>(mut iter: impl Iterator<Item = &'a mut JsValue>) {
let mut max = iter.next().unwrap();
let mut side_effects = max.has_side_effects();
for item in iter {
side_effects |= item.has_side_effects();
if cmp_nodes(item, max) == Ordering::Greater {
max = item;
}
}
max.make_unknown_without_content(side_effects, "node limit reached");
}
if self.total_nodes() > limit {
match self {
JsValue::Constant(_)
| JsValue::Url(_, _)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Argument(..) => {
self.make_unknown_without_content(false, "node limit reached")
}
&mut JsValue::Unknown {
original_value: _,
reason: _,
has_side_effects,
} => self.make_unknown_without_content(has_side_effects, "node limit reached"),
JsValue::Array { items: list, .. }
| JsValue::Alternatives {
total_nodes: _,
values: list,
logical_property: _,
}
| JsValue::Concat(_, list)
| JsValue::Logical(_, _, list)
| JsValue::Add(_, list) => {
make_max_unknown(list.iter_mut());
self.update_total_nodes();
}
JsValue::Not(_, r) => {
r.make_unknown_without_content(false, "node limit reached");
}
JsValue::Binary(_, a, _, b) => {
if a.total_nodes() > b.total_nodes() {
a.make_unknown_without_content(b.has_side_effects(), "node limit reached");
} else {
b.make_unknown_without_content(a.has_side_effects(), "node limit reached");
}
self.update_total_nodes();
}
JsValue::Object { parts, .. } => {
make_max_unknown(parts.iter_mut().flat_map(|v| match v {
// TODO this probably can avoid heap allocation somehow
ObjectPart::KeyValue(k, v) => vec![k, v].into_iter(),
ObjectPart::Spread(s) => vec![s].into_iter(),
}));
self.update_total_nodes();
}
JsValue::New(_, f, args) => {
make_max_unknown([&mut **f].into_iter().chain(args.iter_mut()));
self.update_total_nodes();
}
JsValue::Call(_, f, args) => {
make_max_unknown([&mut **f].into_iter().chain(args.iter_mut()));
self.update_total_nodes();
}
JsValue::SuperCall(_, args) => {
make_max_unknown(args.iter_mut());
self.update_total_nodes();
}
JsValue::MemberCall(_, o, p, args) => {
make_max_unknown([&mut **o, &mut **p].into_iter().chain(args.iter_mut()));
self.update_total_nodes();
}
JsValue::Tenary(_, test, cons, alt) => {
make_max_unknown([&mut **test, &mut **cons, &mut **alt].into_iter());
self.update_total_nodes();
}
JsValue::Iterated(_, iterable) => {
iterable.make_unknown_without_content(false, "node limit reached");
}
JsValue::TypeOf(_, operand) => {
operand.make_unknown_without_content(false, "node limit reached");
}
JsValue::Awaited(_, operand) => {
operand.make_unknown_without_content(false, "node limit reached");
}
JsValue::Promise(_, operand) => {
operand.make_unknown_without_content(false, "node limit reached");
}
JsValue::Member(_, o, p) => {
make_max_unknown([&mut **o, &mut **p].into_iter());
self.update_total_nodes();
}
JsValue::Function(_, _, r) => {
r.make_unknown_without_content(false, "node limit reached");
}
}
}
}
}
// Methods for explaining a value
impl JsValue {
pub fn explain_args(args: &[JsValue], depth: usize, unknown_depth: usize) -> (String, String) {
let mut hints = Vec::new();
let args = args
.iter()
.map(|arg| arg.explain_internal(&mut hints, 1, depth, unknown_depth))
.collect::<Vec<_>>();
let explainer = pretty_join(&args, 0, ", ", ",", "");
(
explainer,
hints.into_iter().fold(String::new(), |mut out, h| {
let _ = write!(out, "\n{h}");
out
}),
)
}
pub fn explain(&self, depth: usize, unknown_depth: usize) -> (String, String) {
let mut hints = Vec::new();
let explainer = self.explain_internal(&mut hints, 0, depth, unknown_depth);
(
explainer,
hints.into_iter().fold(String::new(), |mut out, h| {
let _ = write!(out, "\n{h}");
out
}),
)
}
fn explain_internal_inner(
&self,
hints: &mut Vec<String>,
indent_depth: usize,
depth: usize,
unknown_depth: usize,
) -> String {
if depth == 0 {
return "...".to_string();
}
// let i = hints.len();
// if explainer.len() < 100 {
self.explain_internal(hints, indent_depth, depth - 1, unknown_depth)
// }
// hints.truncate(i);
// hints.push(String::new());
// hints[i] = format!(
// "- *{}* {}",
// i,
// self.explain_internal(hints, 1, depth - 1, unknown_depth)
// );
// format!("*{}*", i)
}
fn explain_internal(
&self,
hints: &mut Vec<String>,
indent_depth: usize,
depth: usize,
unknown_depth: usize,
) -> String {
match self {
JsValue::Constant(v) => format!("{v}"),
JsValue::Array { items, mutable, .. } => format!(
"{}[{}]",
if *mutable { "" } else { "frozen " },
pretty_join(
&items
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
),
JsValue::Object { parts, mutable, .. } => format!(
"{}{{{}}}",
if *mutable { "" } else { "frozen " },
pretty_join(
&parts
.iter()
.map(|v| match v {
ObjectPart::KeyValue(key, value) => format!(
"{}: {}",
key.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
),
value.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
)
),
ObjectPart::Spread(value) => format!(
"...{}",
value.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
)
),
})
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
),
JsValue::Url(url, kind) => format!("{url} {kind}"),
JsValue::Alternatives {
total_nodes: _,
values,
logical_property,
} => {
let list = pretty_join(
&values
.iter()
.map(|v| {
v.explain_internal_inner(hints, indent_depth + 1, depth, unknown_depth)
})
.collect::<Vec<_>>(),
indent_depth,
" | ",
"",
"| ",
);
if let Some(logical_property) = logical_property {
format!("({list}){{{logical_property}}}")
} else {
format!("({list})")
}
}
JsValue::FreeVar(name) => format!("FreeVar({name})"),
JsValue::Variable(name) => {
format!("{}", name.0)
}
JsValue::Argument(_, index) => {
format!("arguments[{index}]")
}
JsValue::Concat(_, list) => format!(
"`{}`",
list.iter()
.map(|v| v.as_str().map_or_else(
|| format!(
"${{{}}}",
v.explain_internal_inner(hints, indent_depth + 1, depth, unknown_depth)
),
|str| str.to_string()
))
.collect::<Vec<_>>()
.join("")
),
JsValue::Add(_, list) => format!(
"({})",
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
" + ",
"",
"+ "
)
),
JsValue::Logical(_, op, list) => format!(
"({})",
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
op.joiner(),
"",
op.multi_line_joiner()
)
),
JsValue::Binary(_, a, op, b) => format!(
"({}{}{})",
a.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
op.joiner(),
b.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
),
JsValue::Tenary(_, test, cons, alt) => format!(
"({} ? {} : {})",
test.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
cons.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
alt.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
),
JsValue::Not(_, value) => format!(
"!({})",
value.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
),
JsValue::Iterated(_, iterable) => {
format!(
"Iterated({})",
iterable.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
)
}
JsValue::TypeOf(_, operand) => {
format!(
"typeof({})",
operand.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
)
}
JsValue::Promise(_, operand) => {
format!(
"Promise<{}>",
operand.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
)
}
JsValue::Awaited(_, operand) => {
format!(
"await({})",
operand.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
)
}
JsValue::New(_, callee, list) => {
format!(
"new {}({})",
callee.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
)
}
JsValue::Call(_, callee, list) => {
format!(
"{}({})",
callee.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
)
}
JsValue::SuperCall(_, list) => {
format!(
"super({})",
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
)
}
JsValue::MemberCall(_, obj, prop, list) => {
format!(
"{}[{}]({})",
obj.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
prop.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
pretty_join(
&list
.iter()
.map(|v| v.explain_internal_inner(
hints,
indent_depth + 1,
depth,
unknown_depth
))
.collect::<Vec<_>>(),
indent_depth,
", ",
",",
""
)
)
}
JsValue::Member(_, obj, prop) => {
format!(
"{}[{}]",
obj.explain_internal_inner(hints, indent_depth, depth, unknown_depth),
prop.explain_internal_inner(hints, indent_depth, depth, unknown_depth)
)
}
JsValue::Module(ModuleValue {
module: name,
annotations,
}) => {
format!("module<{name}, {annotations}>")
}
JsValue::Unknown {
original_value: inner,
reason: explainer,
has_side_effects,
} => {
let has_side_effects = *has_side_effects;
if unknown_depth == 0 || explainer.is_empty() {
"???".to_string()
} else if let Some(inner) = inner {
let i = hints.len();
hints.push(String::new());
hints[i] = format!(
"- *{}* {}\n ⚠️ {}{}",
i,
inner.explain_internal(hints, 1, depth, unknown_depth - 1),
explainer,
if has_side_effects {
"\n ⚠️ This value might have side effects"
} else {
""
}
);
format!("???*{i}*")
} else {
let i = hints.len();
hints.push(String::new());
hints[i] = format!(
"- *{}* {}{}",
i,
explainer,
if has_side_effects {
"\n ⚠️ This value might have side effects"
} else {
""
}
);
format!("???*{i}*")
}
}
JsValue::WellKnownObject(obj) => {
let (name, explainer) = match obj {
WellKnownObjectKind::GlobalObject => (
"Object",
"The global Object variable",
),
WellKnownObjectKind::PathModule | WellKnownObjectKind::PathModuleDefault => (
"path",
"The Node.js path module: https://nodejs.org/api/path.html",
),
WellKnownObjectKind::FsModule | WellKnownObjectKind::FsModuleDefault => (
"fs",
"The Node.js fs module: https://nodejs.org/api/fs.html",
),
WellKnownObjectKind::FsModulePromises => (
"fs/promises",
"The Node.js fs module: https://nodejs.org/api/fs.html#promises-api",
),
WellKnownObjectKind::UrlModule | WellKnownObjectKind::UrlModuleDefault => (
"url",
"The Node.js url module: https://nodejs.org/api/url.html",
),
WellKnownObjectKind::ChildProcess | WellKnownObjectKind::ChildProcessDefault => (
"child_process",
"The Node.js child_process module: https://nodejs.org/api/child_process.html",
),
WellKnownObjectKind::OsModule | WellKnownObjectKind::OsModuleDefault => (
"os",
"The Node.js os module: https://nodejs.org/api/os.html",
),
WellKnownObjectKind::NodeProcess => (
"process",
"The Node.js process module: https://nodejs.org/api/process.html",
),
WellKnownObjectKind::NodeProcessArgv => (
"process.argv",
"The Node.js process.argv property: https://nodejs.org/api/process.html#processargv",
),
WellKnownObjectKind::NodeProcessEnv => (
"process.env",
"The Node.js process.env property: https://nodejs.org/api/process.html#processenv",
),
WellKnownObjectKind::NodePreGyp => (
"@mapbox/node-pre-gyp",
"The Node.js @mapbox/node-pre-gyp module: https://github.com/mapbox/node-pre-gyp",
),
WellKnownObjectKind::NodeExpressApp => (
"express",
"The Node.js express package: https://github.com/expressjs/express"
),
WellKnownObjectKind::NodeProtobufLoader => (
"@grpc/proto-loader",
"The Node.js @grpc/proto-loader package: https://github.com/grpc/grpc-node"
),
WellKnownObjectKind::NodeBuffer => (
"Buffer",
"The Node.js Buffer object: https://nodejs.org/api/buffer.html#class-buffer"
),
WellKnownObjectKind::RequireCache => (
"require.cache",
"The CommonJS require.cache object: https://nodejs.org/api/modules.html#requirecache"
),
WellKnownObjectKind::ImportMeta => (
"import.meta",
"The import.meta object"
),
};
if depth > 0 {
let i = hints.len();
hints.push(format!("- *{i}* {name}: {explainer}"));
format!("{name}*{i}*")
} else {
name.to_string()
}
}
JsValue::WellKnownFunction(func) => {
let (name, explainer) = match func {
WellKnownFunctionKind::ObjectAssign => (
"Object.assign".to_string(),
"Object.assign method: https://developer.mozilla.org/zh-CN/docs/Web/JavaScript/Reference/Global_Objects/Object/assign",
),
WellKnownFunctionKind::PathJoin => (
"path.join".to_string(),
"The Node.js path.join method: https://nodejs.org/api/path.html#pathjoinpaths",
),
WellKnownFunctionKind::PathDirname => (
"path.dirname".to_string(),
"The Node.js path.dirname method: https://nodejs.org/api/path.html#pathdirnamepath",
),
WellKnownFunctionKind::PathResolve(cwd) => (
format!("path.resolve({cwd})"),
"The Node.js path.resolve method: https://nodejs.org/api/path.html#pathresolvepaths",
),
WellKnownFunctionKind::Import => (
"import".to_string(),
"The dynamic import() method from the ESM specification: https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Statements/import#dynamic_imports"
),
WellKnownFunctionKind::Require => ("require".to_string(), "The require method from CommonJS"),
WellKnownFunctionKind::RequireResolve => ("require.resolve".to_string(), "The require.resolve method from CommonJS"),
WellKnownFunctionKind::RequireContext => ("require.context".to_string(), "The require.context method from webpack"),
WellKnownFunctionKind::RequireContextRequire(..) => ("require.context(...)".to_string(), "The require.context(...) method from webpack: https://webpack.js.org/api/module-methods/#requirecontext"),
WellKnownFunctionKind::RequireContextRequireKeys(..) => ("require.context(...).keys".to_string(), "The require.context(...).keys method from webpack: https://webpack.js.org/guides/dependency-management/#requirecontext"),
WellKnownFunctionKind::RequireContextRequireResolve(..) => ("require.context(...).resolve".to_string(), "The require.context(...).resolve method from webpack: https://webpack.js.org/guides/dependency-management/#requirecontext"),
WellKnownFunctionKind::Define => ("define".to_string(), "The define method from AMD"),
WellKnownFunctionKind::FsReadMethod(name) => (
format!("fs.{name}"),
"A file reading method from the Node.js fs module: https://nodejs.org/api/fs.html",
),
WellKnownFunctionKind::PathToFileUrl => (
"url.pathToFileURL".to_string(),
"The Node.js url.pathToFileURL method: https://nodejs.org/api/url.html#urlpathtofileurlpath",
),
WellKnownFunctionKind::ChildProcessSpawnMethod(name) => (
format!("child_process.{name}"),
"A process spawning method from the Node.js child_process module: https://nodejs.org/api/child_process.html",
),
WellKnownFunctionKind::ChildProcessFork => (
"child_process.fork".to_string(),
"The Node.js child_process.fork method: https://nodejs.org/api/child_process.html#child_processforkmodulepath-args-options",
),
WellKnownFunctionKind::OsArch => (
"os.arch".to_string(),
"The Node.js os.arch method: https://nodejs.org/api/os.html#os_os_arch",
),
WellKnownFunctionKind::OsPlatform => (
"os.process".to_string(),
"The Node.js os.process method: https://nodejs.org/api/os.html#os_os_process",
),
WellKnownFunctionKind::OsEndianness => (
"os.endianness".to_string(),
"The Node.js os.endianness method: https://nodejs.org/api/os.html#os_os_endianness",
),
WellKnownFunctionKind::ProcessCwd => (
"process.cwd".to_string(),
"The Node.js process.cwd method: https://nodejs.org/api/process.html#processcwd",
),
WellKnownFunctionKind::NodePreGypFind => (
"binary.find".to_string(),
"The Node.js @mapbox/node-pre-gyp module: https://github.com/mapbox/node-pre-gyp",
),
WellKnownFunctionKind::NodeGypBuild => (
"node-gyp-build".to_string(),
"The Node.js node-gyp-build module: https://github.com/prebuild/node-gyp-build"
),
WellKnownFunctionKind::NodeBindings => (
"bindings".to_string(),
"The Node.js bindings module: https://github.com/TooTallNate/node-bindings"
),
WellKnownFunctionKind::NodeExpress => (
"express".to_string(),
"require('express')() : https://github.com/expressjs/express"
),
WellKnownFunctionKind::NodeExpressSet => (
"set".to_string(),
"require('express')().set('view engine', 'jade') https://github.com/expressjs/express"
),
WellKnownFunctionKind::NodeStrongGlobalize => (
"SetRootDir".to_string(),
"require('strong-globalize')() https://github.com/strongloop/strong-globalize"
),
WellKnownFunctionKind::NodeStrongGlobalizeSetRootDir => (
"SetRootDir".to_string(),
"require('strong-globalize').SetRootDir(__dirname) https://github.com/strongloop/strong-globalize"
),
WellKnownFunctionKind::NodeResolveFrom => (
"resolveFrom".to_string(),
"require('resolve-from')(__dirname, 'node-gyp/bin/node-gyp') https://github.com/sindresorhus/resolve-from"
),
WellKnownFunctionKind::NodeProtobufLoad => (
"load/loadSync".to_string(),
"require('@grpc/proto-loader').load(filepath, { includeDirs: [root] }) https://github.com/grpc/grpc-node"
),
WellKnownFunctionKind::WorkerConstructor => (
"Worker".to_string(),
"The standard Worker constructor: https://developer.mozilla.org/en-US/docs/Web/API/Worker/Worker"
),
WellKnownFunctionKind::URLConstructor => (
"URL".to_string(),
"The standard URL constructor: https://developer.mozilla.org/en-US/docs/Web/API/URL/URL"
),
};
if depth > 0 {
let i = hints.len();
hints.push(format!("- *{i}* {name}: {explainer}"));
format!("{name}*{i}*")
} else {
name
}
}
JsValue::Function(_, _, return_value) => {
if depth > 0 {
format!(
"(...) => {}",
return_value.explain_internal(
hints,
indent_depth,
depth - 1,
unknown_depth
)
)
} else {
"(...) => ...".to_string()
}
}
}
}
}
// Unknown management
impl JsValue {
/// Convert the value into unknown with a specific reason.
pub fn make_unknown(&mut self, side_effects: bool, reason: impl Into<Cow<'static, str>>) {
*self = JsValue::unknown(take(self), side_effects || self.has_side_effects(), reason);
}
/// Convert the owned value into unknown with a specific reason.
pub fn into_unknown(
mut self,
side_effects: bool,
reason: impl Into<Cow<'static, str>>,
) -> Self {
self.make_unknown(side_effects, reason);
self
}
/// Convert the value into unknown with a specific reason, but don't retain
/// the original value.
pub fn make_unknown_without_content(
&mut self,
side_effects: bool,
reason: impl Into<Cow<'static, str>>,
) {
*self = JsValue::unknown_empty(side_effects || self.has_side_effects(), reason);
}
/// Make all nested operations unknown when the value is an operation.
pub fn make_nested_operations_unknown(&mut self) -> bool {
fn inner(this: &mut JsValue) -> bool {
if matches!(this.meta_type(), JsValueMetaKind::Operation) {
this.make_unknown(false, "nested operation");
true
} else {
this.for_each_children_mut(&mut inner)
}
}
if matches!(self.meta_type(), JsValueMetaKind::Operation) {
self.for_each_children_mut(&mut inner)
} else {
false
}
}
pub fn add_unknown_mutations(&mut self, side_effects: bool) {
self.add_alt(JsValue::unknown_empty(side_effects, "unknown mutation"));
}
}
// Definable name management
impl JsValue {
/// When the value has a user-definable name, return the length of it (in segments). Otherwise
/// returns None.
/// - any free var has itself as user-definable name: ["foo"]
/// - any member access adds the identifier as segment after the object: ["foo", "prop"]
/// - some well-known objects/functions have a user-definable names: ["import"]
/// - member calls without arguments also have a user-definable name which is the property with
/// `()` appended: ["foo", "prop()"]
/// - typeof expressions add `typeof` after the argument's segments: ["foo", "typeof"]
pub fn get_definable_name_len(&self) -> Option<usize> {
match self {
JsValue::FreeVar(_) => Some(1),
JsValue::Member(_, obj, prop) if prop.as_str().is_some() => {
Some(obj.get_definable_name_len()? + 1)
}
JsValue::WellKnownObject(obj) => obj.as_define_name().map(|d| d.len()),
JsValue::WellKnownFunction(func) => func.as_define_name().map(|d| d.len()),
JsValue::MemberCall(_, callee, prop, args)
if args.is_empty() && prop.as_str().is_some() =>
{
Some(callee.get_definable_name_len()? + 1)
}
JsValue::TypeOf(_, arg) => Some(arg.get_definable_name_len()? + 1),
_ => None,
}
}
/// Returns a reverse iterator over the segments of the user-definable
/// name. e. g. `foo.bar().baz` would yield `baz`, `bar()`, `foo`.
/// `(1+2).foo.baz` would also yield `baz`, `foo` even while the value is
/// not a complete user-definable name. Before calling this method you must
/// use [JsValue::get_definable_name_len] to determine if the value has a
/// user-definable name at all.
pub fn iter_definable_name_rev(&self) -> DefinableNameIter<'_> {
DefinableNameIter {
next: Some(self),
index: 0,
}
}
/// Returns any matching defined replacement that matches this value (the replacement that
/// matches `$self.$prop`).
///
/// Optionally when passed a VarGraph, verifies that the first segment is not a local
/// variable/was not reassigned.
pub fn match_free_var_reference<'a, T>(
&self,
var_graph: Option<&VarGraph>,
free_var_references: &'a FxIndexMap<
DefinableNameSegment,
FxIndexMap<Vec<DefinableNameSegment>, T>,
>,
prop: &DefinableNameSegment,
) -> Option<&'a T> {
if let Some(def_name_len) = self.get_definable_name_len()
&& let Some(references) = free_var_references.get(prop)
{
for (name, value) in references {
if name.len() != def_name_len {
continue;
}
let name_rev_it = name.iter().map(Cow::Borrowed).rev();
if name_rev_it.eq(self.iter_definable_name_rev()) {
if let Some(var_graph) = var_graph
&& let DefinableNameSegment::Name(first_str) = name.first().unwrap()
{
let first_str: &str = first_str;
if var_graph
.free_var_ids
.get(&first_str.into())
.is_some_and(|id| var_graph.values.contains_key(id))
{
// `typeof foo...` but `foo` was reassigned
return None;
}
}
return Some(value);
}
}
}
None
}
/// Returns any matching defined replacement that matches this value.
pub fn match_define<'a, T>(
&self,
defines: &'a FxIndexMap<Vec<DefinableNameSegment>, T>,
) -> Option<&'a T> {
if let Some(def_name_len) = self.get_definable_name_len() {
for (name, value) in defines.iter() {
if name.len() != def_name_len {
continue;
}
if name
.iter()
.map(Cow::Borrowed)
.rev()
.eq(self.iter_definable_name_rev())
{
return Some(value);
}
}
}
None
}
}
pub struct DefinableNameIter<'a> {
next: Option<&'a JsValue>,
index: usize,
}
impl<'a> Iterator for DefinableNameIter<'a> {
type Item = Cow<'a, DefinableNameSegment>;
fn next(&mut self) -> Option<Self::Item> {
let value = self.next.take()?;
Some(Cow::Owned(match value {
JsValue::FreeVar(kind) => (&**kind).into(),
JsValue::Member(_, obj, prop) => {
self.next = Some(obj);
prop.as_str()?.into()
}
JsValue::WellKnownObject(obj) => {
let name = obj.as_define_name()?;
let i = self.index;
self.index += 1;
if self.index < name.len() {
self.next = Some(value);
}
name[name.len() - i - 1].into()
}
JsValue::WellKnownFunction(func) => {
let name = func.as_define_name()?;
let i = self.index;
self.index += 1;
if self.index < name.len() {
self.next = Some(value);
}
name[name.len() - i - 1].into()
}
JsValue::MemberCall(_, callee, prop, args) if args.is_empty() => {
self.next = Some(callee);
format!("{}()", prop.as_str()?).into()
}
JsValue::TypeOf(_, arg) => {
self.next = Some(arg);
DefinableNameSegment::TypeOf
}
_ => return None,
}))
}
}
// Compile-time information gathering
impl JsValue {
/// Returns the constant string if the value represents a constant string.
pub fn as_str(&self) -> Option<&str> {
match self {
JsValue::Constant(c) => c.as_str(),
_ => None,
}
}
/// Returns the constant bool if the value represents a constant boolean.
pub fn as_bool(&self) -> Option<bool> {
match self {
JsValue::Constant(c) => c.as_bool(),
_ => None,
}
}
pub fn has_side_effects(&self) -> bool {
match self {
JsValue::Constant(_) => false,
JsValue::Concat(_, values)
| JsValue::Add(_, values)
| JsValue::Logical(_, _, values)
| JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => values.iter().any(JsValue::has_side_effects),
JsValue::Binary(_, a, _, b) => a.has_side_effects() || b.has_side_effects(),
JsValue::Tenary(_, test, cons, alt) => {
test.has_side_effects() || cons.has_side_effects() || alt.has_side_effects()
}
JsValue::Not(_, value) => value.has_side_effects(),
JsValue::Array { items, .. } => items.iter().any(JsValue::has_side_effects),
JsValue::Object { parts, .. } => parts.iter().any(|v| match v {
ObjectPart::KeyValue(k, v) => k.has_side_effects() || v.has_side_effects(),
ObjectPart::Spread(v) => v.has_side_effects(),
}),
// As function bodies aren't analyzed for side-effects, we have to assume every call can
// have sideeffects as well.
// Otherwise it would be
// `func_body(callee).has_side_effects() ||
// callee.has_side_effects() || args.iter().any(JsValue::has_side_effects`
JsValue::New(_, _callee, _args) => true,
JsValue::Call(_, _callee, _args) => true,
JsValue::SuperCall(_, _args) => true,
JsValue::MemberCall(_, _obj, _prop, _args) => true,
JsValue::Member(_, obj, prop) => obj.has_side_effects() || prop.has_side_effects(),
JsValue::Function(_, _, _) => false,
JsValue::Url(_, _) => false,
JsValue::Variable(_) => false,
JsValue::Module(_) => false,
JsValue::WellKnownObject(_) => false,
JsValue::WellKnownFunction(_) => false,
JsValue::FreeVar(_) => false,
JsValue::Unknown {
has_side_effects, ..
} => *has_side_effects,
JsValue::Argument(_, _) => false,
JsValue::Iterated(_, iterable) => iterable.has_side_effects(),
JsValue::TypeOf(_, operand) => operand.has_side_effects(),
JsValue::Promise(_, operand) => operand.has_side_effects(),
JsValue::Awaited(_, operand) => operand.has_side_effects(),
}
}
/// Checks if the value is truthy. Returns None if we don't know. Returns
/// Some if we know if or if not the value is truthy.
pub fn is_truthy(&self) -> Option<bool> {
match self {
JsValue::Constant(c) => Some(c.is_truthy()),
JsValue::Concat(..) => self.is_empty_string().map(|x| !x),
JsValue::Url(..)
| JsValue::Array { .. }
| JsValue::Object { .. }
| JsValue::WellKnownObject(..)
| JsValue::WellKnownFunction(..)
| JsValue::Function(..) => Some(true),
JsValue::Alternatives {
total_nodes: _,
values,
logical_property,
} => match logical_property {
Some(LogicalProperty::Truthy) => Some(true),
Some(LogicalProperty::Falsy) => Some(false),
Some(LogicalProperty::Nullish) => Some(false),
_ => merge_if_known(values, JsValue::is_truthy),
},
JsValue::Not(_, value) => value.is_truthy().map(|x| !x),
JsValue::Logical(_, op, list) => match op {
LogicalOperator::And => all_if_known(list, JsValue::is_truthy),
LogicalOperator::Or => any_if_known(list, JsValue::is_truthy),
LogicalOperator::NullishCoalescing => {
shortcircuit_if_known(list, JsValue::is_not_nullish, JsValue::is_truthy)
}
},
JsValue::Binary(_, box a, op, box b) => {
let (positive_op, negate) = op.positive_op();
match (positive_op, a, b) {
(
PositiveBinaryOperator::StrictEqual,
JsValue::Constant(a),
JsValue::Constant(b),
) if a.is_value_type() => Some(a == b),
(
PositiveBinaryOperator::StrictEqual,
JsValue::Constant(a),
JsValue::Constant(b),
) if a.is_value_type() => {
let same_type = {
use ConstantValue::*;
matches!(
(a, b),
(Num(_), Num(_))
| (Str(_), Str(_))
| (BigInt(_), BigInt(_))
| (True | False, True | False)
| (Undefined, Undefined)
| (Null, Null)
)
};
if same_type { Some(a == b) } else { None }
}
(
PositiveBinaryOperator::Equal,
JsValue::Constant(ConstantValue::Str(a)),
JsValue::Constant(ConstantValue::Str(b)),
) => Some(a == b),
(
PositiveBinaryOperator::Equal,
JsValue::Constant(ConstantValue::Num(a)),
JsValue::Constant(ConstantValue::Num(b)),
) => Some(a == b),
_ => None,
}
.map(|x| x ^ negate)
}
_ => None,
}
}
/// Checks if the value is falsy. Returns None if we don't know. Returns
/// Some if we know if or if not the value is falsy.
pub fn is_falsy(&self) -> Option<bool> {
self.is_truthy().map(|x| !x)
}
/// Checks if the value is nullish (null or undefined). Returns None if we
/// don't know. Returns Some if we know if or if not the value is nullish.
pub fn is_nullish(&self) -> Option<bool> {
match self {
JsValue::Constant(c) => Some(c.is_nullish()),
JsValue::Concat(..)
| JsValue::Url(..)
| JsValue::Array { .. }
| JsValue::Object { .. }
| JsValue::WellKnownObject(..)
| JsValue::WellKnownFunction(..)
| JsValue::Not(..)
| JsValue::Binary(..)
| JsValue::Function(..) => Some(false),
JsValue::Alternatives {
total_nodes: _,
values,
logical_property,
} => match logical_property {
Some(LogicalProperty::Nullish) => Some(true),
_ => merge_if_known(values, JsValue::is_nullish),
},
JsValue::Logical(_, op, list) => match op {
LogicalOperator::And => {
shortcircuit_if_known(list, JsValue::is_truthy, JsValue::is_nullish)
}
LogicalOperator::Or => {
shortcircuit_if_known(list, JsValue::is_falsy, JsValue::is_nullish)
}
LogicalOperator::NullishCoalescing => all_if_known(list, JsValue::is_nullish),
},
_ => None,
}
}
/// Checks if we know that the value is not nullish. Returns None if we
/// don't know. Returns Some if we know if or if not the value is not
/// nullish.
pub fn is_not_nullish(&self) -> Option<bool> {
self.is_nullish().map(|x| !x)
}
/// Checks if we know that the value is an empty string. Returns None if we
/// don't know. Returns Some if we know if or if not the value is an empty
/// string.
pub fn is_empty_string(&self) -> Option<bool> {
match self {
JsValue::Constant(c) => Some(c.is_empty_string()),
JsValue::Concat(_, list) => all_if_known(list, JsValue::is_empty_string),
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => merge_if_known(values, JsValue::is_empty_string),
JsValue::Logical(_, op, list) => match op {
LogicalOperator::And => {
shortcircuit_if_known(list, JsValue::is_truthy, JsValue::is_empty_string)
}
LogicalOperator::Or => {
shortcircuit_if_known(list, JsValue::is_falsy, JsValue::is_empty_string)
}
LogicalOperator::NullishCoalescing => {
shortcircuit_if_known(list, JsValue::is_not_nullish, JsValue::is_empty_string)
}
},
// Booleans are not empty strings
JsValue::Not(..) | JsValue::Binary(..) => Some(false),
// Objects are not empty strings
JsValue::Url(..)
| JsValue::Array { .. }
| JsValue::Object { .. }
| JsValue::WellKnownObject(..)
| JsValue::WellKnownFunction(..)
| JsValue::Function(..) => Some(false),
_ => None,
}
}
/// Returns true, if the value is unknown and storing it as condition
/// doesn't make sense. This is for optimization purposes.
pub fn is_unknown(&self) -> bool {
match self {
JsValue::Unknown { .. } => true,
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => values.iter().any(|x| x.is_unknown()),
_ => false,
}
}
/// Checks if we know that the value is a string. Returns None if we
/// don't know. Returns Some if we know if or if not the value is a string.
pub fn is_string(&self) -> Option<bool> {
match self {
JsValue::Constant(ConstantValue::Str(..))
| JsValue::Concat(..)
| JsValue::TypeOf(..) => Some(true),
// Objects are not strings
JsValue::Constant(..)
| JsValue::Array { .. }
| JsValue::Object { .. }
| JsValue::Url(..)
| JsValue::Module(..)
| JsValue::Function(..)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Promise(_, _) => Some(false),
// Booleans are not strings
JsValue::Not(..) | JsValue::Binary(..) => Some(false),
JsValue::Add(_, list) => any_if_known(list, JsValue::is_string),
JsValue::Logical(_, op, list) => match op {
LogicalOperator::And => {
shortcircuit_if_known(list, JsValue::is_truthy, JsValue::is_string)
}
LogicalOperator::Or => {
shortcircuit_if_known(list, JsValue::is_falsy, JsValue::is_string)
}
LogicalOperator::NullishCoalescing => {
shortcircuit_if_known(list, JsValue::is_not_nullish, JsValue::is_string)
}
},
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => merge_if_known(values, JsValue::is_string),
JsValue::Call(
_,
box JsValue::WellKnownFunction(
WellKnownFunctionKind::RequireResolve
| WellKnownFunctionKind::PathJoin
| WellKnownFunctionKind::PathResolve(..)
| WellKnownFunctionKind::OsArch
| WellKnownFunctionKind::OsPlatform
| WellKnownFunctionKind::PathDirname
| WellKnownFunctionKind::PathToFileUrl
| WellKnownFunctionKind::ProcessCwd,
),
_,
) => Some(true),
JsValue::Awaited(_, operand) => match &**operand {
JsValue::Promise(_, v) => v.is_string(),
v => v.is_string(),
},
JsValue::FreeVar(..)
| JsValue::Variable(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..)
| JsValue::New(..)
| JsValue::Call(..)
| JsValue::MemberCall(..)
| JsValue::Member(..)
| JsValue::Tenary(..)
| JsValue::SuperCall(..)
| JsValue::Iterated(..) => None,
}
}
/// Checks if we know that the value starts with a given string. Returns
/// None if we don't know. Returns Some if we know if or if not the
/// value starts with the given string.
pub fn starts_with(&self, str: &str) -> Option<bool> {
if let Some(s) = self.as_str() {
return Some(s.starts_with(str));
}
match self {
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => merge_if_known(values, |a| a.starts_with(str)),
JsValue::Concat(_, list) => {
if let Some(item) = list.iter().next() {
if item.starts_with(str) == Some(true) {
Some(true)
} else if let Some(s) = item.as_str() {
if str.starts_with(s) {
None
} else {
Some(false)
}
} else {
None
}
} else {
Some(false)
}
}
_ => None,
}
}
/// Checks if we know that the value ends with a given string. Returns
/// None if we don't know. Returns Some if we know if or if not the
/// value ends with the given string.
pub fn ends_with(&self, str: &str) -> Option<bool> {
if let Some(s) = self.as_str() {
return Some(s.ends_with(str));
}
match self {
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => merge_if_known(values, |alt| alt.ends_with(str)),
JsValue::Concat(_, list) => {
if let Some(item) = list.last() {
if item.ends_with(str) == Some(true) {
Some(true)
} else if let Some(s) = item.as_str() {
if str.ends_with(s) { None } else { Some(false) }
} else {
None
}
} else {
Some(false)
}
}
_ => None,
}
}
}
/// Compute the compile-time value of all elements of the list. If all evaluate
/// to the same value return that. Otherwise return None.
fn merge_if_known<T: Copy>(
list: impl IntoIterator<Item = T>,
func: impl Fn(T) -> Option<bool>,
) -> Option<bool> {
let mut current = None;
for item in list.into_iter().map(func) {
if item.is_some() {
if current.is_none() {
current = item;
} else if current != item {
return None;
}
} else {
return None;
}
}
current
}
/// Evaluates all elements of the list and returns Some(true) if all elements
/// are compile-time true. If any element is compile-time false, return
/// Some(false). Otherwise return None.
fn all_if_known<T: Copy>(
list: impl IntoIterator<Item = T>,
func: impl Fn(T) -> Option<bool>,
) -> Option<bool> {
let mut unknown = false;
for item in list.into_iter().map(func) {
match item {
Some(false) => return Some(false),
None => unknown = true,
_ => {}
}
}
if unknown { None } else { Some(true) }
}
/// Evaluates all elements of the list and returns Some(true) if any element is
/// compile-time true. If all elements are compile-time false, return
/// Some(false). Otherwise return None.
fn any_if_known<T: Copy>(
list: impl IntoIterator<Item = T>,
func: impl Fn(T) -> Option<bool>,
) -> Option<bool> {
all_if_known(list, |x| func(x).map(|x| !x)).map(|x| !x)
}
/// Selects the first element of the list where `use_item` is compile-time true.
/// For this element returns the result of `item_value`. Otherwise returns None.
fn shortcircuit_if_known<T: Copy>(
list: impl IntoIterator<Item = T>,
use_item: impl Fn(T) -> Option<bool>,
item_value: impl FnOnce(T) -> Option<bool>,
) -> Option<bool> {
let mut it = list.into_iter().peekable();
while let Some(item) = it.next() {
if it.peek().is_none() {
return item_value(item);
} else {
match use_item(item) {
Some(true) => return item_value(item),
None => return None,
_ => {}
}
}
}
None
}
/// Macro to visit all children of a node with an async function
macro_rules! for_each_children_async {
($value:expr, $visit_fn:expr, $($args:expr),+) => {
Ok(match &mut $value {
JsValue::Alternatives { total_nodes: _, values: list, logical_property: _ }
| JsValue::Concat(_, list)
| JsValue::Add(_, list)
| JsValue::Logical(_, _, list)
| JsValue::Array{ items: list, ..} => {
let mut modified = false;
for item in list.iter_mut() {
let (v, m) = $visit_fn(take(item), $($args),+).await?;
*item = v;
if m {
modified = true
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::Object{ parts, ..} => {
let mut modified = false;
for item in parts.iter_mut() {
match item {
ObjectPart::KeyValue(key, value) => {
let (v, m) = $visit_fn(take(key), $($args),+).await?;
*key = v;
if m {
modified = true
}
let (v, m) = $visit_fn(take(value), $($args),+).await?;
*value = v;
if m {
modified = true
}
}
ObjectPart::Spread(value) => {
let (v, m) = $visit_fn(take(value), $($args),+).await?;
*value = v;
if m {
modified = true
}
}
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::New(_, box callee, list) => {
let (new_callee, mut modified) = $visit_fn(take(callee), $($args),+).await?;
*callee = new_callee;
for item in list.iter_mut() {
let (v, m) = $visit_fn(take(item), $($args),+).await?;
*item = v;
if m {
modified = true
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::Call(_, box callee, list) => {
let (new_callee, mut modified) = $visit_fn(take(callee), $($args),+).await?;
*callee = new_callee;
for item in list.iter_mut() {
let (v, m) = $visit_fn(take(item), $($args),+).await?;
*item = v;
if m {
modified = true
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::SuperCall(_, list) => {
let mut modified = false;
for item in list.iter_mut() {
let (v, m) = $visit_fn(take(item), $($args),+).await?;
*item = v;
if m {
modified = true
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::MemberCall(_, box obj, box prop, list) => {
let (new_callee, m1) = $visit_fn(take(obj), $($args),+).await?;
*obj = new_callee;
let (new_member, m2) = $visit_fn(take(prop), $($args),+).await?;
*prop = new_member;
let mut modified = m1 || m2;
for item in list.iter_mut() {
let (v, m) = $visit_fn(take(item), $($args),+).await?;
*item = v;
if m {
modified = true
}
}
$value.update_total_nodes();
($value, modified)
}
JsValue::Function(_, _, box return_value) => {
let (new_return_value, modified) = $visit_fn(take(return_value), $($args),+).await?;
*return_value = new_return_value;
$value.update_total_nodes();
($value, modified)
}
JsValue::Not(_, box value) => {
let (new_value, modified) = $visit_fn(take(value), $($args),+).await?;
*value = new_value;
$value.update_total_nodes();
($value, modified)
}
JsValue::Binary(_, box a, _, box b) => {
let (v, m1) = $visit_fn(take(a), $($args),+).await?;
*a = v;
let (v, m2) = $visit_fn(take(b), $($args),+).await?;
*b = v;
$value.update_total_nodes();
($value, m1 || m2)
}
JsValue::Tenary(_, box test, box cons, box alt) => {
let (v, m1) = $visit_fn(take(test), $($args),+).await?;
*test = v;
let (v, m2) = $visit_fn(take(cons), $($args),+).await?;
*cons = v;
let (v, m3) = $visit_fn(take(alt), $($args),+).await?;
*alt = v;
$value.update_total_nodes();
($value, m1 || m2 || m3)
}
JsValue::Member(_, box obj, box prop) => {
let (v, m1) = $visit_fn(take(obj), $($args),+).await?;
*obj = v;
let (v, m2) = $visit_fn(take(prop), $($args),+).await?;
*prop = v;
$value.update_total_nodes();
($value, m1 || m2)
}
JsValue::Iterated(_, box operand)
| JsValue::TypeOf(_, box operand)
| JsValue::Promise(_, box operand)
| JsValue::Awaited(_, box operand) => {
let (new_operand, modified) = $visit_fn(take(operand), $($args),+).await?;
*operand = new_operand;
$value.update_total_nodes();
($value, modified)
}
JsValue::Constant(_)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::Url(_, _)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..) => ($value, false),
})
}
}
// Visiting
impl JsValue {
/// Visit the node and all its children with a function in a loop until the
/// visitor returns false for the node and all children
pub async fn visit_async_until_settled<'a, F, R, E>(
self,
visitor: &mut F,
) -> Result<(Self, bool), E>
where
R: 'a + Future<Output = Result<(Self, bool), E>> + Send,
F: 'a + FnMut(JsValue) -> R + Send,
{
let mut modified = false;
let mut v = self;
loop {
let m;
(v, m) = visitor(take(&mut v)).await?;
if !m {
break;
}
modified = true;
v = take(&mut v)
.visit_each_children_async_until_settled(visitor)
.await?;
}
Ok((v, modified))
}
/// Visit all children of the node with an async function in a loop until
/// the visitor returns false
pub async fn visit_each_children_async_until_settled<'a, F, R, E>(
mut self,
visitor: &mut F,
) -> Result<Self, E>
where
R: 'a + Future<Output = Result<(Self, bool), E>> + Send,
F: 'a + FnMut(JsValue) -> R + Send,
{
fn visit_async_until_settled_box<'a, F, R, E>(
value: JsValue,
visitor: &'a mut F,
) -> PinnedAsyncUntilSettledBox<'a, E>
where
R: 'a + Future<Output = Result<(JsValue, bool), E>> + Send,
F: 'a + FnMut(JsValue) -> R + Send,
E: 'a,
{
Box::pin(value.visit_async_until_settled(visitor))
}
let (v, _) = for_each_children_async!(self, visit_async_until_settled_box, visitor)?;
Ok(v)
}
/// Visit the node and all its children with an async function.
pub async fn visit_async<'a, F, R, E>(self, visitor: &mut F) -> Result<(Self, bool), E>
where
R: 'a + Future<Output = Result<(Self, bool), E>>,
F: 'a + FnMut(JsValue) -> R,
{
let (v, modified) = self.visit_each_children_async(visitor).await?;
let (v, m) = visitor(v).await?;
if m { Ok((v, true)) } else { Ok((v, modified)) }
}
/// Visit all children of the node with an async function.
pub async fn visit_each_children_async<'a, F, R, E>(
mut self,
visitor: &mut F,
) -> Result<(Self, bool), E>
where
R: 'a + Future<Output = Result<(Self, bool), E>>,
F: 'a + FnMut(JsValue) -> R,
{
fn visit_async_box<'a, F, R, E>(value: JsValue, visitor: &'a mut F) -> PinnedAsyncBox<'a, E>
where
R: 'a + Future<Output = Result<(JsValue, bool), E>>,
F: 'a + FnMut(JsValue) -> R,
E: 'a,
{
Box::pin(value.visit_async(visitor))
}
for_each_children_async!(self, visit_async_box, visitor)
}
/// Call an async function for each child of the node.
pub async fn for_each_children_async<'a, F, R, E>(
mut self,
visitor: &mut F,
) -> Result<(Self, bool), E>
where
R: 'a + Future<Output = Result<(Self, bool), E>>,
F: 'a + FnMut(JsValue) -> R,
{
for_each_children_async!(self, |v, ()| visitor(v), ())
}
/// Visit the node and all its children with a function in a loop until the
/// visitor returns false
pub fn visit_mut_until_settled(&mut self, visitor: &mut impl FnMut(&mut JsValue) -> bool) {
while visitor(self) {
self.for_each_children_mut(&mut |value| {
value.visit_mut_until_settled(visitor);
false
});
}
}
/// Visit the node and all its children with a function.
pub fn visit_mut(&mut self, visitor: &mut impl FnMut(&mut JsValue) -> bool) -> bool {
let modified = self.for_each_children_mut(&mut |value| value.visit_mut(visitor));
if visitor(self) { true } else { modified }
}
/// Visit all children of the node with a function. Only visits nodes where
/// the condition is true.
pub fn visit_mut_conditional(
&mut self,
condition: impl Fn(&JsValue) -> bool,
visitor: &mut impl FnMut(&mut JsValue) -> bool,
) -> bool {
if condition(self) {
let modified = self.for_each_children_mut(&mut |value| value.visit_mut(visitor));
if visitor(self) { true } else { modified }
} else {
false
}
}
/// Calls a function for each child of the node. Allows mutating the node.
/// Updates the total nodes count after mutation.
pub fn for_each_children_mut(
&mut self,
visitor: &mut impl FnMut(&mut JsValue) -> bool,
) -> bool {
match self {
JsValue::Alternatives {
total_nodes: _,
values: list,
logical_property: _,
}
| JsValue::Concat(_, list)
| JsValue::Add(_, list)
| JsValue::Logical(_, _, list)
| JsValue::Array { items: list, .. } => {
let mut modified = false;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Not(_, value) => {
let modified = visitor(value);
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Object { parts, .. } => {
let mut modified = false;
for item in parts.iter_mut() {
match item {
ObjectPart::KeyValue(key, value) => {
if visitor(key) {
modified = true
}
if visitor(value) {
modified = true
}
}
ObjectPart::Spread(value) => {
if visitor(value) {
modified = true
}
}
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::New(_, callee, list) => {
let mut modified = visitor(callee);
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Call(_, callee, list) => {
let mut modified = visitor(callee);
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::SuperCall(_, list) => {
let mut modified = false;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::MemberCall(_, obj, prop, list) => {
let m1 = visitor(obj);
let m2 = visitor(prop);
let mut modified = m1 || m2;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Function(_, _, return_value) => {
let modified = visitor(return_value);
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Binary(_, a, _, b) => {
let m1 = visitor(a);
let m2 = visitor(b);
let modified = m1 || m2;
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Tenary(_, test, cons, alt) => {
let m1 = visitor(test);
let m2 = visitor(cons);
let m3 = visitor(alt);
let modified = m1 || m2 || m3;
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Member(_, obj, prop) => {
let m1 = visitor(obj);
let m2 = visitor(prop);
let modified = m1 || m2;
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Iterated(_, operand)
| JsValue::TypeOf(_, operand)
| JsValue::Promise(_, operand)
| JsValue::Awaited(_, operand) => {
let modified = visitor(operand);
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Constant(_)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::Url(_, _)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..) => false,
}
}
/// Calls a function for only early children. Allows mutating the
/// node. Updates the total nodes count after mutation.
pub fn for_each_early_children_mut(
&mut self,
visitor: &mut impl FnMut(&mut JsValue) -> bool,
) -> bool {
match self {
JsValue::New(_, callee, list) if !list.is_empty() => {
let m = visitor(callee);
if m {
self.update_total_nodes();
}
m
}
JsValue::Call(_, callee, list) if !list.is_empty() => {
let m = visitor(callee);
if m {
self.update_total_nodes();
}
m
}
JsValue::MemberCall(_, obj, prop, list) if !list.is_empty() => {
let m1 = visitor(obj);
let m2 = visitor(prop);
let modified = m1 || m2;
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Member(_, obj, _) => {
let m = visitor(obj);
if m {
self.update_total_nodes();
}
m
}
_ => false,
}
}
/// Calls a function for only late children. Allows mutating the
/// node. Updates the total nodes count after mutation.
pub fn for_each_late_children_mut(
&mut self,
visitor: &mut impl FnMut(&mut JsValue) -> bool,
) -> bool {
match self {
JsValue::New(_, _, list) if !list.is_empty() => {
let mut modified = false;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Call(_, _, list) if !list.is_empty() => {
let mut modified = false;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::MemberCall(_, _, _, list) if !list.is_empty() => {
let mut modified = false;
for item in list.iter_mut() {
if visitor(item) {
modified = true
}
}
if modified {
self.update_total_nodes();
}
modified
}
JsValue::Member(_, _, prop) => {
let m = visitor(prop);
if m {
self.update_total_nodes();
}
m
}
_ => self.for_each_children_mut(visitor),
}
}
/// Visit the node and all its children with a function.
pub fn visit(&self, visitor: &mut impl FnMut(&JsValue)) {
self.for_each_children(&mut |value| value.visit(visitor));
visitor(self);
}
/// Calls a function for all children of the node.
pub fn for_each_children(&self, visitor: &mut impl FnMut(&JsValue)) {
match self {
JsValue::Alternatives {
total_nodes: _,
values: list,
logical_property: _,
}
| JsValue::Concat(_, list)
| JsValue::Add(_, list)
| JsValue::Logical(_, _, list)
| JsValue::Array { items: list, .. } => {
for item in list.iter() {
visitor(item);
}
}
JsValue::Not(_, value) => {
visitor(value);
}
JsValue::Object { parts, .. } => {
for item in parts.iter() {
match item {
ObjectPart::KeyValue(key, value) => {
visitor(key);
visitor(value);
}
ObjectPart::Spread(value) => {
visitor(value);
}
}
}
}
JsValue::New(_, callee, list) => {
visitor(callee);
for item in list.iter() {
visitor(item);
}
}
JsValue::Call(_, callee, list) => {
visitor(callee);
for item in list.iter() {
visitor(item);
}
}
JsValue::SuperCall(_, list) => {
for item in list.iter() {
visitor(item);
}
}
JsValue::MemberCall(_, obj, prop, list) => {
visitor(obj);
visitor(prop);
for item in list.iter() {
visitor(item);
}
}
JsValue::Function(_, _, return_value) => {
visitor(return_value);
}
JsValue::Member(_, obj, prop) => {
visitor(obj);
visitor(prop);
}
JsValue::Binary(_, a, _, b) => {
visitor(a);
visitor(b);
}
JsValue::Tenary(_, test, cons, alt) => {
visitor(test);
visitor(cons);
visitor(alt);
}
JsValue::Iterated(_, operand)
| JsValue::TypeOf(_, operand)
| JsValue::Promise(_, operand)
| JsValue::Awaited(_, operand) => {
visitor(operand);
}
JsValue::Constant(_)
| JsValue::FreeVar(_)
| JsValue::Variable(_)
| JsValue::Module(..)
| JsValue::Url(_, _)
| JsValue::WellKnownObject(_)
| JsValue::WellKnownFunction(_)
| JsValue::Unknown { .. }
| JsValue::Argument(..) => {}
}
}
}
// Alternatives management
impl JsValue {
/// Add an alternative to the current value. Might be a no-op if the value
/// already contains this alternative. Potentially expensive operation
/// as it has to compare the value with all existing alternatives.
fn add_alt(&mut self, v: Self) {
if self == &v {
return;
}
if let JsValue::Alternatives {
total_nodes: c,
values,
logical_property: _,
} = self
{
if !values.contains(&v) {
*c += v.total_nodes();
values.push(v);
}
} else {
let l = take(self);
*self = JsValue::Alternatives {
total_nodes: 1 + l.total_nodes() + v.total_nodes(),
values: vec![l, v],
logical_property: None,
};
}
}
}
// Normalization
impl JsValue {
/// Normalizes only the current node. Nested alternatives, concatenations,
/// or operations are collapsed.
pub fn normalize_shallow(&mut self) {
match self {
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => {
if values.len() == 1 {
*self = take(&mut values[0]);
} else {
let mut set = FxIndexSet::with_capacity_and_hasher(
values.len(),
BuildHasherDefault::<FxHasher>::default(),
);
for v in take(values) {
match v {
JsValue::Alternatives {
total_nodes: _,
values,
logical_property: _,
} => {
for v in values {
set.insert(SimilarJsValue(v));
}
}
v => {
set.insert(SimilarJsValue(v));
}
}
}
if set.len() == 1 {
*self = set.into_iter().next().unwrap().0;
} else {
*values = set.into_iter().map(|v| v.0).collect();
self.update_total_nodes();
}
}
}
JsValue::Concat(_, v) => {
// Remove empty strings
v.retain(|v| v.as_str() != Some(""));
// TODO(kdy1): Remove duplicate
let mut new: Vec<JsValue> = vec![];
for v in take(v) {
if let Some(str) = v.as_str() {
if let Some(last) = new.last_mut() {
if let Some(last_str) = last.as_str() {
*last = [last_str, str].concat().into();
} else {
new.push(v);
}
} else {
new.push(v);
}
} else if let JsValue::Concat(_, v) = v {
new.extend(v);
} else {
new.push(v);
}
}
if new.len() == 1 {
*self = new.into_iter().next().unwrap();
} else {
*v = new;
self.update_total_nodes();
}
}
JsValue::Add(_, v) => {
let mut added: Vec<JsValue> = Vec::new();
let mut iter = take(v).into_iter();
while let Some(item) = iter.next() {
if item.is_string() == Some(true) {
let mut concat = match added.len() {
0 => Vec::new(),
1 => vec![added.into_iter().next().unwrap()],
_ => vec![JsValue::Add(
1 + added.iter().map(|v| v.total_nodes()).sum::<u32>(),
added,
)],
};
concat.push(item);
for item in iter.by_ref() {
concat.push(item);
}
*self = JsValue::Concat(
1 + concat.iter().map(|v| v.total_nodes()).sum::<u32>(),
concat,
);
return;
} else {
added.push(item);
}
}
if added.len() == 1 {
*self = added.into_iter().next().unwrap();
} else {
*v = added;
self.update_total_nodes();
}
}
JsValue::Logical(_, op, list) => {
// Nested logical expressions can be normalized: e. g. `a && (b && c)` => `a &&
// b && c`
if list.iter().any(|v| {
if let JsValue::Logical(_, inner_op, _) = v {
inner_op == op
} else {
false
}
}) {
// Taking the old list and constructing a new merged list
for mut v in take(list).into_iter() {
if let JsValue::Logical(_, inner_op, inner_list) = &mut v {
if inner_op == op {
list.append(inner_list);
} else {
list.push(v);
}
} else {
list.push(v);
}
}
self.update_total_nodes();
}
}
_ => {}
}
}
/// Normalizes the current node and all nested nodes.
pub fn normalize(&mut self) {
self.for_each_children_mut(&mut |child| {
child.normalize();
true
});
self.normalize_shallow();
}
}
// Similarity
// Like equality, but with depth limit
impl JsValue {
/// Check if the values are equal up to the given depth. Might return false
/// even if the values are equal when hitting the depth limit.
fn similar(&self, other: &JsValue, depth: usize) -> bool {
if depth == 0 {
return false;
}
fn all_similar(a: &[JsValue], b: &[JsValue], depth: usize) -> bool {
if a.len() != b.len() {
return false;
}
a.iter().zip(b.iter()).all(|(a, b)| a.similar(b, depth))
}
fn all_parts_similar(a: &[ObjectPart], b: &[ObjectPart], depth: usize) -> bool {
if a.len() != b.len() {
return false;
}
a.iter().zip(b.iter()).all(|(a, b)| match (a, b) {
(ObjectPart::KeyValue(lk, lv), ObjectPart::KeyValue(rk, rv)) => {
lk.similar(rk, depth) && lv.similar(rv, depth)
}
(ObjectPart::Spread(l), ObjectPart::Spread(r)) => l.similar(r, depth),
_ => false,
})
}
match (self, other) {
(JsValue::Constant(l), JsValue::Constant(r)) => l == r,
(
JsValue::Array {
total_nodes: lc,
items: li,
mutable: lm,
},
JsValue::Array {
total_nodes: rc,
items: ri,
mutable: rm,
},
) => lc == rc && lm == rm && all_similar(li, ri, depth - 1),
(
JsValue::Object {
total_nodes: lc,
parts: lp,
mutable: lm,
},
JsValue::Object {
total_nodes: rc,
parts: rp,
mutable: rm,
},
) => lc == rc && lm == rm && all_parts_similar(lp, rp, depth - 1),
(JsValue::Url(l, kl), JsValue::Url(r, kr)) => l == r && kl == kr,
(
JsValue::Alternatives {
total_nodes: lc,
values: l,
logical_property: lp,
},
JsValue::Alternatives {
total_nodes: rc,
values: r,
logical_property: rp,
},
) => lc == rc && all_similar(l, r, depth - 1) && lp == rp,
(JsValue::FreeVar(l), JsValue::FreeVar(r)) => l == r,
(JsValue::Variable(l), JsValue::Variable(r)) => l == r,
(JsValue::Concat(lc, l), JsValue::Concat(rc, r)) => {
lc == rc && all_similar(l, r, depth - 1)
}
(JsValue::Add(lc, l), JsValue::Add(rc, r)) => lc == rc && all_similar(l, r, depth - 1),
(JsValue::Logical(lc, lo, l), JsValue::Logical(rc, ro, r)) => {
lc == rc && lo == ro && all_similar(l, r, depth - 1)
}
(JsValue::Not(lc, l), JsValue::Not(rc, r)) => lc == rc && l.similar(r, depth - 1),
(JsValue::New(lc, lf, la), JsValue::New(rc, rf, ra)) => {
lc == rc && lf.similar(rf, depth - 1) && all_similar(la, ra, depth - 1)
}
(JsValue::Call(lc, lf, la), JsValue::Call(rc, rf, ra)) => {
lc == rc && lf.similar(rf, depth - 1) && all_similar(la, ra, depth - 1)
}
(JsValue::MemberCall(lc, lo, lp, la), JsValue::MemberCall(rc, ro, rp, ra)) => {
lc == rc
&& lo.similar(ro, depth - 1)
&& lp.similar(rp, depth - 1)
&& all_similar(la, ra, depth - 1)
}
(JsValue::Member(lc, lo, lp), JsValue::Member(rc, ro, rp)) => {
lc == rc && lo.similar(ro, depth - 1) && lp.similar(rp, depth - 1)
}
(JsValue::Binary(lc, la, lo, lb), JsValue::Binary(rc, ra, ro, rb)) => {
lc == rc && lo == ro && la.similar(ra, depth - 1) && lb.similar(rb, depth - 1)
}
(
JsValue::Module(ModuleValue {
module: l,
annotations: la,
}),
JsValue::Module(ModuleValue {
module: r,
annotations: ra,
}),
) => l == r && la == ra,
(JsValue::WellKnownObject(l), JsValue::WellKnownObject(r)) => l == r,
(JsValue::WellKnownFunction(l), JsValue::WellKnownFunction(r)) => l == r,
(
JsValue::Unknown {
original_value: _,
reason: l,
has_side_effects: ls,
},
JsValue::Unknown {
original_value: _,
reason: r,
has_side_effects: rs,
},
) => l == r && ls == rs,
(JsValue::Function(lc, _, l), JsValue::Function(rc, _, r)) => {
lc == rc && l.similar(r, depth - 1)
}
(JsValue::Argument(li, l), JsValue::Argument(ri, r)) => li == ri && l == r,
_ => false,
}
}
/// Hashes the value up to the given depth.
fn similar_hash<H: std::hash::Hasher>(&self, state: &mut H, depth: usize) {
if depth == 0 {
self.total_nodes().hash(state);
return;
}
fn all_similar_hash<H: std::hash::Hasher>(slice: &[JsValue], state: &mut H, depth: usize) {
for item in slice {
item.similar_hash(state, depth);
}
}
fn all_parts_similar_hash<H: std::hash::Hasher>(
slice: &[ObjectPart],
state: &mut H,
depth: usize,
) {
for item in slice {
match item {
ObjectPart::KeyValue(key, value) => {
key.similar_hash(state, depth);
value.similar_hash(state, depth);
}
ObjectPart::Spread(value) => {
value.similar_hash(state, depth);
}
}
}
}
match self {
JsValue::Constant(v) => Hash::hash(v, state),
JsValue::Object { parts, .. } => all_parts_similar_hash(parts, state, depth - 1),
JsValue::Url(v, kind) => {
Hash::hash(v, state);
Hash::hash(kind, state);
}
JsValue::FreeVar(v) => Hash::hash(v, state),
JsValue::Variable(v) => Hash::hash(v, state),
JsValue::Array { items: v, .. }
| JsValue::Alternatives {
total_nodes: _,
values: v,
logical_property: _,
}
| JsValue::Concat(_, v)
| JsValue::Add(_, v)
| JsValue::Logical(_, _, v) => all_similar_hash(v, state, depth - 1),
JsValue::Not(_, v) => v.similar_hash(state, depth - 1),
JsValue::New(_, a, b) => {
a.similar_hash(state, depth - 1);
all_similar_hash(b, state, depth - 1);
}
JsValue::Call(_, a, b) => {
a.similar_hash(state, depth - 1);
all_similar_hash(b, state, depth - 1);
}
JsValue::SuperCall(_, a) => {
all_similar_hash(a, state, depth - 1);
}
JsValue::MemberCall(_, a, b, c) => {
a.similar_hash(state, depth - 1);
b.similar_hash(state, depth - 1);
all_similar_hash(c, state, depth - 1);
}
JsValue::Member(_, o, p) => {
o.similar_hash(state, depth - 1);
p.similar_hash(state, depth - 1);
}
JsValue::Binary(_, a, o, b) => {
a.similar_hash(state, depth - 1);
o.hash(state);
b.similar_hash(state, depth - 1);
}
JsValue::Tenary(_, test, cons, alt) => {
test.similar_hash(state, depth - 1);
cons.similar_hash(state, depth - 1);
alt.similar_hash(state, depth - 1);
}
JsValue::Iterated(_, operand)
| JsValue::TypeOf(_, operand)
| JsValue::Promise(_, operand)
| JsValue::Awaited(_, operand) => {
operand.similar_hash(state, depth - 1);
}
JsValue::Module(ModuleValue {
module: v,
annotations: a,
}) => {
Hash::hash(v, state);
Hash::hash(a, state);
}
JsValue::WellKnownObject(v) => Hash::hash(v, state),
JsValue::WellKnownFunction(v) => Hash::hash(v, state),
JsValue::Unknown {
original_value: _,
reason: v,
has_side_effects,
} => {
Hash::hash(v, state);
Hash::hash(has_side_effects, state);
}
JsValue::Function(_, _, v) => v.similar_hash(state, depth - 1),
JsValue::Argument(i, v) => {
Hash::hash(i, state);
Hash::hash(v, state);
}
}
}
}
/// The depth to use when comparing values for similarity.
const SIMILAR_EQ_DEPTH: usize = 3;
/// The depth to use when hashing values for similarity.
const SIMILAR_HASH_DEPTH: usize = 2;
/// A wrapper around `JsValue` that implements `PartialEq` and `Hash` by
/// comparing the values with a depth of [SIMILAR_EQ_DEPTH] and hashing values
/// with a depth of [SIMILAR_HASH_DEPTH].
struct SimilarJsValue(JsValue);
impl PartialEq for SimilarJsValue {
fn eq(&self, other: &Self) -> bool {
self.0.similar(&other.0, SIMILAR_EQ_DEPTH)
}
}
impl Eq for SimilarJsValue {}
impl Hash for SimilarJsValue {
fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
self.0.similar_hash(state, SIMILAR_HASH_DEPTH)
}
}
/// A list of well-known objects that have special meaning in the analysis.
#[derive(Debug, Clone, Hash, PartialEq, Eq)]
pub enum WellKnownObjectKind {
GlobalObject,
PathModule,
PathModuleDefault,
FsModule,
FsModuleDefault,
FsModulePromises,
UrlModule,
UrlModuleDefault,
ChildProcess,
ChildProcessDefault,
OsModule,
OsModuleDefault,
NodeProcess,
NodeProcessArgv,
NodeProcessEnv,
NodePreGyp,
NodeExpressApp,
NodeProtobufLoader,
NodeBuffer,
RequireCache,
ImportMeta,
}
impl WellKnownObjectKind {
pub fn as_define_name(&self) -> Option<&[&str]> {
match self {
Self::GlobalObject => Some(&["global"]),
Self::PathModule => Some(&["path"]),
Self::FsModule => Some(&["fs"]),
Self::UrlModule => Some(&["url"]),
Self::ChildProcess => Some(&["child_process"]),
Self::OsModule => Some(&["os"]),
Self::NodeProcess => Some(&["process"]),
Self::NodeProcessArgv => Some(&["process", "argv"]),
Self::NodeProcessEnv => Some(&["process", "env"]),
Self::NodeBuffer => Some(&["Buffer"]),
Self::RequireCache => Some(&["require", "cache"]),
Self::ImportMeta => Some(&["import", "meta"]),
_ => None,
}
}
}
#[derive(Debug, Clone)]
pub struct RequireContextOptions {
pub dir: RcStr,
pub include_subdirs: bool,
/// this is a regex (pattern, flags)
pub filter: EsRegex,
}
/// Parse the arguments passed to a require.context invocation, validate them
/// and convert them to the appropriate rust values.
pub fn parse_require_context(args: &[JsValue]) -> Result<RequireContextOptions> {
if !(1..=3).contains(&args.len()) {
// https://linear.app/vercel/issue/WEB-910/add-support-for-requirecontexts-mode-argument
bail!("require.context() only supports 1-3 arguments (mode is not supported)");
}
let Some(dir) = args[0].as_str().map(|s| s.into()) else {
bail!("require.context(dir, ...) requires dir to be a constant string");
};
let include_subdirs = if let Some(include_subdirs) = args.get(1) {
if let Some(include_subdirs) = include_subdirs.as_bool() {
include_subdirs
} else {
bail!(
"require.context(..., includeSubdirs, ...) requires includeSubdirs to be a \
constant boolean",
);
}
} else {
true
};
let filter = if let Some(filter) = args.get(2) {
if let JsValue::Constant(ConstantValue::Regex(box (pattern, flags))) = filter {
EsRegex::new(pattern, flags)?
} else {
bail!("require.context(..., ..., filter) requires filter to be a regex");
}
} else {
// https://webpack.js.org/api/module-methods/#requirecontext
// > optional, default /^\.\/.*$/, any file
static DEFAULT_REGEX: Lazy<EsRegex> = Lazy::new(|| EsRegex::new(r"^\\./.*$", "").unwrap());
DEFAULT_REGEX.clone()
};
Ok(RequireContextOptions {
dir,
include_subdirs,
filter,
})
}
#[derive(Debug, Clone, Eq, PartialEq)]
pub struct RequireContextValue(FxIndexMap<RcStr, RcStr>);
impl RequireContextValue {
pub async fn from_context_map(map: Vc<RequireContextMap>) -> Result<Self> {
let mut context_map = FxIndexMap::default();
for (key, entry) in map.await?.iter() {
context_map.insert(key.clone(), entry.origin_relative.clone());
}
Ok(RequireContextValue(context_map))
}
}
impl Hash for RequireContextValue {
fn hash<H: Hasher>(&self, state: &mut H) {
self.0.len().hash(state);
for (i, (k, v)) in self.0.iter().enumerate() {
i.hash(state);
k.hash(state);
v.hash(state);
}
}
}
/// A list of well-known functions that have special meaning in the analysis.
#[derive(Debug, Clone, Hash, PartialEq, Eq)]
pub enum WellKnownFunctionKind {
ObjectAssign,
PathJoin,
PathDirname,
/// `0` is the current working directory.
PathResolve(Box<JsValue>),
Import,
Require,
RequireResolve,
RequireContext,
RequireContextRequire(RequireContextValue),
RequireContextRequireKeys(RequireContextValue),
RequireContextRequireResolve(RequireContextValue),
Define,
FsReadMethod(Atom),
PathToFileUrl,
ChildProcessSpawnMethod(Atom),
ChildProcessFork,
OsArch,
OsPlatform,
OsEndianness,
ProcessCwd,
NodePreGypFind,
NodeGypBuild,
NodeBindings,
NodeExpress,
NodeExpressSet,
NodeStrongGlobalize,
NodeStrongGlobalizeSetRootDir,
NodeResolveFrom,
NodeProtobufLoad,
WorkerConstructor,
URLConstructor,
}
impl WellKnownFunctionKind {
pub fn as_define_name(&self) -> Option<&[&str]> {
match self {
Self::Import { .. } => Some(&["import"]),
Self::Require { .. } => Some(&["require"]),
Self::RequireResolve => Some(&["require", "resolve"]),
Self::RequireContext => Some(&["require", "context"]),
Self::Define => Some(&["define"]),
_ => None,
}
}
}
fn is_unresolved(i: &Ident, unresolved_mark: Mark) -> bool {
i.ctxt.outer() == unresolved_mark
}
fn is_unresolved_id(i: &Id, unresolved_mark: Mark) -> bool {
i.1.outer() == unresolved_mark
}
#[doc(hidden)]
pub mod test_utils {
use anyhow::Result;
use turbo_rcstr::rcstr;
use turbo_tasks::{FxIndexMap, Vc};
use turbopack_core::{compile_time_info::CompileTimeInfo, error::PrettyPrintError};
use super::{
ConstantValue, JsValue, JsValueUrlKind, ModuleValue, WellKnownFunctionKind,
WellKnownObjectKind, builtin::early_replace_builtin, well_known::replace_well_known,
};
use crate::{
analyzer::{
RequireContextValue,
builtin::replace_builtin,
imports::{ImportAnnotations, ImportAttributes},
parse_require_context,
},
utils::module_value_to_well_known_object,
};
pub async fn early_visitor(mut v: JsValue) -> Result<(JsValue, bool)> {
let m = early_replace_builtin(&mut v);
Ok((v, m))
}
/// Visitor that replaces well known functions and objects with their
/// corresponding values. Returns the new value and whether it was modified.
pub async fn visitor(
v: JsValue,
compile_time_info: Vc<CompileTimeInfo>,
attributes: &ImportAttributes,
) -> Result<(JsValue, bool)> {
let ImportAttributes { ignore, .. } = *attributes;
let mut new_value = match v {
JsValue::Call(
_,
box JsValue::WellKnownFunction(WellKnownFunctionKind::Import),
ref args,
) => match &args[0] {
JsValue::Constant(ConstantValue::Str(v)) => {
JsValue::promise(Box::new(JsValue::Module(ModuleValue {
module: v.as_atom().into_owned(),
annotations: ImportAnnotations::default(),
})))
}
_ => v.into_unknown(true, "import() non constant"),
},
JsValue::Call(
_,
box JsValue::WellKnownFunction(WellKnownFunctionKind::RequireResolve),
ref args,
) => match &args[0] {
JsValue::Constant(v) => (v.to_string() + "/resolved/lib/index.js").into(),
_ => v.into_unknown(true, "require.resolve non constant"),
},
JsValue::Call(
_,
box JsValue::WellKnownFunction(WellKnownFunctionKind::RequireContext),
ref args,
) => match parse_require_context(args) {
Ok(options) => {
let mut map = FxIndexMap::default();
map.insert(
rcstr!("./a"),
format!("[context: {}]/a", options.dir).into(),
);
map.insert(
rcstr!("./b"),
format!("[context: {}]/b", options.dir).into(),
);
map.insert(
rcstr!("./c"),
format!("[context: {}]/c", options.dir).into(),
);
JsValue::WellKnownFunction(WellKnownFunctionKind::RequireContextRequire(
RequireContextValue(map),
))
}
Err(err) => v.into_unknown(true, PrettyPrintError(&err).to_string()),
},
JsValue::New(
_,
box JsValue::WellKnownFunction(WellKnownFunctionKind::URLConstructor),
ref args,
) => {
if let [
JsValue::Constant(ConstantValue::Str(url)),
JsValue::Member(
_,
box JsValue::WellKnownObject(WellKnownObjectKind::ImportMeta),
box JsValue::Constant(ConstantValue::Str(prop)),
),
] = &args[..]
{
if prop.as_str() == "url" {
// TODO avoid clone
JsValue::Url(url.clone(), JsValueUrlKind::Relative)
} else {
v.into_unknown(true, "new non constant")
}
} else {
v.into_unknown(true, "new non constant")
}
}
JsValue::FreeVar(ref var) => match &**var {
"__dirname" => "__dirname".into(),
"__filename" => "__filename".into(),
"require" => JsValue::unknown_if(
ignore,
JsValue::WellKnownFunction(WellKnownFunctionKind::Require),
true,
"ignored require",
),
"import" => JsValue::unknown_if(
ignore,
JsValue::WellKnownFunction(WellKnownFunctionKind::Import),
true,
"ignored import",
),
"Worker" => JsValue::unknown_if(
ignore,
JsValue::WellKnownFunction(WellKnownFunctionKind::WorkerConstructor),
true,
"ignored Worker constructor",
),
"define" => JsValue::WellKnownFunction(WellKnownFunctionKind::Define),
"URL" => JsValue::WellKnownFunction(WellKnownFunctionKind::URLConstructor),
"process" => JsValue::WellKnownObject(WellKnownObjectKind::NodeProcess),
"Object" => JsValue::WellKnownObject(WellKnownObjectKind::GlobalObject),
"Buffer" => JsValue::WellKnownObject(WellKnownObjectKind::NodeBuffer),
_ => v.into_unknown(true, "unknown global"),
},
JsValue::Module(ref mv) => {
if let Some(wko) = module_value_to_well_known_object(mv) {
wko
} else {
return Ok((v, false));
}
}
_ => {
let (mut v, m1) = replace_well_known(v, compile_time_info).await?;
let m2 = replace_builtin(&mut v);
let m = m1 || m2 || v.make_nested_operations_unknown();
return Ok((v, m));
}
};
new_value.normalize_shallow();
Ok((new_value, true))
}
}
#[cfg(test)]
mod tests {
use std::{mem::take, path::PathBuf, time::Instant};
use parking_lot::Mutex;
use rustc_hash::FxHashMap;
use swc_core::{
common::{Mark, comments::SingleThreadedComments},
ecma::{
ast::{EsVersion, Id},
parser::parse_file_as_program,
transforms::base::resolver,
visit::VisitMutWith,
},
testing::{NormalizedOutput, fixture, run_test},
};
use turbo_tasks::{ResolvedVc, util::FormatDuration};
use turbopack_core::{
compile_time_info::CompileTimeInfo,
environment::{Environment, ExecutionEnvironment, NodeJsEnvironment, NodeJsVersion},
target::{Arch, CompileTarget, Endianness, Libc, Platform},
};
use super::{
JsValue,
graph::{ConditionalKind, Effect, EffectArg, EvalContext, VarGraph, create_graph},
linker::link,
};
use crate::analyzer::imports::ImportAttributes;
#[fixture("tests/analyzer/graph/**/input.js")]
fn fixture(input: PathBuf) {
crate::register();
let graph_snapshot_path = input.with_file_name("graph.snapshot");
let graph_explained_snapshot_path = input.with_file_name("graph-explained.snapshot");
let graph_effects_snapshot_path = input.with_file_name("graph-effects.snapshot");
let resolved_explained_snapshot_path = input.with_file_name("resolved-explained.snapshot");
let resolved_effects_snapshot_path = input.with_file_name("resolved-effects.snapshot");
let large_marker = input.with_file_name("large");
run_test(false, |cm, handler| {
let r = tokio::runtime::Builder::new_current_thread()
.build()
.unwrap();
r.block_on(async move {
let fm = cm.load_file(&input).unwrap();
let comments = SingleThreadedComments::default();
let mut m = parse_file_as_program(
&fm,
Default::default(),
EsVersion::latest(),
Some(&comments),
&mut vec![],
)
.map_err(|err| err.into_diagnostic(handler).emit())?;
let unresolved_mark = Mark::new();
let top_level_mark = Mark::new();
m.visit_mut_with(&mut resolver(unresolved_mark, top_level_mark, false));
let eval_context = EvalContext::new(
&m,
unresolved_mark,
top_level_mark,
Default::default(),
Some(&comments),
None,
);
let mut var_graph = create_graph(&m, &eval_context);
let var_cache = Default::default();
let mut named_values = var_graph
.values
.clone()
.into_iter()
.map(|((id, ctx), value)| {
let unique = var_graph.values.keys().filter(|(i, _)| &id == i).count() == 1;
if unique {
(id.to_string(), ((id, ctx), value))
} else {
(format!("{id}{ctx:?}"), ((id, ctx), value))
}
})
.collect::<Vec<_>>();
named_values.sort_by(|a, b| a.0.cmp(&b.0));
fn explain_all<'a>(
values: impl IntoIterator<Item = (&'a String, &'a JsValue)>,
) -> String {
values
.into_iter()
.map(|(id, value)| {
let (explainer, hints) = value.explain(10, 5);
format!("{id} = {explainer}{hints}")
})
.collect::<Vec<_>>()
.join("\n\n")
}
{
// Dump snapshot of graph
let large = large_marker.exists();
if !large {
NormalizedOutput::from(format!(
"{:#?}",
named_values
.iter()
.map(|(name, (_, value))| (name, value))
.collect::<Vec<_>>()
))
.compare_to_file(&graph_snapshot_path)
.unwrap();
}
NormalizedOutput::from(explain_all(
named_values.iter().map(|(name, (_, value))| (name, value)),
))
.compare_to_file(&graph_explained_snapshot_path)
.unwrap();
if !large {
NormalizedOutput::from(format!("{:#?}", var_graph.effects))
.compare_to_file(&graph_effects_snapshot_path)
.unwrap();
}
}
{
// Dump snapshot of resolved
let start = Instant::now();
let mut resolved = Vec::new();
for (name, (id, _)) in named_values.iter().cloned() {
let start = Instant::now();
// Ideally this would use eval_context.imports.get_attributes(span), but the
// span isn't available here
let (res, steps) = resolve(
&var_graph,
JsValue::Variable(id),
ImportAttributes::empty_ref(),
&var_cache,
)
.await;
let time = start.elapsed();
if time.as_millis() > 1 {
println!(
"linking {} {name} took {} in {} steps",
input.display(),
FormatDuration(time),
steps
);
}
resolved.push((name, res));
}
let time = start.elapsed();
if time.as_millis() > 1 {
println!("linking {} took {}", input.display(), FormatDuration(time));
}
let start = Instant::now();
let explainer = explain_all(resolved.iter().map(|(name, value)| (name, value)));
let time = start.elapsed();
if time.as_millis() > 1 {
println!(
"explaining {} took {}",
input.display(),
FormatDuration(time)
);
}
NormalizedOutput::from(explainer)
.compare_to_file(&resolved_explained_snapshot_path)
.unwrap();
}
{
// Dump snapshot of resolved effects
let start = Instant::now();
let mut resolved = Vec::new();
let mut queue = take(&mut var_graph.effects)
.into_iter()
.map(|effect| (0, effect))
.rev()
.collect::<Vec<_>>();
let mut i = 0;
while let Some((parent, effect)) = queue.pop() {
i += 1;
let start = Instant::now();
async fn handle_args(
args: Vec<EffectArg>,
queue: &mut Vec<(usize, Effect)>,
var_graph: &VarGraph,
var_cache: &Mutex<FxHashMap<Id, JsValue>>,
i: usize,
) -> Vec<JsValue> {
let mut new_args = Vec::new();
for arg in args {
match arg {
EffectArg::Value(v) => {
new_args.push(
resolve(
var_graph,
v,
ImportAttributes::empty_ref(),
var_cache,
)
.await
.0,
);
}
EffectArg::Closure(v, effects) => {
new_args.push(
resolve(
var_graph,
v,
ImportAttributes::empty_ref(),
var_cache,
)
.await
.0,
);
queue.extend(
effects.effects.into_iter().rev().map(|e| (i, e)),
);
}
EffectArg::Spread => {
new_args.push(JsValue::unknown_empty(true, "spread"));
}
}
}
new_args
}
let steps = match effect {
Effect::Conditional {
condition, kind, ..
} => {
let (condition, steps) = resolve(
&var_graph,
*condition,
ImportAttributes::empty_ref(),
&var_cache,
)
.await;
resolved.push((format!("{parent} -> {i} conditional"), condition));
match *kind {
ConditionalKind::If { then } => {
queue
.extend(then.effects.into_iter().rev().map(|e| (i, e)));
}
ConditionalKind::Else { r#else } => {
queue.extend(
r#else.effects.into_iter().rev().map(|e| (i, e)),
);
}
ConditionalKind::IfElse { then, r#else }
| ConditionalKind::Ternary { then, r#else } => {
queue.extend(
r#else.effects.into_iter().rev().map(|e| (i, e)),
);
queue
.extend(then.effects.into_iter().rev().map(|e| (i, e)));
}
ConditionalKind::IfElseMultiple { then, r#else } => {
for then in then {
queue.extend(
then.effects.into_iter().rev().map(|e| (i, e)),
);
}
for r#else in r#else {
queue.extend(
r#else.effects.into_iter().rev().map(|e| (i, e)),
);
}
}
ConditionalKind::And { expr }
| ConditionalKind::Or { expr }
| ConditionalKind::NullishCoalescing { expr }
| ConditionalKind::Labeled { body: expr } => {
queue
.extend(expr.effects.into_iter().rev().map(|e| (i, e)));
}
};
steps
}
Effect::Call {
func,
args,
new,
span,
..
} => {
let (func, steps) = resolve(
&var_graph,
*func,
eval_context.imports.get_attributes(span),
&var_cache,
)
.await;
let new_args =
handle_args(args, &mut queue, &var_graph, &var_cache, i).await;
resolved.push((
format!("{parent} -> {i} call"),
if new {
JsValue::new(Box::new(func), new_args)
} else {
JsValue::call(Box::new(func), new_args)
},
));
steps
}
Effect::FreeVar { var, .. } => {
resolved.push((format!("{parent} -> {i} free var"), *var));
0
}
Effect::TypeOf { arg, .. } => {
let (arg, steps) = resolve(
&var_graph,
*arg,
ImportAttributes::empty_ref(),
&var_cache,
)
.await;
resolved.push((
format!("{parent} -> {i} typeof"),
JsValue::type_of(Box::new(arg)),
));
steps
}
Effect::MemberCall {
obj, prop, args, ..
} => {
let (obj, obj_steps) = resolve(
&var_graph,
*obj,
ImportAttributes::empty_ref(),
&var_cache,
)
.await;
let (prop, prop_steps) = resolve(
&var_graph,
*prop,
ImportAttributes::empty_ref(),
&var_cache,
)
.await;
let new_args =
handle_args(args, &mut queue, &var_graph, &var_cache, i).await;
resolved.push((
format!("{parent} -> {i} member call"),
JsValue::member_call(Box::new(obj), Box::new(prop), new_args),
));
obj_steps + prop_steps
}
Effect::Unreachable { .. } => {
resolved.push((
format!("{parent} -> {i} unreachable"),
JsValue::unknown_empty(true, "unreachable"),
));
0
}
Effect::ImportMeta { .. }
| Effect::ImportedBinding { .. }
| Effect::Member { .. } => 0,
};
let time = start.elapsed();
if time.as_millis() > 1 {
println!(
"linking effect {} took {} in {} steps",
input.display(),
FormatDuration(time),
steps
);
}
}
let time = start.elapsed();
if time.as_millis() > 1 {
println!(
"linking effects {} took {}",
input.display(),
FormatDuration(time)
);
}
let start = Instant::now();
let explainer = explain_all(resolved.iter().map(|(name, value)| (name, value)));
let time = start.elapsed();
if time.as_millis() > 1 {
println!(
"explaining effects {} took {}",
input.display(),
FormatDuration(time)
);
}
NormalizedOutput::from(explainer)
.compare_to_file(&resolved_effects_snapshot_path)
.unwrap();
}
Ok(())
})
})
.unwrap();
}
async fn resolve(
var_graph: &VarGraph,
val: JsValue,
attributes: &ImportAttributes,
var_cache: &Mutex<FxHashMap<Id, JsValue>>,
) -> (JsValue, u32) {
turbo_tasks_testing::VcStorage::with(async {
let compile_time_info = CompileTimeInfo::builder(
Environment::new(ExecutionEnvironment::NodeJsLambda(
NodeJsEnvironment {
compile_target: CompileTarget {
arch: Arch::X64,
platform: Platform::Linux,
endianness: Endianness::Little,
libc: Libc::Glibc,
}
.resolved_cell(),
node_version: NodeJsVersion::default().resolved_cell(),
cwd: ResolvedVc::cell(None),
}
.resolved_cell(),
))
.to_resolved()
.await?,
)
.cell()
.await?;
link(
var_graph,
val,
&super::test_utils::early_visitor,
&(|val| {
Box::pin(super::test_utils::visitor(
val,
compile_time_info,
attributes,
))
}),
&Default::default(),
var_cache,
)
.await
})
.await
.unwrap()
}
}