tvl-depot/tvix/eval/src/vm.rs

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//! This module implements the virtual (or abstract) machine that runs
//! Tvix bytecode.
use std::{cell::RefMut, path::PathBuf, rc::Rc};
use crate::{
chunk::Chunk,
fix(tvix/eval): correctly thread through dynamic upvalues This puts together the puzzle pieces for threading dynamic upvalues (that is, upvalues resolved from the `with`-stack) all the way through. Reading the test case enclosed in this commit and walking through it is recommended to understand what problem is being tackled here. In short, because the compiler can not statically know *which* with-scope a dynamic argument is resolved from it needs to lay the groundwork for resolving from *all* possible scopes. There are multiple different approaches to doing this. The approach chosen in this commit is that if a dynamic upvalue is detected, the compiler will emit instructions to close over this dynamic value in *all* enclosing lambda contexts. It uses a new instruction for this that will leave around a sentinel value in case an identifier could not be resolved, and wire the location of this found value (or sentinel) up through the upvalues to the next level of nesting. In this tradeoff, tvix potentially closes over more upvalues than are needed (but in practice, how often do people create *really* deep `with`-stacks? and in *this* kind of code situation? maybe we should even warn for this!) but avoids keeping the entire attribute sets themselves around. Looking at the test case, each surrounding closure will close over *all* dynamic identifiers that are referenced later on visible to it, but only the last one for each identifier will actually end up being used. This also covers our bases for an additional edge-case this creates, in which an identifier potentially resolves to a dynamic upvalue *and* to a dynamic value within the function's own scope (again, would anyone really do this?) by introducing a resolution instruction for that particular case. There is likely some potential for cleaning up this code which is quite ugly in some parts, but as this implementation is now carefully calibrated to work I decided it is time to commit it and clean it up in subsequent commits. Change-Id: Ib701e3e6da39bd2c95938d1384036ff4f9fb3749 Reviewed-on: https://cl.tvl.fyi/c/depot/+/6322 Tested-by: BuildkiteCI Reviewed-by: sterni <sternenseemann@systemli.org>
2022-08-28 02:45:45 +02:00
errors::{Error, ErrorKind, EvalResult},
nix_search_path::NixSearchPath,
observer::RuntimeObserver,
opcode::{CodeIdx, Count, JumpOffset, OpCode, StackIdx, UpvalueIdx},
upvalues::{UpvalueCarrier, Upvalues},
value::{Builtin, Closure, CoercionKind, Lambda, NixAttrs, NixList, Thunk, Value},
warnings::{EvalWarning, WarningKind},
};
struct CallFrame {
/// The lambda currently being executed.
lambda: Rc<Lambda>,
/// Optional captured upvalues of this frame (if a thunk or
/// closure if being evaluated).
upvalues: Upvalues,
/// Instruction pointer to the instruction currently being
/// executed.
ip: CodeIdx,
/// Stack offset, i.e. the frames "view" into the VM's full stack.
stack_offset: usize,
}
impl CallFrame {
/// Retrieve an upvalue from this frame at the given index.
fn upvalue(&self, idx: UpvalueIdx) -> &Value {
&self.upvalues[idx]
}
}
pub struct VM<'o> {
/// The VM call stack. One element is pushed onto this stack
/// each time a function is called or a thunk is forced.
frames: Vec<CallFrame>,
/// The VM value stack. This is actually a "stack of stacks",
/// with one stack-of-Values for each CallFrame in frames. This
/// is represented as a Vec<Value> rather than as
/// Vec<Vec<Value>> or a Vec<Value> inside CallFrame for
/// efficiency reasons: it avoids having to allocate a Vec on
/// the heap each time a CallFrame is entered.
stack: Vec<Value>,
/// Stack indices (absolute indexes into `stack`) of attribute
/// sets from which variables should be dynamically resolved
/// (`with`).
with_stack: Vec<usize>,
/// Runtime warnings collected during evaluation.
warnings: Vec<EvalWarning>,
nix_search_path: NixSearchPath,
observer: &'o mut dyn RuntimeObserver,
}
/// The result of a VM's runtime evaluation.
pub struct RuntimeResult {
pub value: Value,
pub warnings: Vec<EvalWarning>,
}
/// This macro wraps a computation that returns an ErrorKind or a
/// result, and wraps the ErrorKind in an Error struct if present.
///
/// The reason for this macro's existence is that calculating spans is
/// potentially expensive, so it should be avoided to the last moment
/// (i.e. definite instantiation of a runtime error) if possible.
macro_rules! fallible {
( $self:ident, $body:expr) => {
match $body {
Ok(result) => result,
Err(kind) => {
return Err(Error {
kind,
span: $self.current_span(),
})
}
}
};
}
#[macro_export]
macro_rules! arithmetic_op {
( $self:ident, $op:tt ) => {{
let b = $self.pop();
let a = $self.pop();
let result = fallible!($self, arithmetic_op!(&a, &b, $op));
$self.push(result);
}};
( $a:expr, $b:expr, $op:tt ) => {{
match ($a, $b) {
(Value::Integer(i1), Value::Integer(i2)) => Ok(Value::Integer(i1 $op i2)),
(Value::Float(f1), Value::Float(f2)) => Ok(Value::Float(f1 $op f2)),
(Value::Integer(i1), Value::Float(f2)) => Ok(Value::Float(*i1 as f64 $op f2)),
(Value::Float(f1), Value::Integer(i2)) => Ok(Value::Float(f1 $op *i2 as f64)),
(v1, v2) => Err(ErrorKind::TypeError {
expected: "number (either int or float)",
actual: if v1.is_number() {
v2.type_of()
} else {
v1.type_of()
},
}),
}
}};
}
#[macro_export]
macro_rules! cmp_op {
( $self:ident, $op:tt ) => {{
let b = $self.pop();
let a = $self.pop();
let result = fallible!($self, cmp_op!(&a, &b, $op));
$self.push(result);
}};
( $a:expr, $b:expr, $op:tt ) => {
// Comparable (in terms of ordering) values are numbers and
// strings. Numbers need to be coerced similarly to arithmetic
// ops if mixed types are encountered.
match ($a, $b) {
// same types
(Value::Integer(i1), Value::Integer(i2)) => Ok(Value::Bool(i1 $op i2)),
(Value::Float(f1), Value::Float(f2)) => Ok(Value::Bool(f1 $op f2)),
(Value::String(s1), Value::String(s2)) => Ok(Value::Bool(s1 $op s2)),
// different types
(Value::Integer(i1), Value::Float(f2)) => Ok(Value::Bool((*i1 as f64) $op *f2)),
(Value::Float(f1), Value::Integer(i2)) => Ok(Value::Bool(*f1 $op (*i2 as f64))),
// unsupported types
(lhs, rhs) => Err(ErrorKind::Incomparable {
lhs: lhs.type_of(),
rhs: rhs.type_of(),
}),
}
}
}
impl<'o> VM<'o> {
pub fn new(nix_search_path: NixSearchPath, observer: &'o mut dyn RuntimeObserver) -> Self {
Self {
nix_search_path,
observer,
frames: vec![],
stack: vec![],
with_stack: vec![],
warnings: vec![],
}
}
fn frame(&self) -> &CallFrame {
&self.frames[self.frames.len() - 1]
}
fn chunk(&self) -> &Chunk {
&self.frame().lambda.chunk
}
fn frame_mut(&mut self) -> &mut CallFrame {
let idx = self.frames.len() - 1;
&mut self.frames[idx]
}
fn inc_ip(&mut self) -> OpCode {
let op = self.chunk()[self.frame().ip];
self.frame_mut().ip += 1;
op
}
pub fn pop(&mut self) -> Value {
self.stack.pop().expect("runtime stack empty")
}
pub fn push(&mut self, value: Value) {
self.stack.push(value)
}
fn peek(&self, offset: usize) -> &Value {
&self.stack[self.stack.len() - 1 - offset]
}
/// Returns the source span of the instruction currently being
/// executed.
pub(crate) fn current_span(&self) -> codemap::Span {
self.chunk().get_span(self.frame().ip - 1)
}
/// Construct an error from the given ErrorKind and the source
/// span of the current instruction.
pub fn error(&self, kind: ErrorKind) -> Error {
Error {
kind,
span: self.current_span(),
}
}
/// Push an already constructed warning.
pub fn push_warning(&mut self, warning: EvalWarning) {
self.warnings.push(warning);
}
/// Emit a warning with the given WarningKind and the source span
/// of the current instruction.
pub fn emit_warning(&mut self, kind: WarningKind) {
self.push_warning(EvalWarning {
kind,
span: self.current_span(),
});
}
/// Execute the given value in this VM's context, if it is a
/// callable.
///
/// The stack of the VM must be prepared with all required
/// arguments before calling this and the value must have already
/// been forced.
pub fn call_value(&mut self, callable: &Value) -> EvalResult<()> {
match callable {
Value::Closure(c) => self.enter_frame(c.lambda(), c.upvalues().clone(), 1),
Value::Builtin(b) => self.call_builtin(b.clone()),
Value::Thunk(t) => self.call_value(&t.value()),
// Attribute sets with a __functor attribute are callable.
Value::Attrs(ref attrs) => match attrs.select("__functor") {
None => Err(self.error(ErrorKind::NotCallable(callable.type_of()))),
Some(functor) => {
// The functor receives the set itself as its first argument
// and needs to be called with it. However, this call is
// synthetic (i.e. there is no corresponding OpCall for the
// first call in the bytecode.)
self.push(callable.clone());
self.call_value(functor)?;
let primed = self.pop();
self.call_value(&primed)
}
},
// TODO: this isn't guaranteed to be a useful span, actually
other => Err(self.error(ErrorKind::NotCallable(other.type_of()))),
}
}
/// Call the given `callable` value with the given list of `args`
///
/// # Panics
///
/// Panics if the passed list of `args` is empty
#[track_caller]
pub fn call_with<I>(&mut self, callable: &Value, args: I) -> EvalResult<Value>
where
I: IntoIterator<Item = Value>,
{
let mut num_args = 0_usize;
for arg in args {
num_args += 1;
self.push(arg);
}
if num_args == 0 {
panic!("call_with called with an empty list of args");
}
self.call_value(callable)?;
let mut res = self.pop();
for _ in 0..(num_args - 1) {
self.call_value(&res)?;
res = self.pop();
}
Ok(res)
}
fn tail_call_value(&mut self, callable: Value) -> EvalResult<()> {
match callable {
Value::Builtin(builtin) => self.call_builtin(builtin),
Value::Thunk(thunk) => self.tail_call_value(thunk.value().clone()),
Value::Closure(closure) => {
let lambda = closure.lambda();
self.observer.observe_tail_call(self.frames.len(), &lambda);
// Replace the current call frames internals with
// that of the tail-called closure.
let mut frame = self.frame_mut();
frame.lambda = lambda;
frame.upvalues = closure.upvalues().clone();
frame.ip = CodeIdx(0); // reset instruction pointer to beginning
Ok(())
}
// Attribute sets with a __functor attribute are callable.
Value::Attrs(ref attrs) => match attrs.select("__functor") {
None => Err(self.error(ErrorKind::NotCallable(callable.type_of()))),
Some(functor) => {
// The functor receives the set itself as its first argument
// and needs to be called with it. However, this call is
// synthetic (i.e. there is no corresponding OpCall for the
// first call in the bytecode.)
self.push(callable.clone());
self.call_value(functor)?;
let primed = self.pop();
self.tail_call_value(primed)
}
},
_ => Err(self.error(ErrorKind::NotCallable(callable.type_of()))),
}
}
/// Execute the given lambda in this VM's context, returning its
/// value after its stack frame completes.
pub fn enter_frame(
&mut self,
lambda: Rc<Lambda>,
upvalues: Upvalues,
arg_count: usize,
) -> EvalResult<()> {
self.observer
.observe_enter_frame(arg_count, &lambda, self.frames.len() + 1);
let frame = CallFrame {
lambda,
upvalues,
ip: CodeIdx(0),
stack_offset: self.stack.len() - arg_count,
};
self.frames.push(frame);
let result = self.run();
self.observer
.observe_exit_frame(self.frames.len() + 1, &self.stack);
result
}
/// Run the VM's current call frame to completion.
///
/// On successful return, the top of the stack is the value that
/// the frame evaluated to. The frame itself is popped off. It is
/// up to the caller to consume the value.
fn run(&mut self) -> EvalResult<()> {
loop {
// Break the loop if this call frame has already run to
// completion, pop it off, and return the value to the
// caller.
if self.frame().ip.0 == self.chunk().code.len() {
self.frames.pop();
return Ok(());
}
let op = self.inc_ip();
self.observer
.observe_execute_op(self.frame().ip, &op, &self.stack);
let res = self.run_op(op);
if self.frame().ip.0 == self.chunk().code.len() {
self.frames.pop();
return res;
} else {
res?;
}
}
}
fn run_op(&mut self, op: OpCode) -> EvalResult<()> {
match op {
OpCode::OpConstant(idx) => {
let c = self.chunk()[idx].clone();
self.push(c);
}
OpCode::OpPop => {
self.pop();
}
OpCode::OpAdd => {
let b = self.pop();
let a = self.pop();
let result = match (&a, &b) {
(Value::String(s1), Value::String(s2)) => Value::String(s1.concat(s2)),
(Value::Path(p), v) => {
let mut path = p.to_string_lossy().into_owned();
path.push_str(
&v.coerce_to_string(CoercionKind::Weak, self)
.map_err(|ek| self.error(ek))?,
);
crate::value::canon_path(PathBuf::from(path)).into()
}
_ => fallible!(self, arithmetic_op!(&a, &b, +)),
};
self.push(result)
}
OpCode::OpSub => arithmetic_op!(self, -),
OpCode::OpMul => arithmetic_op!(self, *),
OpCode::OpDiv => arithmetic_op!(self, /),
OpCode::OpInvert => {
let v = fallible!(self, self.pop().as_bool());
self.push(Value::Bool(!v));
}
OpCode::OpNegate => match self.pop() {
Value::Integer(i) => self.push(Value::Integer(-i)),
Value::Float(f) => self.push(Value::Float(-f)),
v => {
return Err(self.error(ErrorKind::TypeError {
expected: "number (either int or float)",
actual: v.type_of(),
}));
}
},
OpCode::OpEqual => {
let v2 = self.pop();
let v1 = self.pop();
let res = fallible!(self, v1.nix_eq(&v2, self));
self.push(Value::Bool(res))
}
OpCode::OpLess => cmp_op!(self, <),
OpCode::OpLessOrEq => cmp_op!(self, <=),
OpCode::OpMore => cmp_op!(self, >),
OpCode::OpMoreOrEq => cmp_op!(self, >=),
OpCode::OpNull => self.push(Value::Null),
OpCode::OpTrue => self.push(Value::Bool(true)),
OpCode::OpFalse => self.push(Value::Bool(false)),
OpCode::OpAttrs(Count(count)) => self.run_attrset(count)?,
OpCode::OpAttrsUpdate => {
let rhs = unwrap_or_clone_rc(fallible!(self, self.pop().to_attrs()));
let lhs = unwrap_or_clone_rc(fallible!(self, self.pop().to_attrs()));
self.push(Value::attrs(lhs.update(rhs)))
}
OpCode::OpAttrsSelect => {
let key = fallible!(self, self.pop().to_str());
let attrs = fallible!(self, self.pop().to_attrs());
match attrs.select(key.as_str()) {
Some(value) => self.push(value.clone()),
None => {
return Err(self.error(ErrorKind::AttributeNotFound {
name: key.as_str().to_string(),
}))
}
}
}
OpCode::OpAttrsTrySelect => {
let key = fallible!(self, self.pop().to_str());
let value = match self.pop() {
Value::Attrs(attrs) => match attrs.select(key.as_str()) {
Some(value) => value.clone(),
None => Value::AttrNotFound,
},
_ => Value::AttrNotFound,
};
self.push(value);
}
OpCode::OpHasAttr => {
let key = fallible!(self, self.pop().to_str());
let result = match self.pop() {
Value::Attrs(attrs) => attrs.contains(key.as_str()),
// Nix allows use of `?` on non-set types, but
// always returns false in those cases.
_ => false,
};
self.push(Value::Bool(result));
}
OpCode::OpList(Count(count)) => {
let list =
NixList::construct(count, self.stack.split_off(self.stack.len() - count));
self.push(Value::List(list));
}
OpCode::OpConcat => {
let rhs = fallible!(self, self.pop().to_list());
let lhs = fallible!(self, self.pop().to_list());
self.push(Value::List(lhs.concat(&rhs)))
}
OpCode::OpInterpolate(Count(count)) => self.run_interpolate(count)?,
OpCode::OpCoerceToString => {
// TODO: handle string context, copying to store
let string = fallible!(
self,
// note that coerce_to_string also forces
self.pop().coerce_to_string(CoercionKind::Weak, self)
);
self.push(Value::String(string));
}
OpCode::OpFindFile => {
let path = self.pop().to_str().map_err(|e| self.error(e))?;
let resolved = self
.nix_search_path
.resolve(path)
.map_err(|e| self.error(e))?;
self.push(resolved.into());
}
OpCode::OpJump(JumpOffset(offset)) => {
debug_assert!(offset != 0);
self.frame_mut().ip += offset;
}
OpCode::OpJumpIfTrue(JumpOffset(offset)) => {
debug_assert!(offset != 0);
if fallible!(self, self.peek(0).as_bool()) {
self.frame_mut().ip += offset;
}
}
OpCode::OpJumpIfFalse(JumpOffset(offset)) => {
debug_assert!(offset != 0);
if !fallible!(self, self.peek(0).as_bool()) {
self.frame_mut().ip += offset;
}
}
OpCode::OpJumpIfNotFound(JumpOffset(offset)) => {
debug_assert!(offset != 0);
if matches!(self.peek(0), Value::AttrNotFound) {
self.pop();
self.frame_mut().ip += offset;
}
}
// These assertion operations error out if the stack
// top is not of the expected type. This is necessary
// to implement some specific behaviours of Nix
// exactly.
OpCode::OpAssertBool => {
let val = self.peek(0);
if !val.is_bool() {
return Err(self.error(ErrorKind::TypeError {
expected: "bool",
actual: val.type_of(),
}));
}
}
// Remove the given number of elements from the stack,
// but retain the top value.
OpCode::OpCloseScope(Count(count)) => {
// Immediately move the top value into the right
// position.
let target_idx = self.stack.len() - 1 - count;
self.stack[target_idx] = self.pop();
// Then drop the remaining values.
for _ in 0..(count - 1) {
self.pop();
}
}
OpCode::OpGetLocal(StackIdx(local_idx)) => {
let idx = self.frame().stack_offset + local_idx;
self.push(self.stack[idx].clone());
}
OpCode::OpPushWith(StackIdx(idx)) => {
self.with_stack.push(self.frame().stack_offset + idx)
}
OpCode::OpPopWith => {
self.with_stack.pop();
}
OpCode::OpResolveWith => {
let ident = fallible!(self, self.pop().to_str());
let value = self.resolve_with(ident.as_str())?;
self.push(value)
}
OpCode::OpAssertFail => {
return Err(self.error(ErrorKind::AssertionFailed));
}
OpCode::OpCall => {
let callable = self.pop();
self.call_value(&callable)?;
}
OpCode::OpTailCall => {
let callable = self.pop();
self.tail_call_value(callable)?;
}
OpCode::OpGetUpvalue(upv_idx) => {
let value = self.frame().upvalue(upv_idx).clone();
self.push(value);
}
OpCode::OpClosure(idx) => {
let blueprint = match &self.chunk()[idx] {
Value::Blueprint(lambda) => lambda.clone(),
_ => panic!("compiler bug: non-blueprint in blueprint slot"),
};
let upvalue_count = blueprint.upvalue_count;
debug_assert!(
upvalue_count > 0,
"OpClosure should not be called for plain lambdas"
);
let closure = Closure::new(blueprint);
let upvalues = closure.upvalues_mut();
self.push(Value::Closure(closure.clone()));
// From this point on we internally mutate the
// closure object's upvalues. The closure is
// already in its stack slot, which means that it
// can capture itself as an upvalue for
// self-recursion.
self.populate_upvalues(upvalue_count, upvalues)?;
}
OpCode::OpThunk(idx) => {
let blueprint = match &self.chunk()[idx] {
Value::Blueprint(lambda) => lambda.clone(),
_ => panic!("compiler bug: non-blueprint in blueprint slot"),
};
let upvalue_count = blueprint.upvalue_count;
let thunk = Thunk::new(blueprint, self.current_span());
let upvalues = thunk.upvalues_mut();
self.push(Value::Thunk(thunk.clone()));
self.populate_upvalues(upvalue_count, upvalues)?;
}
OpCode::OpForce => {
let mut value = self.pop();
if let Value::Thunk(thunk) = value {
fallible!(self, thunk.force(self));
value = thunk.value().clone();
}
self.push(value);
}
OpCode::OpFinalise(StackIdx(idx)) => {
match &self.stack[self.frame().stack_offset + idx] {
Value::Closure(closure) => {
closure.resolve_deferred_upvalues(&self.stack[self.frame().stack_offset..])
}
Value::Thunk(thunk) => {
thunk.resolve_deferred_upvalues(&self.stack[self.frame().stack_offset..])
}
// In functions with "formals" attributes, it is
// possible for `OpFinalise` to be called on a
// non-capturing value, in which case it is a no-op.
//
// TODO: detect this in some phase and skip the finalise; fail here
_ => { /* TODO: panic here again to catch bugs */ }
}
}
// Data-carrying operands should never be executed,
// that is a critical error in the VM.
OpCode::DataLocalIdx(_)
| OpCode::DataDeferredLocal(_)
| OpCode::DataUpvalueIdx(_)
| OpCode::DataCaptureWith => {
panic!("VM bug: attempted to execute data-carrying operand")
}
}
Ok(())
}
fn run_attrset(&mut self, count: usize) -> EvalResult<()> {
let attrs = fallible!(
self,
NixAttrs::construct(count, self.stack.split_off(self.stack.len() - count * 2))
);
self.push(Value::attrs(attrs));
Ok(())
}
/// Interpolate string fragments by popping the specified number of
/// fragments of the stack, evaluating them to strings, and pushing
/// the concatenated result string back on the stack.
fn run_interpolate(&mut self, count: usize) -> EvalResult<()> {
let mut out = String::new();
for _ in 0..count {
out.push_str(fallible!(self, self.pop().to_str()).as_str());
}
self.push(Value::String(out.into()));
Ok(())
}
/// Resolve a dynamic identifier through the with-stack at runtime.
fn resolve_with(&mut self, ident: &str) -> EvalResult<Value> {
// Iterate over the with_stack manually to avoid borrowing
// self, which is required for forcing the set.
for with_stack_idx in (0..self.with_stack.len()).rev() {
let with = self.stack[self.with_stack[with_stack_idx]].clone();
if let Value::Thunk(thunk) = &with {
fallible!(self, thunk.force(self));
}
match fallible!(self, with.to_attrs()).select(ident) {
None => continue,
Some(val) => return Ok(val.clone()),
}
}
// Iterate over the captured with stack if one exists. This is
// extra tricky to do without a lot of cloning.
for idx in (0..self.frame().upvalues.with_stack_len()).rev() {
// This will not panic because having an index here guarantees
// that the stack is present.
let with = self.frame().upvalues.with_stack().unwrap()[idx].clone();
if let Value::Thunk(thunk) = &with {
fallible!(self, thunk.force(self));
}
match fallible!(self, with.to_attrs()).select(ident) {
None => continue,
Some(val) => return Ok(val.clone()),
}
}
Err(self.error(ErrorKind::UnknownDynamicVariable(ident.to_string())))
}
/// Populate the upvalue fields of a thunk or closure under construction.
fn populate_upvalues(
&mut self,
count: usize,
mut upvalues: RefMut<'_, Upvalues>,
) -> EvalResult<()> {
for _ in 0..count {
match self.inc_ip() {
OpCode::DataLocalIdx(StackIdx(local_idx)) => {
let idx = self.frame().stack_offset + local_idx;
upvalues.push(self.stack[idx].clone());
}
OpCode::DataUpvalueIdx(upv_idx) => {
upvalues.push(self.frame().upvalue(upv_idx).clone());
}
OpCode::DataDeferredLocal(idx) => {
upvalues.push(Value::DeferredUpvalue(idx));
}
OpCode::DataCaptureWith => {
// Start the captured with_stack off of the
// current call frame's captured with_stack, ...
let mut captured_with_stack = self
.frame()
.upvalues
.with_stack()
.map(Clone::clone)
// ... or make an empty one if there isn't one already.
.unwrap_or_else(|| Vec::with_capacity(self.with_stack.len()));
for idx in &self.with_stack {
captured_with_stack.push(self.stack[*idx].clone());
}
upvalues.set_with_stack(captured_with_stack);
}
_ => panic!("compiler error: missing closure operand"),
}
}
Ok(())
}
/// Strictly evaluate the supplied value for outputting it. This
/// will ensure that lists and attribute sets do not contain
/// chunks which, for users, are displayed in a strange and often
/// unexpected way.
fn force_for_output(&mut self, value: &Value) -> EvalResult<()> {
match value {
Value::Attrs(attrs) => {
for (_, value) in attrs.iter() {
self.force_for_output(value)?;
}
Ok(())
}
Value::List(list) => list.iter().try_for_each(|elem| self.force_for_output(elem)),
Value::Thunk(thunk) => {
fallible!(self, thunk.force(self));
let value = thunk.value().clone();
self.force_for_output(&value)
}
// If any of these internal values are encountered here a
// critical error has happened (likely a compiler bug).
Value::AttrNotFound
| Value::DynamicUpvalueMissing(_)
| Value::Blueprint(_)
| Value::DeferredUpvalue(_) => {
panic!("tvix bug: internal value left on stack: {:?}", value)
}
Value::Null
| Value::Bool(_)
| Value::Integer(_)
| Value::Float(_)
| Value::String(_)
| Value::Path(_)
| Value::Closure(_)
| Value::Builtin(_) => Ok(()),
}
}
pub fn call_builtin(&mut self, builtin: Builtin) -> EvalResult<()> {
let builtin_name = builtin.name();
self.observer.observe_enter_builtin(builtin_name);
let arg = self.pop();
let result = fallible!(self, builtin.apply(self, arg));
self.observer
.observe_exit_builtin(builtin_name, &self.stack);
self.push(result);
Ok(())
}
}
// TODO: use Rc::unwrap_or_clone once it is stabilised.
// https://doc.rust-lang.org/std/rc/struct.Rc.html#method.unwrap_or_clone
fn unwrap_or_clone_rc<T: Clone>(rc: Rc<T>) -> T {
Rc::try_unwrap(rc).unwrap_or_else(|rc| (*rc).clone())
}
pub fn run_lambda(
nix_search_path: NixSearchPath,
observer: &mut dyn RuntimeObserver,
lambda: Rc<Lambda>,
) -> EvalResult<RuntimeResult> {
let mut vm = VM::new(nix_search_path, observer);
vm.enter_frame(lambda, Upvalues::with_capacity(0), 0)?;
let value = vm.pop();
vm.force_for_output(&value)?;
Ok(RuntimeResult {
value,
warnings: vm.warnings,
})
}