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wasmtime/cranelift/codegen/src/machinst/abi.rs
Chris Fallin 835db11bea Support for SpiderMonkey's "Wasm ABI 2020". 
As part of a Wasm JIT update, SpiderMonkey is changing its internal
WebAssembly function ABI. The new ABI's frame format includes "caller
TLS" and "callee TLS" slots. The details of where these come from are
not important; from Cranelift's point of view, the only relevant
requirement is that we have two on-stack args that are always present
(offsetting other on-stack args), and that we define special argument
purposes so that we can supply values for these slots.

Note that this adds a *new* ABI (a variant of the Baldrdash ABI) because
we do not want to tightly couple the landing of this PR to the landing
of the changes in SpiderMonkey; it's better if both the old and new
behavior remain available in Cranelift, so SpiderMonkey can continue to
vendor Cranelift even if it does not land (or backs out) the ABI change.

Furthermore, note that this needs to be a Cranelift-level change (i.e.
cannot be done purely from the translator environment implementation)
because the special TLS arguments must always go on the stack, which
would not otherwise happen with the usual argument-placement logic; and
there is no primitive to push a value directly in CLIF code (the notion
of a stack frame is a lower-level concept).
2020-09-30 14:55:56 -07:00

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//! ABI definitions.
use crate::binemit::StackMap;
use crate::ir::StackSlot;
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>>);
/// Get the settings controlling this function's compilation.
fn flags(&self) -> &settings::Flags;
/// 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;
}
/// 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);
/// 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);
}
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