vendor/cranelift-codegen/src/machinst/abi.rs - toolchain/rustc - Git at Google

 //! ABI definitions.

 use crate::binemit::StackMap;
 use crate::ir::StackSlot;
 use crate::isa::CallConv;
 use crate::machinst::*;
 use crate::settings;

 use regalloc::{Reg, Set, SpillSlot, Writable};

 /// Trait implemented by an object that tracks ABI-related state (e.g., stack
 /// layout) and can generate code while emitting the *body* of a function.
 pub trait ABICallee {
     /// The instruction type for the ISA associated with this ABI.
     type I: VCodeInst;

     /// Does the ABI-body code need a temp reg? One will be provided to `init()`
     /// as the `maybe_tmp` arg if so.
     fn temp_needed(&self) -> bool;

     /// Initialize. This is called after the ABICallee is constructed because it
     /// may be provided with a temp vreg, which can only be allocated once the
     /// lowering context exists.
     fn init(&mut self, maybe_tmp: Option<Writable<Reg>>);

     /// Accumulate outgoing arguments.  This ensures that at least SIZE bytes
     /// are allocated in the prologue to be available for use in function calls
     /// to hold arguments and/or return values.  If this function is called
     /// multiple times, the maximum of all SIZE values will be available.
     fn accumulate_outgoing_args_size(&mut self, size: u32);

     /// Get the settings controlling this function's compilation.
     fn flags(&self) -> &settings::Flags;

     /// Get the calling convention implemented by this ABI object.
     fn call_conv(&self) -> CallConv;

     /// Get the liveins of the function.
     fn liveins(&self) -> Set<RealReg>;

     /// Get the liveouts of the function.
     fn liveouts(&self) -> Set<RealReg>;

     /// Number of arguments.
     fn num_args(&self) -> usize;

     /// Number of return values.
     fn num_retvals(&self) -> usize;

     /// Number of stack slots (not spill slots).
     fn num_stackslots(&self) -> usize;

     /// Generate an instruction which copies an argument to a destination
     /// register.
     fn gen_copy_arg_to_reg(&self, idx: usize, into_reg: Writable<Reg>) -> Self::I;

     /// Is the given argument needed in the body (as opposed to, e.g., serving
     /// only as a special ABI-specific placeholder)? This controls whether
     /// lowering will copy it to a virtual reg use by CLIF instructions.
     fn arg_is_needed_in_body(&self, idx: usize) -> bool;

     /// Generate any setup instruction needed to save values to the
     /// return-value area. This is usually used when were are multiple return
     /// values or an otherwise large return value that must be passed on the
     /// stack; typically the ABI specifies an extra hidden argument that is a
     /// pointer to that memory.
     fn gen_retval_area_setup(&self) -> Option<Self::I>;

     /// Generate an instruction which copies a source register to a return value slot.
     fn gen_copy_reg_to_retval(&self, idx: usize, from_reg: Writable<Reg>) -> Vec<Self::I>;

     /// Generate a return instruction.
     fn gen_ret(&self) -> Self::I;

     /// Generate an epilogue placeholder. The returned instruction should return `true` from
     /// `is_epilogue_placeholder()`; this is used to indicate to the lowering driver when
     /// the epilogue should be inserted.
     fn gen_epilogue_placeholder(&self) -> Self::I;

     // -----------------------------------------------------------------
     // Every function above this line may only be called pre-regalloc.
     // Every function below this line may only be called post-regalloc.
     // `spillslots()` must be called before any other post-regalloc
     // function.
     // ----------------------------------------------------------------

     /// Update with the number of spillslots, post-regalloc.
     fn set_num_spillslots(&mut self, slots: usize);

     /// Update with the clobbered registers, post-regalloc.
     fn set_clobbered(&mut self, clobbered: Set<Writable<RealReg>>);

     /// Get the address of a stackslot.
     fn stackslot_addr(&self, slot: StackSlot, offset: u32, into_reg: Writable<Reg>) -> Self::I;

     /// Load from a stackslot.
     fn load_stackslot(
         &self,
         slot: StackSlot,
         offset: u32,
         ty: Type,
         into_reg: Writable<Reg>,
     ) -> Self::I;

     /// Store to a stackslot.
     fn store_stackslot(&self, slot: StackSlot, offset: u32, ty: Type, from_reg: Reg) -> Self::I;

     /// Load from a spillslot.
     fn load_spillslot(&self, slot: SpillSlot, ty: Type, into_reg: Writable<Reg>) -> Self::I;

     /// Store to a spillslot.
     fn store_spillslot(&self, slot: SpillSlot, ty: Type, from_reg: Reg) -> Self::I;

     /// Generate a stack map, given a list of spillslots and the emission state
     /// at a given program point (prior to emission fo the safepointing
     /// instruction).
     fn spillslots_to_stack_map(
         &self,
         slots: &[SpillSlot],
         state: &<Self::I as MachInstEmit>::State,
     ) -> StackMap;

     /// Generate a prologue, post-regalloc. This should include any stack
     /// frame or other setup necessary to use the other methods (`load_arg`,
     /// `store_retval`, and spillslot accesses.)  `self` is mutable so that we
     /// can store information in it which will be useful when creating the
     /// epilogue.
     fn gen_prologue(&mut self) -> Vec<Self::I>;

     /// Generate an epilogue, post-regalloc. Note that this must generate the
     /// actual return instruction (rather than emitting this in the lowering
     /// logic), because the epilogue code comes before the return and the two are
     /// likely closely related.
     fn gen_epilogue(&self) -> Vec<Self::I>;

     /// Returns the full frame size for the given function, after prologue
     /// emission has run. This comprises the spill slots and stack-storage slots
     /// (but not storage for clobbered callee-save registers, arguments pushed
     /// at callsites within this function, or other ephemeral pushes).  This is
     /// used for ABI variants where the client generates prologue/epilogue code,
     /// as in Baldrdash (SpiderMonkey integration).
     fn frame_size(&self) -> u32;

     /// Returns the size of arguments expected on the stack.
     fn stack_args_size(&self) -> u32;

     /// Get the spill-slot size.
     fn get_spillslot_size(&self, rc: RegClass, ty: Type) -> u32;

     /// Generate a spill. The type, if known, is given; this can be used to
     /// generate a store instruction optimized for the particular type rather
     /// than the RegClass (e.g., only F64 that resides in a V128 register). If
     /// no type is given, the implementation should spill the whole register.
     fn gen_spill(&self, to_slot: SpillSlot, from_reg: RealReg, ty: Option<Type>) -> Self::I;

     /// Generate a reload (fill). As for spills, the type may be given to allow
     /// a more optimized load instruction to be generated.
     fn gen_reload(
         &self,
         to_reg: Writable<RealReg>,
         from_slot: SpillSlot,
         ty: Option<Type>,
     ) -> Self::I;

     /// Desired unwind info type.
     fn unwind_info_kind(&self) -> UnwindInfoKind;
 }

 /// Trait implemented by an object that tracks ABI-related state and can
 /// generate code while emitting a *call* to a function.
 ///
 /// An instance of this trait returns information for a *particular*
 /// callsite. It will usually be computed from the called function's
 /// signature.
 ///
 /// Unlike `ABICallee` above, methods on this trait are not invoked directly
 /// by the machine-independent code. Rather, the machine-specific lowering
 /// code will typically create an `ABICaller` when creating machine instructions
 /// for an IR call instruction inside `lower()`, directly emit the arg and
 /// and retval copies, and attach the register use/def info to the call.
 ///
 /// This trait is thus provided for convenience to the backends.
 pub trait ABICaller {
     /// The instruction type for the ISA associated with this ABI.
     type I: VCodeInst;

     /// Get the number of arguments expected.
     fn num_args(&self) -> usize;

     /// Emit a copy of an argument value from a source register, prior to the call.
     fn emit_copy_reg_to_arg<C: LowerCtx<I = Self::I>>(
         &self,
         ctx: &mut C,
         idx: usize,
         from_reg: Reg,
     );

     /// Emit a copy a return value into a destination register, after the call returns.
     fn emit_copy_retval_to_reg<C: LowerCtx<I = Self::I>>(
         &self,
         ctx: &mut C,
         idx: usize,
         into_reg: Writable<Reg>,
     );

     /// Emit code to pre-adjust the stack, prior to argument copies and call.
     fn emit_stack_pre_adjust<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

     /// Emit code to post-adjust the satck, after call return and return-value copies.
     fn emit_stack_post_adjust<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

     /// Accumulate outgoing arguments.  This ensures that the caller (as
     /// identified via the CTX argument) allocates enough space in the
     /// prologue to hold all arguments and return values for this call.
     /// There is no code emitted at the call site, everything is done
     /// in the caller's function prologue.
     fn accumulate_outgoing_args_size<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

     /// Emit the call itself.
     ///
     /// The returned instruction should have proper use- and def-sets according
     /// to the argument registers, return-value registers, and clobbered
     /// registers for this function signature in this ABI.
     ///
     /// (Arg registers are uses, and retval registers are defs. Clobbered
     /// registers are also logically defs, but should never be read; their
     /// values are "defined" (to the regalloc) but "undefined" in every other
     /// sense.)
     ///
     /// This function should only be called once, as it is allowed to re-use
     /// parts of the ABICaller object in emitting instructions.
     fn emit_call<C: LowerCtx<I = Self::I>>(&mut self, ctx: &mut C);
 }
	//! ABI definitions.

	use crate::binemit::StackMap;
	use crate::ir::StackSlot;
	use crate::isa::CallConv;
	use crate::machinst::*;
	use crate::settings;

	use regalloc::{Reg, Set, SpillSlot, Writable};

	/// Trait implemented by an object that tracks ABI-related state (e.g., stack
	/// layout) and can generate code while emitting the body of a function.
	pub trait ABICallee {
	/// The instruction type for the ISA associated with this ABI.
	type I: VCodeInst;

	/// Does the ABI-body code need a temp reg? One will be provided to `init()`
	/// as the `maybe_tmp` arg if so.
	fn temp_needed(&self) -> bool;

	/// Initialize. This is called after the ABICallee is constructed because it
	/// may be provided with a temp vreg, which can only be allocated once the
	/// lowering context exists.
	fn init(&mut self, maybe_tmp: Option<Writable<Reg>>);

	/// Accumulate outgoing arguments. This ensures that at least SIZE bytes
	/// are allocated in the prologue to be available for use in function calls
	/// to hold arguments and/or return values. If this function is called
	/// multiple times, the maximum of all SIZE values will be available.
	fn accumulate_outgoing_args_size(&mut self, size: u32);

	/// Get the settings controlling this function's compilation.
	fn flags(&self) -> &settings::Flags;

	/// Get the calling convention implemented by this ABI object.
	fn call_conv(&self) -> CallConv;

	/// Get the liveins of the function.
	fn liveins(&self) -> Set<RealReg>;

	/// Get the liveouts of the function.
	fn liveouts(&self) -> Set<RealReg>;

	/// Number of arguments.
	fn num_args(&self) -> usize;

	/// Number of return values.
	fn num_retvals(&self) -> usize;

	/// Number of stack slots (not spill slots).
	fn num_stackslots(&self) -> usize;

	/// Generate an instruction which copies an argument to a destination
	/// register.
	fn gen_copy_arg_to_reg(&self, idx: usize, into_reg: Writable<Reg>) -> Self::I;

	/// Is the given argument needed in the body (as opposed to, e.g., serving
	/// only as a special ABI-specific placeholder)? This controls whether
	/// lowering will copy it to a virtual reg use by CLIF instructions.
	fn arg_is_needed_in_body(&self, idx: usize) -> bool;

	/// Generate any setup instruction needed to save values to the
	/// return-value area. This is usually used when were are multiple return
	/// values or an otherwise large return value that must be passed on the
	/// stack; typically the ABI specifies an extra hidden argument that is a
	/// pointer to that memory.
	fn gen_retval_area_setup(&self) -> Option<Self::I>;

	/// Generate an instruction which copies a source register to a return value slot.
	fn gen_copy_reg_to_retval(&self, idx: usize, from_reg: Writable<Reg>) -> Vec<Self::I>;

	/// Generate a return instruction.
	fn gen_ret(&self) -> Self::I;

	/// Generate an epilogue placeholder. The returned instruction should return `true` from
	/// `is_epilogue_placeholder()`; this is used to indicate to the lowering driver when
	/// the epilogue should be inserted.
	fn gen_epilogue_placeholder(&self) -> Self::I;

	// -----------------------------------------------------------------
	// Every function above this line may only be called pre-regalloc.
	// Every function below this line may only be called post-regalloc.
	// `spillslots()` must be called before any other post-regalloc
	// function.
	// ----------------------------------------------------------------

	/// Update with the number of spillslots, post-regalloc.
	fn set_num_spillslots(&mut self, slots: usize);

	/// Update with the clobbered registers, post-regalloc.
	fn set_clobbered(&mut self, clobbered: Set<Writable<RealReg>>);

	/// Get the address of a stackslot.
	fn stackslot_addr(&self, slot: StackSlot, offset: u32, into_reg: Writable<Reg>) -> Self::I;

	/// Load from a stackslot.
	fn load_stackslot(
	&self,
	slot: StackSlot,
	offset: u32,
	ty: Type,
	into_reg: Writable<Reg>,
	) -> Self::I;

	/// Store to a stackslot.
	fn store_stackslot(&self, slot: StackSlot, offset: u32, ty: Type, from_reg: Reg) -> Self::I;

	/// Load from a spillslot.
	fn load_spillslot(&self, slot: SpillSlot, ty: Type, into_reg: Writable<Reg>) -> Self::I;

	/// Store to a spillslot.
	fn store_spillslot(&self, slot: SpillSlot, ty: Type, from_reg: Reg) -> Self::I;

	/// Generate a stack map, given a list of spillslots and the emission state
	/// at a given program point (prior to emission fo the safepointing
	/// instruction).
	fn spillslots_to_stack_map(
	&self,
	slots: &[SpillSlot],
	state: &<Self::I as MachInstEmit>::State,
	) -> StackMap;

	/// Generate a prologue, post-regalloc. This should include any stack
	/// frame or other setup necessary to use the other methods (`load_arg`,
	/// `store_retval`, and spillslot accesses.) `self` is mutable so that we
	/// can store information in it which will be useful when creating the
	/// epilogue.
	fn gen_prologue(&mut self) -> Vec<Self::I>;

	/// Generate an epilogue, post-regalloc. Note that this must generate the
	/// actual return instruction (rather than emitting this in the lowering
	/// logic), because the epilogue code comes before the return and the two are
	/// likely closely related.
	fn gen_epilogue(&self) -> Vec<Self::I>;

	/// Returns the full frame size for the given function, after prologue
	/// emission has run. This comprises the spill slots and stack-storage slots
	/// (but not storage for clobbered callee-save registers, arguments pushed
	/// at callsites within this function, or other ephemeral pushes). This is
	/// used for ABI variants where the client generates prologue/epilogue code,
	/// as in Baldrdash (SpiderMonkey integration).
	fn frame_size(&self) -> u32;

	/// Returns the size of arguments expected on the stack.
	fn stack_args_size(&self) -> u32;

	/// Get the spill-slot size.
	fn get_spillslot_size(&self, rc: RegClass, ty: Type) -> u32;

	/// Generate a spill. The type, if known, is given; this can be used to
	/// generate a store instruction optimized for the particular type rather
	/// than the RegClass (e.g., only F64 that resides in a V128 register). If
	/// no type is given, the implementation should spill the whole register.
	fn gen_spill(&self, to_slot: SpillSlot, from_reg: RealReg, ty: Option<Type>) -> Self::I;

	/// Generate a reload (fill). As for spills, the type may be given to allow
	/// a more optimized load instruction to be generated.
	fn gen_reload(
	&self,
	to_reg: Writable<RealReg>,
	from_slot: SpillSlot,
	ty: Option<Type>,
	) -> Self::I;

	/// Desired unwind info type.
	fn unwind_info_kind(&self) -> UnwindInfoKind;
	}

	/// Trait implemented by an object that tracks ABI-related state and can
	/// generate code while emitting a call to a function.
	///
	/// An instance of this trait returns information for a particular
	/// callsite. It will usually be computed from the called function's
	/// signature.
	///
	/// Unlike `ABICallee` above, methods on this trait are not invoked directly
	/// by the machine-independent code. Rather, the machine-specific lowering
	/// code will typically create an `ABICaller` when creating machine instructions
	/// for an IR call instruction inside `lower()`, directly emit the arg and
	/// and retval copies, and attach the register use/def info to the call.
	///
	/// This trait is thus provided for convenience to the backends.
	pub trait ABICaller {
	/// The instruction type for the ISA associated with this ABI.
	type I: VCodeInst;

	/// Get the number of arguments expected.
	fn num_args(&self) -> usize;

	/// Emit a copy of an argument value from a source register, prior to the call.
	fn emit_copy_reg_to_arg<C: LowerCtx<I = Self::I>>(
	&self,
	ctx: &mut C,
	idx: usize,
	from_reg: Reg,
	);

	/// Emit a copy a return value into a destination register, after the call returns.
	fn emit_copy_retval_to_reg<C: LowerCtx<I = Self::I>>(
	&self,
	ctx: &mut C,
	idx: usize,
	into_reg: Writable<Reg>,
	);

	/// Emit code to pre-adjust the stack, prior to argument copies and call.
	fn emit_stack_pre_adjust<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

	/// Emit code to post-adjust the satck, after call return and return-value copies.
	fn emit_stack_post_adjust<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

	/// Accumulate outgoing arguments. This ensures that the caller (as
	/// identified via the CTX argument) allocates enough space in the
	/// prologue to hold all arguments and return values for this call.
	/// There is no code emitted at the call site, everything is done
	/// in the caller's function prologue.
	fn accumulate_outgoing_args_size<C: LowerCtx<I = Self::I>>(&self, ctx: &mut C);

	/// Emit the call itself.
	///
	/// The returned instruction should have proper use- and def-sets according
	/// to the argument registers, return-value registers, and clobbered
	/// registers for this function signature in this ABI.
	///
	/// (Arg registers are uses, and retval registers are defs. Clobbered
	/// registers are also logically defs, but should never be read; their
	/// values are "defined" (to the regalloc) but "undefined" in every other
	/// sense.)
	///
	/// This function should only be called once, as it is allowed to re-use
	/// parts of the ABICaller object in emitting instructions.
	fn emit_call<C: LowerCtx<I = Self::I>>(&mut self, ctx: &mut C);
	}