pub struct ReplaceBuilder<'f> { /* private fields */ }
Expand description

Instruction builder that replaces an existing instruction.

The inserted instruction will have the same Inst number as the old one.

If the old instruction still has result values attached, it is assumed that the new instruction produces the same number and types of results. The old result values are preserved. If the replacement instruction format does not support multiple results, the builder panics. It is a bug to leave result values dangling.

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impl<'f> ReplaceBuilder<'f>

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pub fn new(dfg: &'f mut DataFlowGraph, inst: Inst) -> Self

Create a ReplaceBuilder that will overwrite inst.

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impl<'f> InstBuilderBase<'f> for ReplaceBuilder<'f>

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fn data_flow_graph(&self) -> &DataFlowGraph

Get an immutable reference to the data flow graph that will hold the constructed instructions.
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fn data_flow_graph_mut(&mut self) -> &mut DataFlowGraph

Get a mutable reference to the data flow graph that will hold the constructed instructions.
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fn build( self, data: InstructionData, ctrl_typevar: Type ) -> (Inst, &'f mut DataFlowGraph)

Insert an instruction and return a reference to it, consuming the builder. Read more

Auto Trait Implementations§

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impl<'f> RefUnwindSafe for ReplaceBuilder<'f>

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impl<'f> Send for ReplaceBuilder<'f>

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impl<'f> Sync for ReplaceBuilder<'f>

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impl<'f> Unpin for ReplaceBuilder<'f>

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impl<'f> !UnwindSafe for ReplaceBuilder<'f>

Blanket Implementations§

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impl<T> Any for Twhere T: 'static + ?Sized,

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fn type_id(&self) -> TypeId

Gets the TypeId of self. Read more
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impl<T> Borrow<T> for Twhere T: ?Sized,

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fn borrow(&self) -> &T

Immutably borrows from an owned value. Read more
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impl<T> BorrowMut<T> for Twhere T: ?Sized,

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fn borrow_mut(&mut self) -> &mut T

Mutably borrows from an owned value. Read more
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impl<T> From<T> for T

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fn from(t: T) -> T

Returns the argument unchanged.

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impl<'f, T> InstBuilder<'f> for Twhere T: InstBuilderBase<'f>,

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fn jump(self, block_call_label: Block, block_call_args: &[Value]) -> Inst

Jump. Read more
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fn brif( self, c: Value, block_then_label: Block, block_then_args: &[Value], block_else_label: Block, block_else_args: &[Value] ) -> Inst

Conditional branch when cond is non-zero. Read more
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fn br_table(self, x: Value, label: Block, JT: JumpTable) -> Inst

Indirect branch via jump table. Read more
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fn debugtrap(self) -> Inst

Encodes an assembly debug trap.
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fn trap<T1: Into<TrapCode>>(self, code: T1) -> Inst

Terminate execution unconditionally. Read more
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fn trapz<T1: Into<TrapCode>>(self, c: Value, code: T1) -> Inst

Trap when zero. Read more
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fn resumable_trap<T1: Into<TrapCode>>(self, code: T1) -> Inst

A resumable trap. Read more
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fn trapnz<T1: Into<TrapCode>>(self, c: Value, code: T1) -> Inst

Trap when non-zero. Read more
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fn resumable_trapnz<T1: Into<TrapCode>>(self, c: Value, code: T1) -> Inst

A resumable trap to be called when the passed condition is non-zero. Read more
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fn return_(self, rvals: &[Value]) -> Inst

Return from the function. Read more
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fn call(self, FN: FuncRef, args: &[Value]) -> Inst

Direct function call. Read more
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fn call_indirect(self, SIG: SigRef, callee: Value, args: &[Value]) -> Inst

Indirect function call. Read more
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fn return_call(self, FN: FuncRef, args: &[Value]) -> Inst

Direct tail call. Read more
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fn return_call_indirect( self, SIG: SigRef, callee: Value, args: &[Value] ) -> Inst

Indirect tail call. Read more
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fn func_addr(self, iAddr: Type, FN: FuncRef) -> Value

Get the address of a function. Read more
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fn splat(self, TxN: Type, x: Value) -> Value

Vector splat. Read more
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fn swizzle(self, TxN: Type, x: Value, y: Value) -> Value

Vector swizzle. Read more
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fn insertlane<T1: Into<Uimm8>>(self, x: Value, y: Value, Idx: T1) -> Value

Insert y as lane Idx in x. Read more
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fn extractlane<T1: Into<Uimm8>>(self, x: Value, Idx: T1) -> Value

Extract lane Idx from x. Read more
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fn smin(self, x: Value, y: Value) -> Value

Signed integer minimum. Read more
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fn umin(self, x: Value, y: Value) -> Value

Unsigned integer minimum. Read more
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fn smax(self, x: Value, y: Value) -> Value

Signed integer maximum. Read more
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fn umax(self, x: Value, y: Value) -> Value

Unsigned integer maximum. Read more
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fn avg_round(self, x: Value, y: Value) -> Value

Unsigned average with rounding: a := (x + y + 1) // 2 Read more
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fn uadd_sat(self, x: Value, y: Value) -> Value

Add with unsigned saturation. Read more
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fn sadd_sat(self, x: Value, y: Value) -> Value

Add with signed saturation. Read more
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fn usub_sat(self, x: Value, y: Value) -> Value

Subtract with unsigned saturation. Read more
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fn ssub_sat(self, x: Value, y: Value) -> Value

Subtract with signed saturation. Read more
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fn load<T1: Into<MemFlags>, T2: Into<Offset32>>( self, Mem: Type, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load from memory at p + Offset. Read more
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fn store<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, x: Value, p: Value, Offset: T2 ) -> Inst

Store x to memory at p + Offset. Read more
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fn uload8<T1: Into<MemFlags>, T2: Into<Offset32>>( self, iExt8: Type, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 8 bits from memory at p + Offset and zero-extend. Read more
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fn sload8<T1: Into<MemFlags>, T2: Into<Offset32>>( self, iExt8: Type, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 8 bits from memory at p + Offset and sign-extend. Read more
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fn istore8<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, x: Value, p: Value, Offset: T2 ) -> Inst

Store the low 8 bits of x to memory at p + Offset. Read more
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fn uload16<T1: Into<MemFlags>, T2: Into<Offset32>>( self, iExt16: Type, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 16 bits from memory at p + Offset and zero-extend. Read more
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fn sload16<T1: Into<MemFlags>, T2: Into<Offset32>>( self, iExt16: Type, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 16 bits from memory at p + Offset and sign-extend. Read more
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fn istore16<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, x: Value, p: Value, Offset: T2 ) -> Inst

Store the low 16 bits of x to memory at p + Offset. Read more
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fn uload32<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 32 bits from memory at p + Offset and zero-extend. Read more
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fn sload32<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load 32 bits from memory at p + Offset and sign-extend. Read more
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fn istore32<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, x: Value, p: Value, Offset: T2 ) -> Inst

Store the low 32 bits of x to memory at p + Offset. Read more
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fn uload8x8<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load an 8x8 vector (64 bits) from memory at p + Offset and zero-extend into an i16x8 vector. Read more
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fn sload8x8<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load an 8x8 vector (64 bits) from memory at p + Offset and sign-extend into an i16x8 vector. Read more
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fn uload16x4<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load a 16x4 vector (64 bits) from memory at p + Offset and zero-extend into an i32x4 vector. Read more
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fn sload16x4<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load a 16x4 vector (64 bits) from memory at p + Offset and sign-extend into an i32x4 vector. Read more
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fn uload32x2<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load an 32x2 vector (64 bits) from memory at p + Offset and zero-extend into an i64x2 vector. Read more
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fn sload32x2<T1: Into<MemFlags>, T2: Into<Offset32>>( self, MemFlags: T1, p: Value, Offset: T2 ) -> Value

Load a 32x2 vector (64 bits) from memory at p + Offset and sign-extend into an i64x2 vector. Read more
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fn stack_load<T1: Into<Offset32>>( self, Mem: Type, SS: StackSlot, Offset: T1 ) -> Value

Load a value from a stack slot at the constant offset. Read more
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fn stack_store<T1: Into<Offset32>>( self, x: Value, SS: StackSlot, Offset: T1 ) -> Inst

Store a value to a stack slot at a constant offset. Read more
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fn stack_addr<T1: Into<Offset32>>( self, iAddr: Type, SS: StackSlot, Offset: T1 ) -> Value

Get the address of a stack slot. Read more
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fn dynamic_stack_load(self, Mem: Type, DSS: DynamicStackSlot) -> Value

Load a value from a dynamic stack slot. Read more
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fn dynamic_stack_store(self, x: Value, DSS: DynamicStackSlot) -> Inst

Store a value to a dynamic stack slot. Read more
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fn dynamic_stack_addr(self, iAddr: Type, DSS: DynamicStackSlot) -> Value

Get the address of a dynamic stack slot. Read more
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fn global_value(self, Mem: Type, GV: GlobalValue) -> Value

Compute the value of global GV. Read more
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fn symbol_value(self, Mem: Type, GV: GlobalValue) -> Value

Compute the value of global GV, which is a symbolic value. Read more
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fn tls_value(self, Mem: Type, GV: GlobalValue) -> Value

Compute the value of global GV, which is a TLS (thread local storage) value. Read more
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fn get_pinned_reg(self, iAddr: Type) -> Value

Gets the content of the pinned register, when it’s enabled. Read more
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fn set_pinned_reg(self, addr: Value) -> Inst

Sets the content of the pinned register, when it’s enabled. Read more
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fn get_frame_pointer(self, iAddr: Type) -> Value

Get the address in the frame pointer register. Read more
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fn get_stack_pointer(self, iAddr: Type) -> Value

Get the address in the stack pointer register. Read more
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fn get_return_address(self, iAddr: Type) -> Value

Get the PC where this function will transfer control to when it returns. Read more
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fn table_addr<T1: Into<Offset32>>( self, iAddr: Type, T: Table, p: Value, Offset: T1 ) -> Value

Bounds check and compute absolute address of a table entry. Read more
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fn iconst<T1: Into<Imm64>>(self, NarrowInt: Type, N: T1) -> Value

Integer constant. Read more
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fn f32const<T1: Into<Ieee32>>(self, N: T1) -> Value

Floating point constant. Read more
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fn f64const<T1: Into<Ieee64>>(self, N: T1) -> Value

Floating point constant. Read more
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fn vconst<T1: Into<Constant>>(self, TxN: Type, N: T1) -> Value

SIMD vector constant. Read more
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fn shuffle<T1: Into<Immediate>>(self, a: Value, b: Value, mask: T1) -> Value

SIMD vector shuffle. Read more
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fn null(self, Ref: Type) -> Value

Null constant value for reference types. Read more
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fn nop(self) -> Inst

Just a dummy instruction. Read more
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fn select(self, c: Value, x: Value, y: Value) -> Value

Conditional select. Read more
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fn select_spectre_guard(self, c: Value, x: Value, y: Value) -> Value

Conditional select intended for Spectre guards. Read more
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fn bitselect(self, c: Value, x: Value, y: Value) -> Value

Conditional select of bits. Read more
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fn vselect(self, c: Value, x: Value, y: Value) -> Value

Vector lane select. Read more
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fn vany_true(self, a: Value) -> Value

Reduce a vector to a scalar boolean. Read more
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fn vall_true(self, a: Value) -> Value

Reduce a vector to a scalar boolean. Read more
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fn vhigh_bits(self, Int: Type, a: Value) -> Value

Reduce a vector to a scalar integer. Read more
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fn icmp<T1: Into<IntCC>>(self, Cond: T1, x: Value, y: Value) -> Value

Integer comparison. Read more
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fn icmp_imm<T1: Into<IntCC>, T2: Into<Imm64>>( self, Cond: T1, x: Value, Y: T2 ) -> Value

Compare scalar integer to a constant. Read more
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fn iadd(self, x: Value, y: Value) -> Value

Wrapping integer addition: a := x + y \pmod{2^B}. Read more
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fn isub(self, x: Value, y: Value) -> Value

Wrapping integer subtraction: a := x - y \pmod{2^B}. Read more
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fn ineg(self, x: Value) -> Value

Integer negation: a := -x \pmod{2^B}. Read more
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fn iabs(self, x: Value) -> Value

Integer absolute value with wrapping: a := |x|. Read more
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fn imul(self, x: Value, y: Value) -> Value

Wrapping integer multiplication: a := x y \pmod{2^B}. Read more
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fn umulhi(self, x: Value, y: Value) -> Value

Unsigned integer multiplication, producing the high half of a double-length result. Read more
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fn smulhi(self, x: Value, y: Value) -> Value

Signed integer multiplication, producing the high half of a double-length result. Read more
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fn sqmul_round_sat(self, x: Value, y: Value) -> Value

Fixed-point multiplication of numbers in the QN format, where N + 1 is the number bitwidth: a := signed_saturate((x * y + 1 << (Q - 1)) >> Q) Read more
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fn udiv(self, x: Value, y: Value) -> Value

Unsigned integer division: a := \lfloor {x \over y} \rfloor. Read more
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fn sdiv(self, x: Value, y: Value) -> Value

Signed integer division rounded toward zero: a := sign(xy) \lfloor {|x| \over |y|}\rfloor. Read more
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fn urem(self, x: Value, y: Value) -> Value

Unsigned integer remainder. Read more
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fn srem(self, x: Value, y: Value) -> Value

Signed integer remainder. The result has the sign of the dividend. Read more
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fn iadd_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Add immediate integer. Read more
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fn imul_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Integer multiplication by immediate constant. Read more
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fn udiv_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Unsigned integer division by an immediate constant. Read more
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fn sdiv_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Signed integer division by an immediate constant. Read more
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fn urem_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Unsigned integer remainder with immediate divisor. Read more
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fn srem_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Signed integer remainder with immediate divisor. Read more
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fn irsub_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Immediate reverse wrapping subtraction: a := Y - x \pmod{2^B}. Read more
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fn iadd_cin(self, x: Value, y: Value, c_in: Value) -> Value

Add integers with carry in. Read more
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fn iadd_cout(self, x: Value, y: Value) -> (Value, Value)

Add integers with carry out. Read more
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fn iadd_carry(self, x: Value, y: Value, c_in: Value) -> (Value, Value)

Add integers with carry in and out. Read more
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fn uadd_overflow_trap<T1: Into<TrapCode>>( self, x: Value, y: Value, code: T1 ) -> Value

Unsigned addition of x and y, trapping if the result overflows. Read more
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fn isub_bin(self, x: Value, y: Value, b_in: Value) -> Value

Subtract integers with borrow in. Read more
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fn isub_bout(self, x: Value, y: Value) -> (Value, Value)

Subtract integers with borrow out. Read more
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fn isub_borrow(self, x: Value, y: Value, b_in: Value) -> (Value, Value)

Subtract integers with borrow in and out. Read more
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fn band(self, x: Value, y: Value) -> Value

Bitwise and. Read more
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fn bor(self, x: Value, y: Value) -> Value

Bitwise or. Read more
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fn bxor(self, x: Value, y: Value) -> Value

Bitwise xor. Read more
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fn bnot(self, x: Value) -> Value

Bitwise not. Read more
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fn band_not(self, x: Value, y: Value) -> Value

Bitwise and not. Read more
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fn bor_not(self, x: Value, y: Value) -> Value

Bitwise or not. Read more
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fn bxor_not(self, x: Value, y: Value) -> Value

Bitwise xor not. Read more
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fn band_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Bitwise and with immediate. Read more
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fn bor_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Bitwise or with immediate. Read more
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fn bxor_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Bitwise xor with immediate. Read more
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fn rotl(self, x: Value, y: Value) -> Value

Rotate left. Read more
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fn rotr(self, x: Value, y: Value) -> Value

Rotate right. Read more
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fn rotl_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Rotate left by immediate. Read more
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fn rotr_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Rotate right by immediate. Read more
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fn ishl(self, x: Value, y: Value) -> Value

Integer shift left. Shift the bits in x towards the MSB by y places. Shift in zero bits to the LSB. Read more
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fn ushr(self, x: Value, y: Value) -> Value

Unsigned shift right. Shift bits in x towards the LSB by y places, shifting in zero bits to the MSB. Also called a logical shift. Read more
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fn sshr(self, x: Value, y: Value) -> Value

Signed shift right. Shift bits in x towards the LSB by y places, shifting in sign bits to the MSB. Also called an arithmetic shift. Read more
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fn ishl_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Integer shift left by immediate. Read more
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fn ushr_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Unsigned shift right by immediate. Read more
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fn sshr_imm<T1: Into<Imm64>>(self, x: Value, Y: T1) -> Value

Signed shift right by immediate. Read more
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fn bitrev(self, x: Value) -> Value

Reverse the bits of a integer. Read more
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fn clz(self, x: Value) -> Value

Count leading zero bits. Read more
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fn cls(self, x: Value) -> Value

Count leading sign bits. Read more
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fn ctz(self, x: Value) -> Value

Count trailing zeros. Read more
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fn bswap(self, x: Value) -> Value

Reverse the byte order of an integer. Read more
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fn popcnt(self, x: Value) -> Value

Population count Read more
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fn fcmp<T1: Into<FloatCC>>(self, Cond: T1, x: Value, y: Value) -> Value

Floating point comparison. Read more
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fn fadd(self, x: Value, y: Value) -> Value

Floating point addition. Read more
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fn fsub(self, x: Value, y: Value) -> Value

Floating point subtraction. Read more
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fn fmul(self, x: Value, y: Value) -> Value

Floating point multiplication. Read more
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fn fdiv(self, x: Value, y: Value) -> Value

Floating point division. Read more
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fn sqrt(self, x: Value) -> Value

Floating point square root. Read more
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fn fma(self, x: Value, y: Value, z: Value) -> Value

Floating point fused multiply-and-add. Read more
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fn fneg(self, x: Value) -> Value

Floating point negation. Read more
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fn fabs(self, x: Value) -> Value

Floating point absolute value. Read more
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fn fcopysign(self, x: Value, y: Value) -> Value

Floating point copy sign. Read more
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fn fmin(self, x: Value, y: Value) -> Value

Floating point minimum, propagating NaNs using the WebAssembly rules. Read more
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fn fmin_pseudo(self, x: Value, y: Value) -> Value

Floating point pseudo-minimum, propagating NaNs. This behaves differently from fmin. See https://github.com/WebAssembly/simd/pull/122 for background. Read more
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fn fmax(self, x: Value, y: Value) -> Value

Floating point maximum, propagating NaNs using the WebAssembly rules. Read more
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fn fmax_pseudo(self, x: Value, y: Value) -> Value

Floating point pseudo-maximum, propagating NaNs. This behaves differently from fmax. See https://github.com/WebAssembly/simd/pull/122 for background. Read more
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fn ceil(self, x: Value) -> Value

Round floating point round to integral, towards positive infinity. Read more
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fn floor(self, x: Value) -> Value

Round floating point round to integral, towards negative infinity. Read more
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fn trunc(self, x: Value) -> Value

Round floating point round to integral, towards zero. Read more
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fn nearest(self, x: Value) -> Value

Round floating point round to integral, towards nearest with ties to even. Read more
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fn is_null(self, x: Value) -> Value

Reference verification. Read more
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fn is_invalid(self, x: Value) -> Value

Reference verification. Read more
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fn bitcast<T1: Into<MemFlags>>( self, MemTo: Type, MemFlags: T1, x: Value ) -> Value

Reinterpret the bits in x as a different type. Read more
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fn scalar_to_vector(self, TxN: Type, s: Value) -> Value

Copies a scalar value to a vector value. The scalar is copied into the least significant lane of the vector, and all other lanes will be zero. Read more
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fn bmask(self, IntTo: Type, x: Value) -> Value

Convert x to an integer mask. Read more
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fn ireduce(self, IntTo: Type, x: Value) -> Value

Convert x to a smaller integer type by discarding the most significant bits. Read more
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fn snarrow(self, x: Value, y: Value) -> Value

Combine x and y into a vector with twice the lanes but half the integer width while saturating overflowing values to the signed maximum and minimum. Read more
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fn unarrow(self, x: Value, y: Value) -> Value

Combine x and y into a vector with twice the lanes but half the integer width while saturating overflowing values to the unsigned maximum and minimum. Read more
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fn uunarrow(self, x: Value, y: Value) -> Value

Combine x and y into a vector with twice the lanes but half the integer width while saturating overflowing values to the unsigned maximum and minimum. Read more
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fn swiden_low(self, x: Value) -> Value

Widen the low lanes of x using signed extension. Read more
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fn swiden_high(self, x: Value) -> Value

Widen the high lanes of x using signed extension. Read more
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fn uwiden_low(self, x: Value) -> Value

Widen the low lanes of x using unsigned extension. Read more
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fn uwiden_high(self, x: Value) -> Value

Widen the high lanes of x using unsigned extension. Read more
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fn iadd_pairwise(self, x: Value, y: Value) -> Value

Does lane-wise integer pairwise addition on two operands, putting the combined results into a single vector result. Here a pair refers to adjacent lanes in a vector, i.e. i2 + (i2+1) for i == num_lanes/2. The first operand pairwise add results will make up the low half of the resulting vector while the second operand pairwise add results will make up the upper half of the resulting vector. Read more
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fn widening_pairwise_dot_product_s(self, x: Value, y: Value) -> Value

Takes corresponding elements in x and y, performs a sign-extending length-doubling multiplication on them, then adds adjacent pairs of elements to form the result. For example, if the input vectors are [x3, x2, x1, x0] and [y3, y2, y1, y0], it produces the vector [r1, r0], where r1 = sx(x3) * sx(y3) + sx(x2) * sx(y2) and r0 = sx(x1) * sx(y1) + sx(x0) * sx(y0), and sx(n) sign-extends n to twice its width. Read more
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fn uextend(self, IntTo: Type, x: Value) -> Value

Convert x to a larger integer type by zero-extending. Read more
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fn sextend(self, IntTo: Type, x: Value) -> Value

Convert x to a larger integer type by sign-extending. Read more
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fn fpromote(self, FloatTo: Type, x: Value) -> Value

Convert x to a larger floating point format. Read more
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fn fdemote(self, FloatTo: Type, x: Value) -> Value

Convert x to a smaller floating point format. Read more
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fn fvdemote(self, x: Value) -> Value

Convert x to a smaller floating point format. Read more
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fn fvpromote_low(self, a: Value) -> Value

Converts packed single precision floating point to packed double precision floating point. Read more
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fn fcvt_to_uint(self, IntTo: Type, x: Value) -> Value

Converts floating point scalars to unsigned integer. Read more
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fn fcvt_to_sint(self, IntTo: Type, x: Value) -> Value

Converts floating point scalars to signed integer. Read more
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fn fcvt_to_uint_sat(self, IntTo: Type, x: Value) -> Value

Convert floating point to unsigned integer as fcvt_to_uint does, but saturates the input instead of trapping. NaN and negative values are converted to 0. Read more
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fn fcvt_to_sint_sat(self, IntTo: Type, x: Value) -> Value

Convert floating point to signed integer as fcvt_to_sint does, but saturates the input instead of trapping. NaN values are converted to 0. Read more
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fn fcvt_from_uint(self, FloatTo: Type, x: Value) -> Value

Convert unsigned integer to floating point. Read more
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fn fcvt_from_sint(self, FloatTo: Type, x: Value) -> Value

Convert signed integer to floating point. Read more
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fn fcvt_low_from_sint(self, FloatTo: Type, x: Value) -> Value

Converts packed signed 32-bit integers to packed double precision floating point. Read more
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fn isplit(self, x: Value) -> (Value, Value)

Split an integer into low and high parts. Read more
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fn iconcat(self, lo: Value, hi: Value) -> Value

Concatenate low and high bits to form a larger integer type. Read more
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fn atomic_rmw<T1: Into<MemFlags>, T2: Into<AtomicRmwOp>>( self, AtomicMem: Type, MemFlags: T1, AtomicRmwOp: T2, p: Value, x: Value ) -> Value

Atomically read-modify-write memory at p, with second operand x. The old value is returned. p has the type of the target word size, and x may be an integer type of 8, 16, 32 or 64 bits, even on a 32-bit target. The type of the returned value is the same as the type of x. This operation is sequentially consistent and creates happens-before edges that order normal (non-atomic) loads and stores. Read more
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fn atomic_cas<T1: Into<MemFlags>>( self, MemFlags: T1, p: Value, e: Value, x: Value ) -> Value

Perform an atomic compare-and-swap operation on memory at p, with expected value e, storing x if the value at p equals e. The old value at p is returned, regardless of whether the operation succeeds or fails. p has the type of the target word size, and x and e must have the same type and the same size, which may be an integer type of 8, 16, 32 or 64 bits, even on a 32-bit target. The type of the returned value is the same as the type of x and e. This operation is sequentially consistent and creates happens-before edges that order normal (non-atomic) loads and stores. Read more
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fn atomic_load<T1: Into<MemFlags>>( self, AtomicMem: Type, MemFlags: T1, p: Value ) -> Value

Atomically load from memory at p. Read more
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fn atomic_store<T1: Into<MemFlags>>( self, MemFlags: T1, x: Value, p: Value ) -> Inst

Atomically store x to memory at p. Read more
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fn fence(self) -> Inst

A memory fence. This must provide ordering to ensure that, at a minimum, neither loads nor stores of any kind may move forwards or backwards across the fence. This operation is sequentially consistent.
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fn extract_vector<T1: Into<Uimm8>>(self, x: Value, y: T1) -> Value

Return a fixed length sub vector, extracted from a dynamic vector. Read more
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fn AtomicCas( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, arg0: Value, arg1: Value, arg2: Value ) -> (Inst, &'f mut DataFlowGraph)

AtomicCas(imms=(flags: ir::MemFlags), vals=3, blocks=0)
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fn AtomicRmw( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, op: AtomicRmwOp, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

AtomicRmw(imms=(flags: ir::MemFlags, op: ir::AtomicRmwOp), vals=2, blocks=0)
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fn Binary( self, opcode: Opcode, ctrl_typevar: Type, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

Binary(imms=(), vals=2, blocks=0)
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fn BinaryImm64( self, opcode: Opcode, ctrl_typevar: Type, imm: Imm64, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

BinaryImm64(imms=(imm: ir::immediates::Imm64), vals=1, blocks=0)
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fn BinaryImm8( self, opcode: Opcode, ctrl_typevar: Type, imm: Uimm8, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

BinaryImm8(imms=(imm: ir::immediates::Uimm8), vals=1, blocks=0)
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fn BranchTable( self, opcode: Opcode, ctrl_typevar: Type, destination: Block, table: JumpTable, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

BranchTable(imms=(destination: ir::Block, table: ir::JumpTable), vals=1, blocks=0)
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fn Brif( self, opcode: Opcode, ctrl_typevar: Type, block0: BlockCall, block1: BlockCall, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

Brif(imms=(), vals=1, blocks=2)
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fn Call( self, opcode: Opcode, ctrl_typevar: Type, func_ref: FuncRef, args: ValueList ) -> (Inst, &'f mut DataFlowGraph)

Call(imms=(func_ref: ir::FuncRef), vals=0, blocks=0)
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fn CallIndirect( self, opcode: Opcode, ctrl_typevar: Type, sig_ref: SigRef, args: ValueList ) -> (Inst, &'f mut DataFlowGraph)

CallIndirect(imms=(sig_ref: ir::SigRef), vals=1, blocks=0)
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fn CondTrap( self, opcode: Opcode, ctrl_typevar: Type, code: TrapCode, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

CondTrap(imms=(code: ir::TrapCode), vals=1, blocks=0)
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fn DynamicStackLoad( self, opcode: Opcode, ctrl_typevar: Type, dynamic_stack_slot: DynamicStackSlot ) -> (Inst, &'f mut DataFlowGraph)

DynamicStackLoad(imms=(dynamic_stack_slot: ir::DynamicStackSlot), vals=0, blocks=0)
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fn DynamicStackStore( self, opcode: Opcode, ctrl_typevar: Type, dynamic_stack_slot: DynamicStackSlot, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

DynamicStackStore(imms=(dynamic_stack_slot: ir::DynamicStackSlot), vals=1, blocks=0)
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fn FloatCompare( self, opcode: Opcode, ctrl_typevar: Type, cond: FloatCC, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

FloatCompare(imms=(cond: ir::condcodes::FloatCC), vals=2, blocks=0)
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fn FuncAddr( self, opcode: Opcode, ctrl_typevar: Type, func_ref: FuncRef ) -> (Inst, &'f mut DataFlowGraph)

FuncAddr(imms=(func_ref: ir::FuncRef), vals=0, blocks=0)
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fn IntAddTrap( self, opcode: Opcode, ctrl_typevar: Type, code: TrapCode, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

IntAddTrap(imms=(code: ir::TrapCode), vals=2, blocks=0)
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fn IntCompare( self, opcode: Opcode, ctrl_typevar: Type, cond: IntCC, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

IntCompare(imms=(cond: ir::condcodes::IntCC), vals=2, blocks=0)
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fn IntCompareImm( self, opcode: Opcode, ctrl_typevar: Type, cond: IntCC, imm: Imm64, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

IntCompareImm(imms=(cond: ir::condcodes::IntCC, imm: ir::immediates::Imm64), vals=1, blocks=0)
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fn Jump( self, opcode: Opcode, ctrl_typevar: Type, block0: BlockCall ) -> (Inst, &'f mut DataFlowGraph)

Jump(imms=(), vals=0, blocks=1)
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fn Load( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, offset: Offset32, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

Load(imms=(flags: ir::MemFlags, offset: ir::immediates::Offset32), vals=1, blocks=0)
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fn LoadNoOffset( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

LoadNoOffset(imms=(flags: ir::MemFlags), vals=1, blocks=0)
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fn MultiAry( self, opcode: Opcode, ctrl_typevar: Type, args: ValueList ) -> (Inst, &'f mut DataFlowGraph)

MultiAry(imms=(), vals=0, blocks=0)
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fn NullAry( self, opcode: Opcode, ctrl_typevar: Type ) -> (Inst, &'f mut DataFlowGraph)

NullAry(imms=(), vals=0, blocks=0)
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fn Shuffle( self, opcode: Opcode, ctrl_typevar: Type, imm: Immediate, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

Shuffle(imms=(imm: ir::Immediate), vals=2, blocks=0)
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fn StackLoad( self, opcode: Opcode, ctrl_typevar: Type, stack_slot: StackSlot, offset: Offset32 ) -> (Inst, &'f mut DataFlowGraph)

StackLoad(imms=(stack_slot: ir::StackSlot, offset: ir::immediates::Offset32), vals=0, blocks=0)
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fn StackStore( self, opcode: Opcode, ctrl_typevar: Type, stack_slot: StackSlot, offset: Offset32, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

StackStore(imms=(stack_slot: ir::StackSlot, offset: ir::immediates::Offset32), vals=1, blocks=0)
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fn Store( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, offset: Offset32, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

Store(imms=(flags: ir::MemFlags, offset: ir::immediates::Offset32), vals=2, blocks=0)
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fn StoreNoOffset( self, opcode: Opcode, ctrl_typevar: Type, flags: MemFlags, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

StoreNoOffset(imms=(flags: ir::MemFlags), vals=2, blocks=0)
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fn TableAddr( self, opcode: Opcode, ctrl_typevar: Type, table: Table, offset: Offset32, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

TableAddr(imms=(table: ir::Table, offset: ir::immediates::Offset32), vals=1, blocks=0)
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fn Ternary( self, opcode: Opcode, ctrl_typevar: Type, arg0: Value, arg1: Value, arg2: Value ) -> (Inst, &'f mut DataFlowGraph)

Ternary(imms=(), vals=3, blocks=0)
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fn TernaryImm8( self, opcode: Opcode, ctrl_typevar: Type, imm: Uimm8, arg0: Value, arg1: Value ) -> (Inst, &'f mut DataFlowGraph)

TernaryImm8(imms=(imm: ir::immediates::Uimm8), vals=2, blocks=0)
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fn Trap( self, opcode: Opcode, ctrl_typevar: Type, code: TrapCode ) -> (Inst, &'f mut DataFlowGraph)

Trap(imms=(code: ir::TrapCode), vals=0, blocks=0)
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fn Unary( self, opcode: Opcode, ctrl_typevar: Type, arg0: Value ) -> (Inst, &'f mut DataFlowGraph)

Unary(imms=(), vals=1, blocks=0)
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fn UnaryConst( self, opcode: Opcode, ctrl_typevar: Type, constant_handle: Constant ) -> (Inst, &'f mut DataFlowGraph)

UnaryConst(imms=(constant_handle: ir::Constant), vals=0, blocks=0)
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fn UnaryGlobalValue( self, opcode: Opcode, ctrl_typevar: Type, global_value: GlobalValue ) -> (Inst, &'f mut DataFlowGraph)

UnaryGlobalValue(imms=(global_value: ir::GlobalValue), vals=0, blocks=0)
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fn UnaryIeee32( self, opcode: Opcode, ctrl_typevar: Type, imm: Ieee32 ) -> (Inst, &'f mut DataFlowGraph)

UnaryIeee32(imms=(imm: ir::immediates::Ieee32), vals=0, blocks=0)
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fn UnaryIeee64( self, opcode: Opcode, ctrl_typevar: Type, imm: Ieee64 ) -> (Inst, &'f mut DataFlowGraph)

UnaryIeee64(imms=(imm: ir::immediates::Ieee64), vals=0, blocks=0)
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fn UnaryImm( self, opcode: Opcode, ctrl_typevar: Type, imm: Imm64 ) -> (Inst, &'f mut DataFlowGraph)

UnaryImm(imms=(imm: ir::immediates::Imm64), vals=0, blocks=0)
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impl<T, U> Into<U> for Twhere U: From<T>,

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fn into(self) -> U

Calls U::from(self).

That is, this conversion is whatever the implementation of From<T> for U chooses to do.

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impl<T, U> TryFrom<U> for Twhere U: Into<T>,

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type Error = Infallible

The type returned in the event of a conversion error.
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fn try_from(value: U) -> Result<T, <T as TryFrom<U>>::Error>

Performs the conversion.
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impl<T, U> TryInto<U> for Twhere U: TryFrom<T>,

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type Error = <U as TryFrom<T>>::Error

The type returned in the event of a conversion error.
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fn try_into(self) -> Result<U, <U as TryFrom<T>>::Error>

Performs the conversion.