//! This module implements the instruction set running on the abstract //! machine implemented by tvix. use std::ops::{AddAssign, Sub}; /// Index of a constant in the current code chunk. #[repr(transparent)] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub struct ConstantIdx(pub usize); /// Index of an instruction in the current code chunk. #[repr(transparent)] #[derive(Clone, Copy, Debug)] pub struct CodeIdx(pub usize); impl AddAssign for CodeIdx { fn add_assign(&mut self, rhs: usize) { *self = CodeIdx(self.0 + rhs) } } impl Sub for CodeIdx { type Output = Self; fn sub(self, rhs: usize) -> Self::Output { CodeIdx(self.0 - rhs) } } /// Index of a value in the runtime stack. This is an offset /// *relative to* the VM value stack_base of the CallFrame /// containing the opcode which contains this StackIdx. #[repr(transparent)] #[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd)] pub struct StackIdx(pub usize); /// Index of an upvalue within a closure's bound-variable upvalue /// list. This is an absolute index into the Upvalues of the /// CallFrame containing the opcode which contains this UpvalueIdx. #[repr(transparent)] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub struct UpvalueIdx(pub usize); /// Offset by which an instruction pointer should change in a jump. #[repr(transparent)] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub struct JumpOffset(pub usize); /// Provided count for an instruction (could represent e.g. a number /// of elements). #[repr(transparent)] #[derive(Clone, Copy, Debug, PartialEq, Eq)] pub struct Count(pub usize); /// Op represents all instructions in the Tvix abstract machine. /// /// In documentation comments, stack positions are referred to by /// indices written in `{}` as such, where required: /// /// ```notrust /// --- top of the stack /// / /// v /// [ ... | 3 | 2 | 1 | 0 ] /// ^ /// / /// 2 values deep --- /// ``` /// /// Unless otherwise specified, operations leave their result at the /// top of the stack. #[repr(u8)] #[derive(Debug, PartialEq, Eq)] pub enum Op { /// Push a constant onto the stack. Constant, /// Discard the value on top of the stack. Pop, /// Invert the boolean at the top of the stack. Invert, /// Invert the sign of the number at the top of the stack. Negate, /// Sum up the two numbers at the top of the stack. Add, /// Subtract the number at {1} from the number at {2}. Sub, /// Multiply the two numbers at the top of the stack. Mul, /// Divide the two numbers at the top of the stack. Div, /// Check the two values at the top of the stack for Nix-equality. Equal, /// Check whether the value at {2} is less than {1}. Less, /// Check whether the value at {2} is less than or equal to {1}. LessOrEq, /// Check whether the value at {2} is greater than {1}. More, /// Check whether the value at {2} is greater than or equal to {1}. MoreOrEq, /// Jump forward in the bytecode specified by the number of /// instructions in its usize operand. Jump, /// Jump forward in the bytecode specified by the number of /// instructions in its usize operand, *if* the value at the top /// of the stack is `true`. JumpIfTrue, /// Jump forward in the bytecode specified by the number of /// instructions in its usize operand, *if* the value at the top /// of the stack is `false`. JumpIfFalse, /// Pop one stack item and jump forward in the bytecode /// specified by the number of instructions in its usize /// operand, *if* the value at the top of the stack is a /// Value::Catchable. JumpIfCatchable, /// Jump forward in the bytecode specified by the number of /// instructions in its usize operand, *if* the value at the top /// of the stack is the internal value representing a missing /// attribute set key. JumpIfNotFound, /// Jump forward in the bytecode specified by the number of /// instructions in its usize operand, *if* the value at the top /// of the stack is *not* the internal value requesting a /// stack value finalisation. JumpIfNoFinaliseRequest, /// Construct an attribute set from the given number of key-value pairs on /// the top of the stack. The operand gives the count of *pairs*, not the /// number of *stack values* - the actual number of values popped off the /// stack will be twice the argument to this op. Attrs, /// Merge the attribute set at {2} into the attribute set at {1}, /// and leave the new set at the top of the stack. AttrsUpdate, /// Select the attribute with the name at {1} from the set at {2}. AttrsSelect, /// Select the attribute with the name at {1} from the set at {2}, but leave /// a `Value::AttrNotFound` in the stack instead of failing if it is /// missing. AttrsTrySelect, /// Check for the presence of the attribute with the name at {1} in the set /// at {2}. HasAttr, /// Throw an error if the attribute set at the top of the stack has any attributes /// other than those listed in the formals of the current lambda /// /// Panics if the current frame is not a lambda with formals ValidateClosedFormals, /// Push a value onto the runtime `with`-stack to enable dynamic identifier /// resolution. The absolute stack index of the value is supplied as a usize /// operand. PushWith, /// Pop the last runtime `with`-stack element. PopWith, /// Dynamically resolve an identifier with the name at {1} from the runtime /// `with`-stack. ResolveWith, // Lists /// Construct a list from the given number of values at the top of the /// stack. List, /// Concatenate the lists at {2} and {1}. Concat, // Strings /// Interpolate the given number of string fragments into a single string. Interpolate, /// Force the Value on the stack and coerce it to a string CoerceToString, // Paths /// Attempt to resolve the Value on the stack using the configured [`NixSearchPath`][] /// /// [`NixSearchPath`]: crate::nix_search_path::NixSearchPath FindFile, /// Attempt to resolve a path literal relative to the home dir ResolveHomePath, // Type assertion operators /// Assert that the value at {1} is a boolean, and fail with a runtime error /// otherwise. AssertBool, AssertAttrs, /// Access local identifiers with statically known positions. GetLocal, /// Close scopes while leaving their expression value around. CloseScope, /// Return an error indicating that an `assert` failed AssertFail, // Lambdas & closures /// Call the value at {1} in a new VM callframe Call, /// Retrieve the upvalue at the given index from the closure or thunk /// currently under evaluation. GetUpvalue, /// Construct a closure which has upvalues but no self-references Closure, /// Construct a closure which has self-references (direct or via upvalues) ThunkClosure, /// Construct a suspended thunk, used to delay a computation for laziness. ThunkSuspended, /// Force the value at {1} until it is a `Thunk::Evaluated`. Force, /// Finalise initialisation of the upvalues of the value in the given stack /// index (which must be a Value::Thunk) after the scope is fully bound. Finalise, /// Final instruction emitted in a chunk. Does not have an /// inherent effect, but can simplify VM logic as a marker in some /// cases. /// /// Can be thought of as "returning" the value to the parent /// frame, hence the name. Return, /// Sentinel value to signal invalid bytecode. This MUST always be the last /// value in the enum. Do not move it! Invalid, } const _ASSERT_SMALL_OP: () = assert!(std::mem::size_of::() == 1); impl From for Op { fn from(num: u8) -> Self { if num >= Self::Invalid as u8 { return Self::Invalid; } // SAFETY: As long as `Invalid` remains the last variant of the enum, // and as long as variant values are not specified manually, this // conversion is safe. unsafe { std::mem::transmute(num) } } } pub enum OpArg { None, Uvarint, Fixed, Custom, } impl Op { pub fn arg_type(&self) -> OpArg { match self { Op::Constant | Op::Attrs | Op::PushWith | Op::List | Op::Interpolate | Op::GetLocal | Op::CloseScope | Op::GetUpvalue | Op::Finalise => OpArg::Uvarint, Op::Jump | Op::JumpIfTrue | Op::JumpIfFalse | Op::JumpIfCatchable | Op::JumpIfNotFound | Op::JumpIfNoFinaliseRequest => OpArg::Fixed, Op::CoerceToString | Op::Closure | Op::ThunkClosure | Op::ThunkSuspended => { OpArg::Custom } _ => OpArg::None, } } } /// Position is used to represent where to capture an upvalue from. #[derive(Clone, Copy)] pub struct Position(pub u64); impl Position { pub fn stack_index(idx: StackIdx) -> Self { Position((idx.0 as u64) << 2) } pub fn deferred_local(idx: StackIdx) -> Self { Position(((idx.0 as u64) << 2) | 1) } pub fn upvalue_index(idx: UpvalueIdx) -> Self { Position(((idx.0 as u64) << 2) | 2) } pub fn runtime_stack_index(&self) -> Option { if (self.0 & 0b11) == 0 { return Some(StackIdx((self.0 >> 2) as usize)); } None } pub fn runtime_deferred_local(&self) -> Option { if (self.0 & 0b11) == 1 { return Some(StackIdx((self.0 >> 2) as usize)); } None } pub fn runtime_upvalue_index(&self) -> Option { if (self.0 & 0b11) == 2 { return Some(UpvalueIdx((self.0 >> 2) as usize)); } None } } #[cfg(test)] mod position_tests { use super::Position; // he-he use super::{StackIdx, UpvalueIdx}; #[test] fn test_stack_index_position() { let idx = StackIdx(42); let pos = Position::stack_index(idx); let result = pos.runtime_stack_index(); assert_eq!(result, Some(idx)); assert_eq!(pos.runtime_deferred_local(), None); assert_eq!(pos.runtime_upvalue_index(), None); } #[test] fn test_deferred_local_position() { let idx = StackIdx(42); let pos = Position::deferred_local(idx); let result = pos.runtime_deferred_local(); assert_eq!(result, Some(idx)); assert_eq!(pos.runtime_stack_index(), None); assert_eq!(pos.runtime_upvalue_index(), None); } #[test] fn test_upvalue_index_position() { let idx = UpvalueIdx(42); let pos = Position::upvalue_index(idx); let result = pos.runtime_upvalue_index(); assert_eq!(result, Some(idx)); assert_eq!(pos.runtime_stack_index(), None); assert_eq!(pos.runtime_deferred_local(), None); } }