;; Extern type definitions and constructors for the x64 `MachInst` type.
;;;; `MInst` ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Don't build `MInst` variants directly, in general. Instead, use the
;; instruction-emitting helpers defined further down.
(type MInst nodebug
(enum
;; =========================================
;; Integer instructions.
;; A synthetic instruction sequence used as part of the lowering of the
;; `srem` instruction which returns 0 if the divisor is -1 and
;; otherwise executes an `idiv` instruction.
;;
;; Note that this does not check for 0 as that's expected to be done
;; separately. Also note that 8-bit types don't use this and use
;; `CheckedSRemSeq8` instead.
(CheckedSRemSeq (size OperandSize)
(dividend_lo Gpr)
(dividend_hi Gpr)
(divisor Gpr)
(dst_quotient WritableGpr)
(dst_remainder WritableGpr))
;; Same as above but for 8-bit types.
(CheckedSRemSeq8 (dividend Gpr)
(divisor Gpr)
(dst WritableGpr))
;; Like `MovRR` but with a physical register source (for implementing
;; CLIF instructions like `get_stack_pointer`).
(MovFromPReg (src PReg)
(dst WritableGpr))
;; Like `MovRR` but with a physical register destination (for
;; implementing CLIF instructions like `set_pinned_reg`).
(MovToPReg (src Gpr)
(dst PReg))
;; =========================================
;; Conditional moves.
;; XMM conditional move; overwrites the destination register.
(XmmCmove (ty Type)
(cc CC)
(consequent Xmm)
(alternative Xmm)
(dst WritableXmm))
;; =========================================
;; Stack manipulation.
;; Emits a inline stack probe loop.
(StackProbeLoop (tmp WritableReg)
(frame_size u32)
(guard_size u32))
;; =========================================
;; Floating-point operations.
;; Converts an unsigned int64 to a float32/float64.
(CvtUint64ToFloatSeq (dst_size OperandSize) ;; 4 or 8
(src Gpr)
(dst WritableXmm)
(tmp_gpr1 WritableGpr)
(tmp_gpr2 WritableGpr))
;; Converts a scalar xmm to a signed int32/int64.
(CvtFloatToSintSeq (dst_size OperandSize)
(src_size OperandSize)
(is_saturating bool)
(src Xmm)
(dst WritableGpr)
(tmp_gpr WritableGpr)
(tmp_xmm WritableXmm))
;; Converts a scalar xmm to an unsigned int32/int64.
(CvtFloatToUintSeq (dst_size OperandSize)
(src_size OperandSize)
(is_saturating bool)
(src Xmm)
(dst WritableGpr)
(tmp_gpr WritableGpr)
(tmp_xmm WritableXmm)
(tmp_xmm2 WritableXmm))
;; A sequence to compute min/max with the proper NaN semantics for xmm
;; registers.
(XmmMinMaxSeq (size OperandSize)
(is_min bool)
(lhs Xmm)
(rhs Xmm)
(dst WritableXmm))
;; =========================================
;; Control flow instructions.
;; Direct call: call simm32.
(CallKnown (info BoxCallInfo))
;; Indirect call: callq (reg mem)
(CallUnknown (info BoxCallIndInfo))
;; Tail call to a direct destination.
(ReturnCallKnown (info BoxReturnCallInfo))
;; Tail call to an indirect destination.
(ReturnCallUnknown (info BoxReturnCallIndInfo))
;; A pseudo-instruction that captures register arguments in vregs.
(Args
(args VecArgPair))
;; A pseudo-instruction that moves vregs to return registers.
(Rets
(rets VecRetPair))
;; Stack switching
(StackSwitchBasic (store_context_ptr Gpr)
(load_context_ptr Gpr)
(in_payload0 Gpr)
(out_payload0 WritableGpr))
;; Jump to a known target: jmp simm32.
(JmpKnown (dst MachLabel))
;; Low-level one-way conditional branch: jcond cond target.
;;
;; This instruction is useful only for lower-level code
;; generators that use the Cranelift instruction backend as an
;; assembler library. The instruction is thus named after its
;; primary user, Winch. This instruction *should not* be used
;; by Cranelift proper and placed into VCode: it does not
;; adhere to the basic-block invariant, namely that branches
;; always end a block (with no fallthrough).
(WinchJmpIf (cc CC)
(taken MachLabel))
;; Two-way conditional branch: jcond cond target target.
;;
;; Emitted as a compound sequence; the MachBuffer will shrink it as
;; appropriate.
(JmpCond (cc CC)
(taken MachLabel)
(not_taken MachLabel))
;; Two-way conditional branch with a combination of conditions:
;;
;; j(cc1 or cc2) target1 target2
;;
;; Emitted as a compound sequence of three branches -- `jcc1
;; target1`, `jcc2 target1`, `jmp target2`.
(JmpCondOr (cc1 CC)
(cc2 CC)
(taken MachLabel)
(not_taken MachLabel))
;; Jump-table sequence, as one compound instruction (see note in lower.rs
;; for rationale).
;;
;; The generated code sequence is described in the emit's function match
;; arm for this instruction.
;;
;; See comment on jmp_table_seq below about the temporaries signedness.
(JmpTableSeq (idx Reg)
(tmp1 WritableReg)
(tmp2 WritableReg)
(default_target MachLabel)
(targets BoxVecMachLabel))
;; Traps if the condition code is set.
(TrapIf (cc CC)
(trap_code TrapCode))
;; Traps if both of the condition codes are set.
(TrapIfAnd (cc1 CC)
(cc2 CC)
(trap_code TrapCode))
;; Traps if either of the condition codes are set.
(TrapIfOr (cc1 CC)
(cc2 CC)
(trap_code TrapCode))
;; Loads an external symbol in a register, with a relocation:
;;
;; movq $name@GOTPCREL(%rip), dst if PIC is enabled, or
;; lea $name($rip), dst if distance is near, or
;; movabsq $name, dst otherwise.
(LoadExtName (dst WritableGpr)
(name BoxExternalName)
(offset i64)
(distance RelocDistance))
;; =========================================
;; Instructions pertaining to atomic memory accesses.
;; A synthetic instruction, based on a loop around a native `lock
;; cmpxchg` instruction.
;;
;; This atomically modifies a value in memory and returns the old value.
;; The sequence consists of an initial "normal" load from `dst`, followed
;; by a loop which computes the new value and tries to compare-and-swap
;; ("CAS") it into `dst`, using the native instruction `lock
;; cmpxchg{b,w,l,q}`. The loop iterates until the CAS is successful. If
;; there is no contention, there will be only one pass through the loop
;; body. The sequence does *not* perform any explicit memory fence
;; instructions (`mfence`/`sfence`/`lfence`).
;;
;; Note that the transaction is atomic in the sense that, as observed by
;; some other thread, `dst` either has the initial or final value, but no
;; other. It isn't atomic in the sense of guaranteeing that no other
;; thread writes to `dst` in between the initial load and the CAS -- but
;; that would cause the CAS to fail unless the other thread's last write
;; before the CAS wrote the same value that was already there. In other
;; words, this implementation suffers (unavoidably) from the A-B-A
;; problem.
;;
;; This instruction sequence has fixed register uses as follows:
;; - %rax (written) the old value at `mem`
;; - %rflags is written. Do not assume anything about it after the
;; instruction.
(AtomicRmwSeq (ty Type) ;; I8, I16, I32, or I64
(op AtomicRmwSeqOp)
(mem SyntheticAmode)
(operand Gpr)
(temp WritableGpr)
(dst_old WritableGpr))
;; A synthetic instruction, based on a loop around a native `lock
;; cmpxchg16b` instruction.
;;
;; This is the same as `AtomicRmwSeq`, but for 128-bit integers.
;;
;; For `AtomicRmwOp::Xchg`, use `Atomic128XchgSeq` instead.
;;
;; This instruction sequence has fixed register uses as follows:
;; - %rax (low), %rdx (high) (written) the old value at `mem`
;; - %rbx (low), %rcx (high) (written) used as temp registers to hold
;; the replacement value
;; - %rflags is written. Do not assume anything about it after the
;; instruction.
(Atomic128RmwSeq (op Atomic128RmwSeqOp)
(mem BoxSyntheticAmode)
(operand_low Gpr)
(operand_high Gpr)
(temp_low WritableGpr)
(temp_high WritableGpr)
(dst_old_low WritableGpr)
(dst_old_high WritableGpr))
;; A synthetic instruction, based on a loop around a native `lock
;; cmpxchg16b` instruction.
;;
;; This is `Atomic128XchgSeq` but only for `AtomicRmwOp::Xchg`. As the
;; replacement value is the same every time, this instruction doesn't
;; require any temporary registers.
;;
;; This instruction sequence has fixed register uses as follows:
;; - %rax (low), %rdx (high) (written) the old value at `mem`
;; - %rbx (low), %rcx (high) (read) the replacement value
;; - %rflags is written. Do not assume anything about it after the
;; instruction.
(Atomic128XchgSeq (mem SyntheticAmode)
(operand_low Gpr)
(operand_high Gpr)
(dst_old_low WritableGpr)
(dst_old_high WritableGpr))
;; =========================================
;; Meta-instructions generating no code.
;; Provides a way to tell the register allocator that the upcoming
;; sequence of instructions will overwrite `dst` so it should be
;; considered as a `def`; use this with care.
;;
;; This is useful when we have a sequence of instructions whose register
;; usages are nominally `mod`s, but such that the combination of
;; operations creates a result that is independent of the initial
;; register value. It's thus semantically a `def`, not a `mod`, when all
;; the instructions are taken together, so we want to ensure the register
;; is defined (its live-range starts) prior to the sequence to keep
;; analyses happy.
;;
;; One alternative would be a compound instruction that somehow
;; encapsulates the others and reports its own `def`s/`use`s/`mod`s; this
;; adds complexity (the instruction list is no longer flat) and requires
;; knowledge about semantics and initial-value independence anyway.
(XmmUninitializedValue (dst WritableXmm))
;; See `XmmUninitializedValue` above.
(GprUninitializedValue (dst WritableGpr))
;; A call to the `ElfTlsGetAddr` libcall. Returns address of TLS symbol
;; `dst`, which is constrained to `rax`.
(ElfTlsGetAddr (symbol ExternalName)
(dst WritableGpr))
;; A Mach-O TLS symbol access. Returns address of the TLS symbol in
;; `dst`, which is constrained to `rax`.
(MachOTlsGetAddr (symbol ExternalName)
(dst WritableGpr))
;; A Coff TLS symbol access. Returns address of the TLS symbol in
;; `dst`, which is constrained to `rax`.
(CoffTlsGetAddr (symbol ExternalName)
(dst WritableGpr)
(tmp WritableGpr))
;; An unwind pseudoinstruction describing the state of the machine at
;; this program point.
(Unwind (inst UnwindInst))
;; A pseudoinstruction that just keeps a value alive.
(DummyUse (reg Reg))
;; A pseudoinstruction that loads the address of a label.
(LabelAddress (dst WritableGpr)
(label MachLabel))
;; A pseudoinstruction that serves as a sequence point.
(SequencePoint)
;; An instruction assembled outside of cranelift-codegen.
(External (inst AssemblerInst))))
(type AssemblerInst extern (enum))
(type OperandSize extern
(enum Size8
Size16
Size32
Size64))
(type BoxCallInfo extern (enum))
(type BoxCallIndInfo extern (enum))
(type BoxReturnCallInfo extern (enum))
(type BoxReturnCallIndInfo extern (enum))
(type BoxSyntheticAmode extern (enum))
(decl pure box_synthetic_amode (SyntheticAmode) BoxSyntheticAmode)
(extern constructor box_synthetic_amode box_synthetic_amode)
(convert SyntheticAmode BoxSyntheticAmode box_synthetic_amode)
;; Get the `OperandSize` for a given `Type`, rounding smaller types up to 32 bits.
(decl operand_size_of_type_32_64 (Type) OperandSize)
(extern constructor operand_size_of_type_32_64 operand_size_of_type_32_64)
;; Get the true `OperandSize` for a given `Type`, with no rounding.
(decl raw_operand_size_of_type (Type) OperandSize)
(extern constructor raw_operand_size_of_type raw_operand_size_of_type)
;; Get the bit width of an `OperandSize`.
(decl operand_size_bits (OperandSize) u16)
(rule (operand_size_bits (OperandSize.Size8)) 8)
(rule (operand_size_bits (OperandSize.Size16)) 16)
(rule (operand_size_bits (OperandSize.Size32)) 32)
(rule (operand_size_bits (OperandSize.Size64)) 64)
(type RegMemImm extern
(enum
(Reg (reg Reg))
(Mem (addr SyntheticAmode))
(Imm (simm32 u32))))
;; Put the given clif value into a `RegMemImm` operand.
;;
;; Asserts that the value fits into a single register, and doesn't require
;; multiple registers for its representation (like `i128` for example).
;;
;; As a side effect, this marks the value as used.
(decl put_in_reg_mem_imm (Value) RegMemImm)
(extern constructor put_in_reg_mem_imm put_in_reg_mem_imm)
(type RegMem extern
(enum
(Reg (reg Reg))
(Mem (addr SyntheticAmode))))
;; Convert a RegMem to a RegMemImm.
(decl reg_mem_to_reg_mem_imm (RegMem) RegMemImm)
(rule (reg_mem_to_reg_mem_imm (RegMem.Reg reg))
(RegMemImm.Reg reg))
(rule (reg_mem_to_reg_mem_imm (RegMem.Mem addr))
(RegMemImm.Mem addr))
;; Put the given clif value into a `RegMem` operand.
;;
;; Asserts that the value fits into a single register, and doesn't require
;; multiple registers for its representation (like `i128` for example).
;;
;; As a side effect, this marks the value as used.
(decl put_in_reg_mem (Value) RegMem)
(extern constructor put_in_reg_mem put_in_reg_mem)
;; Addressing modes.
(type SyntheticAmode extern (enum))
(decl synthetic_amode_to_reg_mem (SyntheticAmode) RegMem)
(extern constructor synthetic_amode_to_reg_mem synthetic_amode_to_reg_mem)
(spec (amode_to_synthetic_amode amode) (provide (= result amode)))
(decl amode_to_synthetic_amode (Amode) SyntheticAmode)
(extern constructor amode_to_synthetic_amode amode_to_synthetic_amode)
(decl synthetic_amode_slot (i32) SyntheticAmode)
(extern constructor synthetic_amode_slot synthetic_amode_slot)
;; Helper for loads/stores to/from stackslots.
(decl stackslot_amode (StackSlot Offset32 Offset32) SyntheticAmode)
(rule (stackslot_amode slot offset1 offset2)
(let ((slot_offset i32 (abi_stackslot_offset_into_slot_region slot offset1 offset2)))
(synthetic_amode_slot slot_offset)))
;; An `Amode` represents a possible addressing mode that can be used
;; in instructions. These denote a 64-bit value only.
(type Amode (enum
;; Immediate sign-extended and a register
(ImmReg (simm32 i32)
(base Reg)
(flags MemFlags))
;; Sign-extend-32-to-64(simm32) + base + (index << shift)
(ImmRegRegShift (simm32 i32)
(base Gpr)
(index Gpr)
(shift u8)
(flags MemFlags))
;; Sign-extend-32-to-64(immediate) + RIP (instruction
;; pointer). The appropriate relocation is emitted so
;; that the resulting immediate makes this Amode refer to
;; the given MachLabel.
(RipRelative (target MachLabel))))
;; Model an Amode as a combination of flags and the calculated 64-bit address.
;; 16 bits 64 bits
;; [ flags | address ]
(model Amode (type (bv 80)))
(spec (Amode.ImmReg simm base flags)
(provide (= result (concat flags (bvadd base (sign_ext 64 simm)))))
(require
(= (widthof simm) 32)
(= (widthof base) 64)
(= (widthof flags) 16)))
(spec (Amode.ImmRegRegShift simm base index shift flags)
(provide
(= result
(concat flags
(bvadd
(bvadd base (sign_ext 64 simm))
(bvshl index (zero_ext 64 shift))))))
(require
(= (widthof simm) 32)
(= (widthof base) 64)
(= (widthof index) 64)
(= (widthof shift) 8)
(= (widthof flags) 16)))
;; A helper to both check that the `Imm64` and `Offset32` values sum to less
;; than 32-bits AND return this summed `u32` value. Also, the `Imm64` will be
;; zero-extended from `Type` up to 64 bits. This is useful for `to_amode`.
(decl pure partial sum_extend_fits_in_32_bits (Type Imm64 Offset32) u32)
(extern constructor sum_extend_fits_in_32_bits sum_extend_fits_in_32_bits)
;;;; Amode lowering ;;;;
;; Converts a `Value` and a static offset into an `Amode` for x64, attempting
;; to be as fancy as possible with offsets/registers/shifts/etc to make maximal
;; use of the x64 addressing modes.
;;
;; This is a bit subtle unfortunately due to a few constraints. This function
;; was originally written recursively but that can lead to stack overflow
;; for certain inputs due to the recursion being defined by user-controlled
;; input. This means that nowadays this function is not recursive and has a
;; specific structure to handle that.
;;
;; Additionally currently in CLIF all loads/stores have an `Offset32` immediate
;; to go with them, but the wasm lowering to CLIF doesn't use this meaning that
;; it's frequently 0. Additionally mid-end optimizations do not fold `iconst`
;; values into this `Offset32`, meaning that it's left up to backends to hunt
;; for constants for good codegen. That means that one important aspect of this
;; function is that it searches for constants to fold into the `Offset32` to
;; avoid unnecessary instructions.
;;
;; Note, though, that the "optimal addressing modes" are only guaranteed to be
;; generated if egraph-based optimizations have run. For example this will only
;; attempt to find one constant as opposed to many, and that'll only happen
;; with constant folding from optimizations.
;;
;; Finally there's two primary entry points for this function. One is this
;; function here, `to_amode,` and another is `to_amode_add`. The latter is used
;; by the lowering of `iadd` in the x64 backend to use the `lea` instruction
;; where the input is two `Value` operands instead of just one. Most of the
;; logic here is then deferred through `to_amode_add`.
;;
;; In the future if mid-end optimizations fold constants into `Offset32` then
;; this in theory can "simply" delegate to the `amode_imm_reg` helper, and
;; below can delegate to `amode_imm_reg_reg_shift`, or something like that.
(spec (to_amode flags val offset)
(provide (= result (concat flags (bvadd val (sign_ext 64 offset)))))
(require
(= (widthof val) 64)))
(decl to_amode (MemFlags Value Offset32) SyntheticAmode)
(rule 0 (to_amode flags base offset)
(amode_imm_reg flags base offset))
(rule 1 (to_amode flags (iadd x y) offset)
(to_amode_add flags x y offset))
(rule 2
(to_amode flags (stack_addr slot offset1) offset2)
(stackslot_amode slot offset1 offset2))
;; Same as `to_amode`, except that the base address is computed via the addition
;; of the two `Value` arguments provided.
;;
;; The primary purpose of this is to hunt for constants within the two `Value`
;; operands provided. Failing that this will defer to `amode_imm_reg` or
;; `amode_imm_reg_reg_shift` which is the final step in amode lowering and
;; performs final pattern matches related to shifts to see if that can be
;; peeled out into the amode.
;;
;; In other words this function's job is to find constants and then defer to
;; `amode_imm_reg*`.
;;
(spec (to_amode_add flags x y offset)
(provide (= result (concat flags (bvadd (bvadd (sign_ext 64 x) (sign_ext 64 y)) (sign_ext 64 offset))))))
(instantiate to_amode_add
((args (bv 16) (bv 64) (bv 64) (bv 32)) (ret (bv 80)) (canon (bv 64))))
(decl to_amode_add (MemFlags Value Value Offset32) Amode)
(rule to_amode_add_base_case 0 (to_amode_add flags x y offset)
(amode_imm_reg_reg_shift flags x y offset))
(rule to_amode_add_const_rhs 1 (to_amode_add flags x (i32_from_iconst c) offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg flags x sum))
(rule to_amode_add_const_lhs 2 (to_amode_add flags (i32_from_iconst c) x offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg flags x sum))
(rule to_amode_add_const_fold_iadd_lhs_rhs 3 (to_amode_add flags (iadd x (i32_from_iconst c)) y offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg_reg_shift flags x y sum))
(rule to_amode_add_const_fold_iadd_lhs_lhs 4 (to_amode_add flags (iadd (i32_from_iconst c) x) y offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg_reg_shift flags x y sum))
(rule to_amode_add_const_fold_iadd_rhs_rhs 5 (to_amode_add flags x (iadd y (i32_from_iconst c)) offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg_reg_shift flags x y sum))
(rule to_amode_add_const_fold_iadd_rhs_lhs 6 (to_amode_add flags x (iadd (i32_from_iconst c) y) offset)
(if-let sum (i32_checked_add offset c))
(amode_imm_reg_reg_shift flags x y sum))
;; Final cases of amode lowering. Does not hunt for constants and only attempts
;; to pattern match add-of-shifts to generate fancier `ImmRegRegShift` modes,
;; otherwise falls back on `ImmReg`.
(spec (amode_imm_reg flags x offset)
(provide (= result (concat flags (bvadd (sign_ext 64 x) (sign_ext 64 offset))))))
(instantiate amode_imm_reg
((args (bv 16) (bv 64) (bv 32)) (ret (bv 80)) (canon (bv 64))))
(decl amode_imm_reg (MemFlags Value Offset32) Amode)
(rule amode_imm_reg_base 0 (amode_imm_reg flags base offset)
(Amode.ImmReg offset base flags))
(rule amode_imm_reg_iadd 1 (amode_imm_reg flags (iadd x y) offset)
(amode_imm_reg_reg_shift flags x y offset))
(spec (amode_imm_reg_reg_shift flags x y offset)
(provide (= result (concat flags (bvadd (sign_ext 64 (bvadd x y)) (sign_ext 64 offset)))))
(require
(= (widthof flags) 16)
(= (widthof x) (widthof y))
(= (widthof offset) 32)))
(instantiate amode_imm_reg_reg_shift
((args (bv 16) (bv 64) (bv 64) (bv 32)) (ret (bv 80)) (canon (bv 64))))
(decl amode_imm_reg_reg_shift (MemFlags Value Value Offset32) Amode)
(rule amode_imm_reg_reg_shift_no_shift 0 (amode_imm_reg_reg_shift flags x y offset)
(Amode.ImmRegRegShift offset x y 0 flags)) ;; 0 == y<<0 == "no shift"
(rule amode_imm_reg_reg_shift_shl_rhs 1 (amode_imm_reg_reg_shift flags x (ishl y (iconst (uimm8 shift))) offset)
(if-let true (u32_lt_eq shift 3))
(Amode.ImmRegRegShift offset x y shift flags))
(rule amode_imm_reg_reg_shift_shl_lhs 2 (amode_imm_reg_reg_shift flags (ishl y (iconst (uimm8 shift))) x offset)
(if-let true (u32_lt_eq shift 3))
(Amode.ImmRegRegShift offset x y shift flags))
;; Offsetting an Amode. Used when we need to do consecutive
;; loads/stores to adjacent addresses.
(decl amode_offset (SyntheticAmode i32) SyntheticAmode)
(extern constructor amode_offset amode_offset)
;; Return a zero offset as an `Offset32`.
(spec (zero_offset) (provide (= result #x00000000)))
(decl zero_offset () Offset32)
(extern constructor zero_offset zero_offset)
;; Shift kinds.
(type ShiftKind extern
(enum ShiftLeft
ShiftRightLogical
ShiftRightArithmetic
RotateLeft
RotateRight))
(type Imm8Gpr
(enum (Imm8 (imm u8))
(Gpr (reg Gpr))))
;; Put the given clif value into a `Imm8Reg` operand, masked to the bit width of
;; the given type.
;;
;; Asserts that the value fits into a single register, and doesn't require
;; multiple registers for its representation (like `i128` for example).
;;
;; As a side effect, this marks the value as used.
;;
;; This is used when lowering various shifts and rotates.
(decl put_masked_in_imm8_gpr (Value Type) Imm8Gpr)
(rule 2 (put_masked_in_imm8_gpr (u64_from_iconst amt) ty)
(Imm8Gpr.Imm8 (u64_truncate_into_u8 (u64_and amt (shift_mask ty)))))
(rule 1 (put_masked_in_imm8_gpr amt (fits_in_16 ty))
(x64_and $I64 (value_regs_get_gpr amt 0) (RegMemImm.Imm (shift_mask ty))))
(rule (put_masked_in_imm8_gpr amt ty)
(value_regs_get_gpr amt 0))
;; Condition codes
(type CC extern
(enum O
NO
B
NB
Z
NZ
BE
NBE
S
NS
L
NL
LE
NLE
P
NP))
(decl intcc_to_cc (IntCC) CC)
(extern constructor intcc_to_cc intcc_to_cc)
(decl cc_invert (CC) CC)
(extern constructor cc_invert cc_invert)
;; Fails if the argument is not either CC.NZ or CC.Z.
(decl cc_nz_or_z (CC) CC)
(extern extractor cc_nz_or_z cc_nz_or_z)
(type FcmpImm extern
(enum Equal
LessThan
LessThanOrEqual
Unordered
NotEqual
UnorderedOrGreaterThanOrEqual
UnorderedOrGreaterThan
Ordered))
(decl encode_fcmp_imm (FcmpImm) u8)
(extern constructor encode_fcmp_imm encode_fcmp_imm)
(type RoundImm extern
(enum RoundNearest
RoundDown
RoundUp
RoundZero))
(decl encode_round_imm (RoundImm) u8)
(extern constructor encode_round_imm encode_round_imm)
;;;; Newtypes for Different Register Classes ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(type Gpr (primitive Gpr))
(type WritableGpr (primitive WritableGpr))
(type OptionWritableGpr (primitive OptionWritableGpr))
(type GprMem extern (enum))
(type GprMemImm extern (enum))
(type Xmm (primitive Xmm))
(type WritableXmm (primitive WritableXmm))
(type OptionWritableXmm (primitive OptionWritableXmm))
(type XmmMem extern (enum))
(type XmmMemAligned extern (enum))
(type XmmMemImm extern (enum))
(type XmmMemAlignedImm extern (enum))
;; Convert a `WritableGpr` to a `WritableReg`.
(decl writable_gpr_to_reg (WritableGpr) WritableReg)
(extern constructor writable_gpr_to_reg writable_gpr_to_reg)
;; Convert a `WritableXmm` to a `WritableReg`.
(decl writable_xmm_to_reg (WritableXmm) WritableReg)
(extern constructor writable_xmm_to_reg writable_xmm_to_reg)
;; Convert a `WritableReg` to a `WritableXmm`.
(decl writable_reg_to_xmm (WritableReg) WritableXmm)
(extern constructor writable_reg_to_xmm writable_reg_to_xmm)
;; Convert a `WritableXmm` to an `Xmm`.
(decl writable_xmm_to_xmm (WritableXmm) Xmm)
(extern constructor writable_xmm_to_xmm writable_xmm_to_xmm)
;; Convert a `WritableGpr` to an `Gpr`.
(decl writable_gpr_to_gpr (WritableGpr) Gpr)
(extern constructor writable_gpr_to_gpr writable_gpr_to_gpr)
;; Convert an `Gpr` to a `Reg`.
(decl gpr_to_reg (Gpr) Reg)
(extern constructor gpr_to_reg gpr_to_reg)
;; Convert an `Gpr` to a `GprMem`.
(decl gpr_to_gpr_mem (Gpr) GprMem)
(extern constructor gpr_to_gpr_mem gpr_to_gpr_mem)
;; Convert an `Gpr` to a `GprMemImm`.
(decl gpr_to_gpr_mem_imm (Gpr) GprMemImm)
(extern constructor gpr_to_gpr_mem_imm gpr_to_gpr_mem_imm)
;; Convert an `Xmm` to a `Reg`.
(decl xmm_to_reg (Xmm) Reg)
(extern constructor xmm_to_reg xmm_to_reg)
;; Convert an `Xmm` into an `XmmMemImm`.
(decl xmm_to_xmm_mem_imm (Xmm) XmmMemImm)
(extern constructor xmm_to_xmm_mem_imm xmm_to_xmm_mem_imm)
;; Convert an `XmmMem` into an `XmmMemImm`.
(decl xmm_mem_to_xmm_mem_imm (XmmMem) XmmMemImm)
(extern constructor xmm_mem_to_xmm_mem_imm xmm_mem_to_xmm_mem_imm)
;; Convert an `XmmMem` into an `XmmMemAligned`.
;;
;; Note that this is an infallible conversion, not a fallible one. If the
;; original `XmmMem` source is a register, then it's passed through directly.
;; If it's `Mem` and refers to aligned memory, it's also passed through
;; directly. Otherwise, though, it's a memory source which is not aligned to
;; 16 bytes so a load is performed and the temporary register which is the
;; result of the load is passed through. The end-result is that the return value
;; here is guaranteed to be a register or an aligned memory location.
(decl xmm_mem_to_xmm_mem_aligned (XmmMem) XmmMemAligned)
(extern constructor xmm_mem_to_xmm_mem_aligned xmm_mem_to_xmm_mem_aligned)
;; Convert an `XmmMemImm` into an `XmmMemImmAligned`.
;;
;; Note that this is the same as `xmm_mem_to_xmm_mem_aligned` except it handles
;; an immediate case as well.
(decl xmm_mem_imm_to_xmm_mem_aligned_imm (XmmMemImm) XmmMemAlignedImm)
(extern constructor xmm_mem_imm_to_xmm_mem_aligned_imm xmm_mem_imm_to_xmm_mem_aligned_imm)
;; Allocate a new temporary GPR register.
(decl temp_writable_gpr () WritableGpr)
(extern constructor temp_writable_gpr temp_writable_gpr)
;; Allocate a new temporary XMM register.
(decl temp_writable_xmm () WritableXmm)
(extern constructor temp_writable_xmm temp_writable_xmm)
;; Construct a new `XmmMem` from the given `RegMem`.
;;
;; Asserts that the `RegMem`'s register, if any, is an XMM register.
(decl reg_mem_to_xmm_mem (RegMem) XmmMem)
(extern constructor reg_mem_to_xmm_mem reg_mem_to_xmm_mem)
;; Construct a new `RegMemImm` from the given `Reg`.
(decl reg_to_reg_mem_imm (Reg) RegMemImm)
(extern constructor reg_to_reg_mem_imm reg_to_reg_mem_imm)
;; Construct a new `GprMemImm` from the given `RegMemImm`.
;;
;; Asserts that the `RegMemImm`'s register, if any, is an GPR register.
(decl gpr_mem_imm_new (RegMemImm) GprMemImm)
(extern constructor gpr_mem_imm_new gpr_mem_imm_new)
;; Construct a new `XmmMemImm` from the given `RegMemImm`.
;;
;; Asserts that the `RegMemImm`'s register, if any, is an XMM register.
(decl xmm_mem_imm_new (RegMemImm) XmmMemImm)
(extern constructor xmm_mem_imm_new xmm_mem_imm_new)
;; Construct a new `XmmMem` from an `Xmm`.
(decl xmm_to_xmm_mem (Xmm) XmmMem)
(extern constructor xmm_to_xmm_mem xmm_to_xmm_mem)
;; Construct a new `XmmMem` from an `RegMem`.
(decl pure xmm_mem_to_reg_mem (XmmMem) RegMem)
(extern constructor xmm_mem_to_reg_mem xmm_mem_to_reg_mem)
;; Convert a `GprMem` to a `RegMem`.
(decl gpr_mem_to_reg_mem (GprMem) RegMem)
(extern constructor gpr_mem_to_reg_mem gpr_mem_to_reg_mem)
;; Construct a new `Xmm` from a `Reg`.
;;
;; Asserts that the register is a XMM.
(decl xmm_new (Reg) Xmm)
(extern constructor xmm_new xmm_new)
;; Construct a new `Gpr` from a `Reg`.
;;
;; Asserts that the register is a GPR.
(decl gpr_new (Reg) Gpr)
(extern constructor gpr_new gpr_new)
;; Construct a new `GprMem` from a `RegMem`.
;;
;; Asserts that the `RegMem`'s register, if any, is a GPR.
(decl reg_mem_to_gpr_mem (RegMem) GprMem)
(extern constructor reg_mem_to_gpr_mem reg_mem_to_gpr_mem)
;; Construct a `GprMem` from a `Reg`.
;;
;; Asserts that the `Reg` is a GPR.
(decl reg_to_gpr_mem (Reg) GprMem)
(extern constructor reg_to_gpr_mem reg_to_gpr_mem)
;; Construct a `GprMemImm` from a `Reg`.
;;
;; Asserts that the `Reg` is a GPR.
(decl reg_to_gpr_mem_imm (Reg) GprMemImm)
(rule (reg_to_gpr_mem_imm r)
(gpr_to_gpr_mem_imm (gpr_new r)))
;; Put a value into a GPR.
;;
;; Moves the value into a GPR if it is a type that would naturally go into an
;; XMM register.
(spec (put_in_gpr arg) (provide (= result (conv_to 64 arg))))
(decl put_in_gpr (Value) Gpr)
;; Case for when the value naturally lives in a GPR.
(rule (put_in_gpr val)
(if-let (value_type ty) val)
(if-let (type_register_class (RegisterClass.Gpr _)) ty)
(gpr_new (put_in_reg val)))
;; Case for when the value naturally lives in an XMM register and we must
;; bitcast it from an XMM into a GPR.
(rule (put_in_gpr val)
(if-let (value_type ty) val)
(if-let (type_register_class (RegisterClass.Xmm)) ty)
(bitcast_xmm_to_gpr (ty_bits ty) (xmm_new (put_in_reg val))))
;; Put a value into a `GprMem`.
;;
;; Asserts that the value goes into a GPR.
(decl put_in_gpr_mem (Value) GprMem)
(rule (put_in_gpr_mem val)
(reg_mem_to_gpr_mem (put_in_reg_mem val)))
;; Put a value into a `GprMemImm`.
;;
;; Asserts that the value goes into a GPR.
(decl put_in_gpr_mem_imm (Value) GprMemImm)
(rule (put_in_gpr_mem_imm val)
(gpr_mem_imm_new (put_in_reg_mem_imm val)))
;; Put a value into a XMM.
;;
;; Asserts that the value goes into a XMM.
(decl put_in_xmm (Value) Xmm)
(rule (put_in_xmm val)
(xmm_new (put_in_reg val)))
;; Put a value into a `XmmMem`.
;;
;; Asserts that the value goes into a XMM.
(decl put_in_xmm_mem (Value) XmmMem)
(extern constructor put_in_xmm_mem put_in_xmm_mem)
;; Put a value into a `XmmMemImm`.
;;
;; Asserts that the value goes into a XMM.
(decl put_in_xmm_mem_imm (Value) XmmMemImm)
(extern constructor put_in_xmm_mem_imm put_in_xmm_mem_imm)
;; Construct an `InstOutput` out of a single GPR register.
(spec (output_gpr x)
(provide (= result (conv_to (widthof result) x))))
(decl output_gpr (Gpr) InstOutput)
(rule (output_gpr x)
(output_reg (gpr_to_reg x)))
;; Construct a `ValueRegs` out of two GPR registers.
(decl value_gprs (Gpr Gpr) ValueRegs)
(rule (value_gprs x y)
(value_regs (gpr_to_reg x) (gpr_to_reg y)))
;; Construct an `InstOutput` out of a single XMM register.
(decl output_xmm (Xmm) InstOutput)
(rule (output_xmm x)
(output_reg (xmm_to_reg x)))
;; Get the `n`th reg in a `ValueRegs` and construct a GPR from it.
;;
;; Asserts that the register is a GPR.
(decl value_regs_get_gpr (ValueRegs usize) Gpr)
(rule (value_regs_get_gpr regs n)
(gpr_new (value_regs_get regs n)))
;; Convert a `Gpr` to an `Imm8Gpr`.
(decl gpr_to_imm8_gpr (Gpr) Imm8Gpr)
(rule (gpr_to_imm8_gpr gpr) (Imm8Gpr.Gpr gpr))
;; Get the low half of the given `Value` as a GPR.
(decl lo_gpr (Value) Gpr)
(rule (lo_gpr regs) (gpr_new (lo_reg regs)))
;; Construct a new `XmmMemImm` from a 32-bit immediate.
(decl xmi_imm (u32) XmmMemImm)
(extern constructor xmi_imm xmi_imm)
;;;; Helpers for determining the register class of a value type ;;;;;;;;;;;;;;;;
(type RegisterClass
(enum
(Gpr (single_register bool))
(Xmm)))
(decl type_register_class (RegisterClass) Type)
(extern extractor type_register_class type_register_class)
(decl is_xmm_type (Type) Type)
(extractor (is_xmm_type ty) (and (type_register_class (RegisterClass.Xmm)) ty))
(spec (is_gpr_type arg)
(provide (= result arg))
(require (<= arg 64)))
(decl is_gpr_type (Type) Type)
(extractor (is_gpr_type ty) (and (type_register_class (RegisterClass.Gpr _)) ty))
(decl is_single_register_gpr_type (Type) Type)
(extractor (is_single_register_gpr_type ty)
(and (type_register_class (RegisterClass.Gpr true)) ty))
(decl is_multi_register_gpr_type (Type) Type)
(extractor (is_multi_register_gpr_type ty)
(and (type_register_class (RegisterClass.Gpr false)) ty))
;;;; Helpers for matching operands ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;
;; These are mainly used for matching operands for the external assembler.
(decl is_imm8 (u8) GprMemImm)
(extern extractor is_imm8 is_imm8)
(decl is_imm8_xmm (u8) XmmMemImm)
(extern extractor is_imm8_xmm is_imm8_xmm)
(decl is_simm8 (i8) GprMemImm)
(extern extractor is_simm8 is_simm8)
(decl is_imm16 (u16) GprMemImm)
(extern extractor is_imm16 is_imm16)
(decl is_simm16 (i16) GprMemImm)
(extern extractor is_simm16 is_simm16)
(decl is_imm32 (u32) GprMemImm)
(extern extractor is_imm32 is_imm32)
(decl is_simm32 (i32) GprMemImm)
(extern extractor is_simm32 is_simm32)
(decl is_gpr (Gpr) GprMemImm)
(extern extractor is_gpr is_gpr)
(decl is_gpr_mem (GprMem) GprMemImm)
(extern extractor is_gpr_mem is_gpr_mem)
(decl is_xmm_mem (XmmMem) XmmMemImm)
(extern extractor is_xmm_mem is_xmm_mem)
(decl is_xmm (Xmm) XmmMem)
(extern extractor is_xmm is_xmm)
(decl is_mem (SyntheticAmode) XmmMem)
(extern extractor is_mem is_mem)
;;;; Helpers for Querying Enabled ISA Extensions ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl pure has_avx512vl () bool)
(extern constructor has_avx512vl has_avx512vl)
(decl pure has_avx512dq () bool)
(extern constructor has_avx512dq has_avx512dq)
(decl pure has_avx512f () bool)
(extern constructor has_avx512f has_avx512f)
(decl pure has_avx512bitalg () bool)
(extern constructor has_avx512bitalg has_avx512bitalg)
(decl pure has_avx512vbmi () bool)
(extern constructor has_avx512vbmi has_avx512vbmi)
(decl pure has_lzcnt () bool)
(extern constructor has_lzcnt has_lzcnt)
(decl pure has_bmi1 () bool)
(extern constructor has_bmi1 has_bmi1)
(decl pure has_bmi2 () bool)
(extern constructor has_bmi2 has_bmi2)
(decl pure use_popcnt () bool)
(extern constructor use_popcnt use_popcnt)
(decl pure use_fma () bool)
(extern constructor use_fma use_fma)
(decl pure has_sse3 () bool)
(extern constructor has_sse3 has_sse3)
(decl pure has_ssse3 () bool)
(extern constructor has_ssse3 has_ssse3)
(decl pure has_sse41 () bool)
(extern constructor has_sse41 has_sse41)
(decl pure use_sse42 () bool)
(extern constructor use_sse42 use_sse42)
(decl pure has_avx () bool)
(extern constructor has_avx has_avx)
(decl pure use_avx2 () bool)
(extern constructor use_avx2 use_avx2)
(decl pure has_cmpxchg16b () bool)
(extern constructor has_cmpxchg16b has_cmpxchg16b)
;;;; Helpers for Merging and Sinking Immediates/Loads ;;;;;;;;;;;;;;;;;;;;;;;;;
;; Generate a mask for the bit-width of the given type
(decl shift_mask (Type) u8)
(extern constructor shift_mask shift_mask)
;; Mask a constant with the type's shift mask
(decl shift_amount_masked (Type Imm64) u8)
(extern constructor shift_amount_masked shift_amount_masked)
;; Extract a constant `GprMemImm.Imm` from a value operand.
(decl simm32_from_value (GprMemImm) Value)
(extern extractor simm32_from_value simm32_from_value)
;; A load that can be sunk into another operation.
(type SinkableLoad extern (enum))
;; Extract a `SinkableLoad` that works with `RegMemImm.Mem` from a value
;; operand.
;;
;; Note that this will only work for 32-bit-types-or-larger since this is
;; pervasively used with operations that load a minimum of 32-bits. For
;; instructions which load exactly the type width necessary use
;; `sinkable_load_exact`.
(decl sinkable_load (SinkableLoad) Value)
(spec (sinkable_load inst)
(provide (= result inst)))
(extern extractor sinkable_load sinkable_load)
;; Same as `sinkable_load` except that all type widths of loads are supported.
;;
;; Only use this when the instruction which performs the load is guaranteed to
;; load the precisely correct size.
(decl sinkable_load_exact (SinkableLoad) Value)
(extern extractor sinkable_load_exact sinkable_load_exact)
;; Sink a `SinkableLoad` into a `SyntheticAmode`.
;;
;; This is a side-effectful operation that notifies the context that the
;; instruction that produced the `SinkableImm` has been sunk into another
;; instruction, and no longer needs to be lowered.
(decl sink_load (SinkableLoad) SyntheticAmode)
(extern constructor sink_load sink_load)
(decl sink_load_to_gpr_mem_imm (SinkableLoad) GprMemImm)
(rule (sink_load_to_gpr_mem_imm load)
(gpr_mem_imm_new load))
(decl sink_load_to_xmm_mem (SinkableLoad) XmmMem)
(rule (sink_load_to_xmm_mem load)
(reg_mem_to_xmm_mem load))
(decl sink_load_to_reg_mem (SinkableLoad) RegMem)
(rule (sink_load_to_reg_mem load) (RegMem.Mem load))
(decl sink_load_to_gpr_mem (SinkableLoad) GprMem)
(rule (sink_load_to_gpr_mem load) (RegMem.Mem load))
(decl sink_load_to_reg_mem_imm (SinkableLoad) RegMemImm)
(spec (sink_load_to_reg_mem_imm load)
(provide (= result load)))
(rule (sink_load_to_reg_mem_imm load) (RegMemImm.Mem load))
;;;; Helpers for constructing and emitting an `MInst` ;;;;;;;;;;;;;;;;;;;;;;;;;;
;;
;; These helpers are intended to assist in emitting instructions by taking
;; source operands and automatically creating output operands which are then
;; returned. These are additionally designed to assist with SSA-like
;; construction where the writable version of a register is only present in
;; an `MInst` and every other reference to it is a readonly version.
;; Helper for creating XmmUninitializedValue instructions.
(decl xmm_uninit_value () Xmm)
(rule (xmm_uninit_value)
(let ((dst WritableXmm (temp_writable_xmm))
(_ Unit (emit (MInst.XmmUninitializedValue dst))))
dst))
;; Helper for creating GprUninitializedValue instructions.
(decl gpr_uninit_value () Gpr)
(rule (gpr_uninit_value)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.GprUninitializedValue dst))))
dst))
;; Helper for constructing a LoadExtName instruction.
(decl load_ext_name (ExternalName i64 RelocDistance) Gpr)
(rule (load_ext_name extname offset distance)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.LoadExtName dst extname offset distance))))
dst))
;; Helper for creating `xmm_min_max_seq` pseudo-instructions.
(decl xmm_min_max_seq (Type bool Xmm Xmm) Xmm)
(rule (xmm_min_max_seq ty is_min lhs rhs)
(let ((dst WritableXmm (temp_writable_xmm))
(size OperandSize (operand_size_of_type_32_64 ty))
(_ Unit (emit (MInst.XmmMinMaxSeq size is_min lhs rhs dst))))
dst))
(decl cvt_u64_to_float_seq (Type Gpr) Xmm)
(rule (cvt_u64_to_float_seq ty src)
(let ((size OperandSize (raw_operand_size_of_type ty))
(dst WritableXmm (temp_writable_xmm))
(tmp_gpr1 WritableGpr (temp_writable_gpr))
(tmp_gpr2 WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CvtUint64ToFloatSeq size src dst tmp_gpr1 tmp_gpr2))))
dst))
(decl cvt_float_to_uint_seq (Type Value bool) Gpr)
(rule (cvt_float_to_uint_seq out_ty src @ (value_type src_ty) is_saturating)
(let ((out_size OperandSize (raw_operand_size_of_type out_ty))
(src_size OperandSize (raw_operand_size_of_type src_ty))
(dst WritableGpr (temp_writable_gpr))
(tmp_xmm WritableXmm (temp_writable_xmm))
(tmp_xmm2 WritableXmm (temp_writable_xmm))
(tmp_gpr WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CvtFloatToUintSeq out_size src_size is_saturating src dst tmp_gpr tmp_xmm tmp_xmm2))))
dst))
(decl cvt_float_to_sint_seq (Type Value bool) Gpr)
(rule (cvt_float_to_sint_seq out_ty src @ (value_type src_ty) is_saturating)
(let ((out_size OperandSize (raw_operand_size_of_type out_ty))
(src_size OperandSize (raw_operand_size_of_type src_ty))
(dst WritableGpr (temp_writable_gpr))
(tmp_xmm WritableXmm (temp_writable_xmm))
(tmp_gpr WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CvtFloatToSintSeq out_size src_size is_saturating src dst tmp_gpr tmp_xmm))))
dst))
;; Helper for creating `MovFromPReg` instructions.
(decl mov_from_preg (PReg) Reg)
(rule (mov_from_preg preg)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.MovFromPReg preg dst))))
dst))
;;;; Helpers for Sign/Zero Extending ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(type ExtKind extern
(enum None
SignExtend
ZeroExtend))
(type ExtendKind (enum Sign Zero))
(model ExtMode (enum
(BL #b000)
(BQ #b001)
(WL #b010)
(WQ #b011)
(LQ #b100)
))
(type ExtMode extern (enum BL BQ WL WQ LQ))
;; `ExtMode::new`
(spec (ext_mode x y)
(provide (= result (switch x
(#x0008 (switch y
(#x0020 (ExtMode.BL))
(#x0040 (ExtMode.BQ))
))
(#x0010 (switch y
(#x0020 (ExtMode.WL))
(#x0040 (ExtMode.WQ))
))
(#x0020 (switch y
(#x0040 (ExtMode.LQ))
))
))
)
)
(decl ext_mode (u16 u16) ExtMode)
(extern constructor ext_mode ext_mode)
;; Put the given value into a register, but extended as the given type.
(decl extend_to_gpr (Value Type ExtendKind) Gpr)
;; If the value is already of the requested type, no extending is necessary.
(rule 3 (extend_to_gpr val @ (value_type ty) ty _kind)
val)
;; I32 -> I64 with op that produces a zero-extended value in a register.
;;
;; As a particular x64 extra-pattern matching opportunity, all the ALU
;; opcodes on 32-bits will zero-extend the upper 32-bits, so we can
;; even not generate a zero-extended move in this case.
(rule 2 (extend_to_gpr src @ (value_type $I32) $I64 (ExtendKind.Zero))
(if-let true (value32_zeros_upper32 src))
(add_range_fact src 64 0 0xffff_ffff))
;; Both extend instructions are guaranteed to load exactly the source type's size.
;; So we can use `sinkable_load_exact` here to sink loads for small types (<= 16 bits).
(rule 1 (extend_to_gpr (and (sinkable_load_exact val) (value_type from_ty)) to_ty kind)
(extend_to_gpr_types val from_ty to_ty kind))
;; Otherwise emit the extend from a Gpr to a Gpr.
(rule (extend_to_gpr (and val (value_type from_ty)) to_ty kind)
(extend_to_gpr_types val from_ty to_ty kind))
;; Calculates the correct extension mode for an extend between `from_ty` and `to_ty`.
(decl extend_to_gpr_types (GprMem Type Type ExtendKind) Gpr)
(rule (extend_to_gpr_types val from_ty to_ty kind)
(let ((from_bits u16 (ty_bits_u16 from_ty))
;; Use `operand_size_of_type` so that the we clamp the output to 32-
;; or 64-bit width types.
(to_bits u16 (operand_size_bits (operand_size_of_type_32_64 to_ty))))
(extend kind
to_ty
(ext_mode from_bits to_bits)
val)))
;; Do a sign or zero extension of the given `GprMem`.
(decl extend (ExtendKind Type ExtMode GprMem) Gpr)
;; Zero extending uses `movzx`.
(rule (extend (ExtendKind.Zero) ty mode src)
(x64_movzx mode src))
;; Sign extending uses `movsx`.
(rule (extend (ExtendKind.Sign) ty mode src)
(x64_movsx mode src))
;; Tests whether the operation used to produce the input `Value`, which must
;; be a 32-bit operation, will automatically zero the upper 32-bits of the
;; destination register that `Value` is placed in.
(decl pure value32_zeros_upper32 (Value) bool)
(rule (value32_zeros_upper32 (iadd _ _)) true)
(rule (value32_zeros_upper32 (isub _ _)) true)
(rule (value32_zeros_upper32 (imul _ _)) true)
(rule (value32_zeros_upper32 (band _ _)) true)
(rule (value32_zeros_upper32 (bor _ _)) true)
(rule (value32_zeros_upper32 (bxor _ _)) true)
(rule (value32_zeros_upper32 (ishl _ _)) true)
(rule (value32_zeros_upper32 (ushr _ _)) true)
(rule (value32_zeros_upper32 (uload32 _ _ _)) true)
(rule -1 (value32_zeros_upper32 _) false)
;;;; Helpers for Working SSE tidbits ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Turn a vector type into its integer-typed vector equivalent.
(decl vec_int_type (Type) Type)
(rule (vec_int_type (multi_lane 8 16)) $I8X16)
(rule (vec_int_type (multi_lane 16 8)) $I16X8)
(rule (vec_int_type (multi_lane 32 4)) $I32X4)
(rule (vec_int_type (multi_lane 64 2)) $I64X2)
;; Performs an xor operation of the two operands specified.
(decl x64_xor_vector (Type Xmm XmmMem) Xmm)
(rule 1 (x64_xor_vector $F16 x y) (x64_xorps x y))
(rule 1 (x64_xor_vector $F32 x y) (x64_xorps x y))
(rule 1 (x64_xor_vector $F64 x y) (x64_xorpd x y))
(rule 1 (x64_xor_vector $F128 x y) (x64_xorps x y))
(rule 1 (x64_xor_vector $F32X4 x y) (x64_xorps x y))
(rule 1 (x64_xor_vector $F64X2 x y) (x64_xorpd x y))
(rule 0 (x64_xor_vector (multi_lane _ _) x y) (x64_pxor x y))
;; Generates a register value which has an all-ones pattern.
;;
;; Note that this is accomplished by comparing a fresh register with itself,
;; which for integers is always true. Also note that the comparison is always
;; done for integers. This is because we're comparing a fresh register to itself
;; and we don't know the previous contents of the register. If a floating-point
;; comparison is used then it runs the risk of comparing NaN against NaN and not
;; actually producing an all-ones mask. By using integer comparison operations
;; we're guaranteeed that everything is equal to itself.
(decl vector_all_ones () Xmm)
(rule (vector_all_ones)
(let ((tmp Xmm (xmm_uninit_value)))
(x64_pcmpeqd tmp tmp)))
;; Move a `RegMemImm.Reg` operand to an XMM register, if necessary.
(decl mov_rmi_to_xmm (RegMemImm) XmmMemImm)
(rule (mov_rmi_to_xmm rmi @ (RegMemImm.Mem _)) (xmm_mem_imm_new rmi))
(rule (mov_rmi_to_xmm rmi @ (RegMemImm.Imm _)) (xmm_mem_imm_new rmi))
(rule (mov_rmi_to_xmm (RegMemImm.Reg r)) (x64_movd_to_xmm r))
;;;; Helpers for Emitting Calls ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl gen_call_info (Sig ExternalName CallArgList CallRetList OptionTryCallInfo bool) BoxCallInfo)
(extern constructor gen_call_info gen_call_info)
(decl gen_call_ind_info (Sig RegMem CallArgList CallRetList OptionTryCallInfo) BoxCallIndInfo)
(extern constructor gen_call_ind_info gen_call_ind_info)
(decl gen_return_call_info (Sig ExternalName CallArgList) BoxReturnCallInfo)
(extern constructor gen_return_call_info gen_return_call_info)
(decl gen_return_call_ind_info (Sig Reg CallArgList) BoxReturnCallIndInfo)
(extern constructor gen_return_call_ind_info gen_return_call_ind_info)
;; Helper for creating `CallKnown` instructions.
(decl call_known (BoxCallInfo) SideEffectNoResult)
(rule (call_known info)
(SideEffectNoResult.Inst (MInst.CallKnown info)))
;; Helper for creating `CallUnknown` instructions.
(decl call_unknown (BoxCallIndInfo) SideEffectNoResult)
(rule (call_unknown info)
(SideEffectNoResult.Inst (MInst.CallUnknown info)))
;; Helper for creating `ReturnCallKnown` instructions.
(decl return_call_known (BoxReturnCallInfo) SideEffectNoResult)
(rule (return_call_known info)
(SideEffectNoResult.Inst (MInst.ReturnCallKnown info)))
;; Helper for creating `ReturnCallUnknown` instructions.
(decl return_call_unknown (BoxReturnCallIndInfo) SideEffectNoResult)
(rule (return_call_unknown info)
(SideEffectNoResult.Inst (MInst.ReturnCallUnknown info)))
;;;; Helpers for emitting stack switches ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl x64_stack_switch_basic (Gpr Gpr Gpr) Gpr)
(rule (x64_stack_switch_basic store_context_ptr load_context_ptr in_payload0)
(let ((out_payload0 WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.StackSwitchBasic store_context_ptr
load_context_ptr
in_payload0
out_payload0))))
out_payload0))
;;;; Helpers for Emitting Loads ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Load a value into a register.
(decl x64_load (Type SyntheticAmode ExtKind) Reg)
(rule 1 (x64_load (fits_in_32 ty) addr (ExtKind.SignExtend))
(x64_movsx (ext_mode (ty_bytes ty) 8)
addr))
(rule 2 (x64_load $I64 addr _ext_kind)
(x64_movq_rm addr))
(rule 2 (x64_load $F32 addr _ext_kind)
(x64_movss_load addr))
(rule 2 (x64_load $F64 addr _ext_kind)
(x64_movsd_load addr))
(rule 2 (x64_load $F128 addr _ext_kind)
(x64_movdqu_load addr))
(rule 2 (x64_load $F32X4 addr _ext_kind)
(x64_movups_load addr))
(rule 2 (x64_load $F64X2 addr _ext_kind)
(x64_movupd_load addr))
(rule 0 (x64_load (multi_lane _bits _lanes) addr _ext_kind)
(x64_movdqu_load addr))
(decl x64_mov (SyntheticAmode) Reg)
(spec (x64_mov addr)
(provide (= result (conv_to 64 (load_effect (extract 79 64 addr) 64 (extract 63 0 addr))))))
(rule (x64_mov addr) (x64_movq_rm addr))
(decl x64_movzx (ExtMode GprMem) Gpr)
(spec (x64_movzx mode src)
(provide
(= result
(conv_to
64
(zero_ext
32
(load_effect
(extract 79 64 src)
(switch mode
((ExtMode.BL) 8)
((ExtMode.BQ) 8)
((ExtMode.WL) 16)
((ExtMode.WQ) 16)
((ExtMode.LQ) 32))
(extract 63 0 src))))))
(require (or (= mode (ExtMode.BL))
(= mode (ExtMode.BQ))
(= mode (ExtMode.WL))
(= mode (ExtMode.WQ))
(= mode (ExtMode.LQ)))))
(rule (x64_movzx (ExtMode.BL) src) (x64_movzbl_rm src))
(rule (x64_movzx (ExtMode.BQ) src) (x64_movzbq_rm src))
(rule (x64_movzx (ExtMode.WL) src) (x64_movzwl_rm src))
(rule (x64_movzx (ExtMode.WQ) src) (x64_movzwq_rm src))
;; This instruction selection may seem strange but is correct in 64-bit mode:
;; section 3.4.1.1 of the Intel manual says that "32-bit operands generate a
;; 32-bit result, zero-extended to a 64-bit result in the destination
;; general-purpose register." This is applicable beyond `mov` but we use this
;; fact to zero-extend `src` into `dst`.
(rule (x64_movzx (ExtMode.LQ) src) (x64_movl_rm src))
(decl x64_movsx (ExtMode GprMem) Gpr)
(rule (x64_movsx (ExtMode.BL) src) (x64_movsbl_rm src))
(rule (x64_movsx (ExtMode.BQ) src) (x64_movsbq_rm src))
(rule (x64_movsx (ExtMode.WL) src) (x64_movswl_rm src))
(rule (x64_movsx (ExtMode.WQ) src) (x64_movswq_rm src))
(rule (x64_movsx (ExtMode.LQ) src) (x64_movslq_rm src))
(decl x64_movss_load (SyntheticAmode) Xmm)
(rule (x64_movss_load from) (x64_movss_a_m_or_avx from))
(decl x64_movss_store (SyntheticAmode Xmm) SideEffectNoResult)
(rule (x64_movss_store addr data) (x64_movss_c_m_mem_or_avx addr data))
(decl x64_movsd_load (SyntheticAmode) Xmm)
(rule (x64_movsd_load from) (x64_movsd_a_m_or_avx from))
(decl x64_movsd_store (SyntheticAmode Xmm) SideEffectNoResult)
(rule (x64_movsd_store addr data) (x64_movsd_c_m_mem_or_avx addr data))
(decl x64_movups_load (SyntheticAmode) Xmm)
(rule (x64_movups_load from) (x64_movups_a_or_avx from))
(decl x64_movups_store (SyntheticAmode Xmm) SideEffectNoResult)
(rule (x64_movups_store addr data) (x64_movups_b_mem_or_avx addr data))
(decl x64_movupd_load (SyntheticAmode) Xmm)
(rule (x64_movupd_load from) (x64_movupd_a_or_avx from))
(decl x64_movupd_store (SyntheticAmode Xmm) SideEffectNoResult)
(rule (x64_movupd_store addr data) (x64_movupd_b_mem_or_avx addr data))
;; Helper for creating `movd` instructions.
(decl x64_movd_to_gpr (Xmm) Gpr)
(rule (x64_movd_to_gpr from) (x64_movd_b from))
(rule 1 (x64_movd_to_gpr from)
(if-let true (has_avx))
(x64_vmovd_b from))
;; Helper for creating `movd` instructions.
(decl x64_movd_to_xmm (GprMem) Xmm)
(rule (x64_movd_to_xmm from) (x64_movd_a from))
(rule 1 (x64_movd_to_xmm from)
(if-let true (has_avx))
(x64_vmovd_a from))
;; Helper for creating `movq` instructions.
(decl x64_movq_to_xmm (GprMem) Xmm)
(rule (x64_movq_to_xmm src) (x64_movq_a src))
(rule 1 (x64_movq_to_xmm from)
(if-let true (has_avx))
(x64_vmovq_a from))
;; Helper for creating `movq` instructions.
(decl x64_movq_to_gpr (Xmm) Gpr)
(rule (x64_movq_to_gpr src) (x64_movq_b src))
(rule 1 (x64_movq_to_gpr from)
(if-let true (has_avx))
(x64_vmovq_b from))
(decl x64_movdqu_load (XmmMem) Xmm)
(rule (x64_movdqu_load from) (x64_movdqu_a_or_avx from))
(decl x64_movdqu_store (SyntheticAmode Xmm) SideEffectNoResult)
(rule (x64_movdqu_store addr data) (x64_movdqu_b_mem_or_avx addr data))
(decl x64_pmovsxbw (XmmMem) Xmm)
(rule (x64_pmovsxbw from) (x64_pmovsxbw_a_or_avx from))
(decl x64_pmovzxbw (XmmMem) Xmm)
(rule (x64_pmovzxbw from) (x64_pmovzxbw_a_or_avx from))
(decl x64_pmovsxwd (XmmMem) Xmm)
(rule (x64_pmovsxwd from) (x64_pmovsxwd_a_or_avx from))
(decl x64_pmovzxwd (XmmMem) Xmm)
(rule (x64_pmovzxwd from) (x64_pmovzxwd_a_or_avx from))
(decl x64_pmovsxdq (XmmMem) Xmm)
(rule (x64_pmovsxdq from) (x64_pmovsxdq_a_or_avx from))
(decl x64_pmovzxdq (XmmMem) Xmm)
(rule (x64_pmovzxdq from) (x64_pmovzxdq_a_or_avx from))
(decl x64_movrm (Type SyntheticAmode Gpr) SideEffectNoResult)
(spec (x64_movrm ty addr data)
(provide (= result (store_effect (extract 79 64 addr) ty (conv_to ty data) (extract 63 0 addr)))))
(rule (x64_movrm $I8 addr data) (x64_movb_mr_mem addr data))
(rule (x64_movrm $I16 addr data) (x64_movw_mr_mem addr data))
(rule (x64_movrm $I32 addr data) (x64_movl_mr_mem addr data))
(rule (x64_movrm $I64 addr data) (x64_movq_mr_mem addr data))
(decl x64_movimm_m (Type SyntheticAmode i32) SideEffectNoResult)
(rule (x64_movimm_m $I8 addr (i8_from_i32 imm)) (x64_movb_mi_mem addr (i8_cast_unsigned imm)))
(rule (x64_movimm_m $I16 addr (i16_from_i32 imm)) (x64_movw_mi_mem addr (i16_cast_unsigned imm)))
(rule (x64_movimm_m $I32 addr imm) (x64_movl_mi_mem addr (i32_cast_unsigned imm)))
(rule (x64_movimm_m $I64 addr imm) (x64_movq_mi_sxl_mem addr imm))
;; Load a constant into an XMM register.
(decl x64_xmm_load_const (Type VCodeConstant) Xmm)
(rule (x64_xmm_load_const ty const)
(x64_load ty (const_to_synthetic_amode const) (ExtKind.None)))
;;;; Flag Helpers ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;
;; These helpers are used to emit instructions that produce or consume flags.
;; The operations used here are by no means the only ones possible; they are
;; simply the ones currently used in Cranelift's lowerings.
;; Some operations produce flags.
(type ProduceFlagsOp (enum (Add) (Sub)))
(decl x64_produce_flags (ProduceFlagsOp Type Gpr GprMemImm) ProducesFlags)
(rule (x64_produce_flags (ProduceFlagsOp.Add) ty src1 src2)
(x64_add_with_flags_paired ty src1 src2))
(rule (x64_produce_flags (ProduceFlagsOp.Sub) ty src1 src2)
(x64_sub_with_flags_paired ty src1 src2))
;; This should only be use for instructions that _do_ produce flags that can be
;; consumed later. It is semantically "unsafe" and must be used correctly.
(decl asm_produce_flags (AssemblerOutputs) ProducesFlags)
(rule (asm_produce_flags (AssemblerOutputs.RetGpr inst gpr))
(ProducesFlags.ProducesFlagsReturnsResultWithConsumer inst gpr))
(rule (asm_produce_flags (AssemblerOutputs.RetValueRegs inst regs))
(ProducesFlags.ProducesFlagsReturnsResultWithConsumer inst (value_regs_get_gpr regs 0)))
;; Other operations consume _and_ produce flags--"chaining".
(type ChainFlagsOp (enum (Adc) (Sbb)))
(decl x64_chain_flags (ChainFlagsOp Type Gpr Gpr) ConsumesAndProducesFlags)
(rule (x64_chain_flags (ChainFlagsOp.Adc) ty src1 src2)
(x64_adc_chained ty src1 src2))
(rule (x64_chain_flags (ChainFlagsOp.Sbb) ty src1 src2)
(x64_sbb_chained ty src1 src2))
(decl asm_chain_flags (AssemblerOutputs) ConsumesAndProducesFlags)
(rule (asm_chain_flags (AssemblerOutputs.RetGpr inst gpr))
(ConsumesAndProducesFlags.ReturnsReg inst gpr))
;; Still others produce flags a part of a side-effect operation.
(type ProduceFlagsSideEffectOp (enum (Or) (Sbb)))
(decl x64_produce_flags_side_effect (ProduceFlagsSideEffectOp Type Gpr GprMemImm) ProducesFlags)
(rule (x64_produce_flags_side_effect (ProduceFlagsSideEffectOp.Or) (fits_in_64 ty) src1 src2)
(x64_or_with_flags_paired_side_effect ty src1 src2))
(rule (x64_produce_flags_side_effect (ProduceFlagsSideEffectOp.Sbb) (fits_in_64 ty) src1 src2)
(x64_sbb_paired_side_effect ty src1 src2))
(decl asm_produce_flags_side_effect (AssemblerOutputs) ProducesFlags)
(rule (asm_produce_flags_side_effect (AssemblerOutputs.RetGpr inst gpr))
(ProducesFlags.ProducesFlagsSideEffect inst))
(rule (asm_produce_flags_side_effect (AssemblerOutputs.SideEffect inst))
(ProducesFlags.ProducesFlagsSideEffect inst))
;; Other helpers for instruction emission.
(decl asm_consume_flags (AssemblerOutputs) ConsumesFlags)
(rule (asm_consume_flags (AssemblerOutputs.RetGpr inst gpr))
(ConsumesFlags.ConsumesFlagsReturnsResultWithProducer inst gpr))
(decl asm_consumes_flags_returns_gpr (AssemblerOutputs) ConsumesFlags)
(rule (asm_consumes_flags_returns_gpr (AssemblerOutputs.RetGpr inst gpr))
(ConsumesFlags.ConsumesFlagsReturnsReg inst gpr))
;;;; Instruction Constructors ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;;
;; These constructors create SSA-style `MInst`s. It is their responsibility to
;; maintain the invariant that each temporary register they allocate and define
;; only gets defined the once.
;; Helper for creating raw `add` instructions.
(decl x64_add_raw (Type Gpr GprMemImm) AssemblerOutputs)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 2 (x64_add_raw $I32 src1 (is_simm8 src2)) (x64_addl_mi_sxb_raw src1 src2))
(rule 2 (x64_add_raw $I64 src1 (is_simm8 src2)) (x64_addq_mi_sxb_raw src1 src2))
;; Match the remaining immediates.
(rule 1 (x64_add_raw $I8 src1 (is_imm8 src2)) (x64_addb_mi_raw src1 src2))
(rule 1 (x64_add_raw $I16 src1 (is_imm16 src2)) (x64_addw_mi_raw src1 src2))
(rule 1 (x64_add_raw $I32 src1 (is_imm32 src2)) (x64_addl_mi_raw src1 src2))
(rule 1 (x64_add_raw $I64 src1 (is_simm32 src2)) (x64_addq_mi_sxl_raw src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_add_raw $I8 src1 (is_gpr_mem src2)) (x64_addb_rm_raw src1 src2))
(rule 0 (x64_add_raw $I16 src1 (is_gpr_mem src2)) (x64_addw_rm_raw src1 src2))
(rule 0 (x64_add_raw $I32 src1 (is_gpr_mem src2)) (x64_addl_rm_raw src1 src2))
(rule 0 (x64_add_raw $I64 src1 (is_gpr_mem src2)) (x64_addq_rm_raw src1 src2))
;; When the overflow flag is not considered, we can use wider instructions than
;; necessary for 8/16-bit register-to-register operations to avoid CPU false
;; dependencies.
(decl x64_add_break_deps (Type Gpr GprMemImm) AssemblerOutputs)
(rule 1 (x64_add_break_deps $I8 src1 (is_gpr src2)) (x64_addl_rm_raw src1 src2))
(rule 1 (x64_add_break_deps $I16 src1 (is_gpr src2)) (x64_addl_rm_raw src1 src2))
(rule 0 (x64_add_break_deps ty src1 src2) (x64_add_raw ty src1 src2))
;; Normal use of `add` returns a `Gpr` register.
(decl x64_add (Type Gpr GprMemImm) Gpr)
(rule (x64_add ty src1 src2)
(emit_ret_gpr (x64_add_break_deps ty src1 src2)))
;; When using `add` for its overflow flag (OF), we track that the flags are
;; changed (and avoid the "dependency-breaking" rules that short-circuit
;; overflow).
(decl x64_add_with_flags_paired (Type Gpr GprMemImm) ProducesFlags)
(rule (x64_add_with_flags_paired ty src1 src2)
(asm_produce_flags (x64_add_raw ty src1 src2)))
;; Helper for creating raw `adc` instructions; Cranelift only uses the 64-bit
;; variant of this instruction. As with `add`, we match 8-bit immediates first;
;; this allows a smaller instruction encoding.
(decl x64_adc_raw (Type Gpr GprMemImm) AssemblerOutputs)
(rule 2 (x64_adc_raw $I64 src1 (is_simm8 src2)) (x64_adcq_mi_sxb_raw src1 src2))
(rule 1 (x64_adc_raw $I64 src1 (is_simm32 src2)) (x64_adcq_mi_sxl_raw src1 src2))
(rule 0 (x64_adc_raw $I64 src1 (is_gpr_mem src2)) (x64_adcq_rm_raw src1 src2))
;; Normal use of the `adc` instruction consumes a previously-produced flag.
(decl x64_adc_paired (Type Gpr GprMemImm) ConsumesFlags)
(rule (x64_adc_paired ty src1 src2)
(asm_consume_flags (x64_adc_raw ty src1 src2)))
;; We also use `adc` to modify flags that are used later.
(decl x64_adc_chained (Type Gpr GprMemImm) ConsumesAndProducesFlags)
(rule (x64_adc_chained ty src1 src2)
(asm_chain_flags (x64_adc_raw ty src1 src2)))
;; Helper for emitting raw `sub` instructions.
(decl x64_sub_raw (Type Gpr GprMemImm) AssemblerOutputs)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 3 (x64_sub_raw $I32 src1 (is_simm8 src2)) (x64_subl_mi_sxb_raw src1 src2))
(rule 3 (x64_sub_raw $I64 src1 (is_simm8 src2)) (x64_subq_mi_sxb_raw src1 src2))
;; Match the remaining immediates.
(rule 2 (x64_sub_raw $I8 src1 (is_imm8 src2)) (x64_subb_mi_raw src1 src2))
(rule 2 (x64_sub_raw $I16 src1 (is_imm16 src2)) (x64_subw_mi_raw src1 src2))
(rule 2 (x64_sub_raw $I32 src1 (is_imm32 src2)) (x64_subl_mi_raw src1 src2))
(rule 2 (x64_sub_raw $I64 src1 (is_simm32 src2)) (x64_subq_mi_sxl_raw src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_sub_raw $I8 src1 (is_gpr_mem src2)) (x64_subb_rm_raw src1 src2))
(rule 0 (x64_sub_raw $I16 src1 (is_gpr_mem src2)) (x64_subw_rm_raw src1 src2))
(rule 0 (x64_sub_raw $I32 src1 (is_gpr_mem src2)) (x64_subl_rm_raw src1 src2))
(rule 0 (x64_sub_raw $I64 src1 (is_gpr_mem src2)) (x64_subq_rm_raw src1 src2))
;; When the overflow flag is not considered, we can use wider instructions than
;; necessary for 8/16-bit register-to-register operations to avoid CPU false
;; dependencies.
(decl x64_sub_break_deps (Type Gpr GprMemImm) AssemblerOutputs)
(rule 1 (x64_sub_break_deps $I8 src1 (is_gpr src2)) (x64_subl_rm_raw src1 src2))
(rule 1 (x64_sub_break_deps $I16 src1 (is_gpr src2)) (x64_subl_rm_raw src1 src2))
(rule 0 (x64_sub_break_deps ty src1 src2) (x64_sub_raw ty src1 src2))
;; Normal use of `sub` returns a `Gpr` register.
(decl x64_sub (Type Gpr GprMemImm) Gpr)
(rule (x64_sub ty src1 src2)
(emit_ret_gpr (x64_sub_break_deps ty src1 src2)))
;; When using `sub` for its flags (OF, CF, SF), we track that the flags are
;; changed.
(decl x64_sub_with_flags_paired (Type Gpr GprMemImm) ProducesFlags)
(rule (x64_sub_with_flags_paired ty src1 src2)
(asm_produce_flags (x64_sub_raw ty src1 src2)))
;; Helper for creating raw `sbb` instructions; Cranelift only uses the 64-bit
;; variant of this instruction.
(decl x64_sbb_raw (Type Gpr GprMemImm) AssemblerOutputs)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 2 (x64_sbb_raw $I32 src1 (is_simm8 src2)) (x64_sbbl_mi_sxb_raw src1 src2))
(rule 2 (x64_sbb_raw $I64 src1 (is_simm8 src2)) (x64_sbbq_mi_sxb_raw src1 src2))
;; Match the remaining immediates.
(rule 1 (x64_sbb_raw $I8 src1 (is_imm8 src2)) (x64_sbbb_mi_raw src1 src2))
(rule 1 (x64_sbb_raw $I16 src1 (is_imm16 src2)) (x64_sbbw_mi_raw src1 src2))
(rule 1 (x64_sbb_raw $I32 src1 (is_imm32 src2)) (x64_sbbl_mi_raw src1 src2))
(rule 1 (x64_sbb_raw $I64 src1 (is_simm32 src2)) (x64_sbbq_mi_sxl_raw src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_sbb_raw $I8 src1 (is_gpr_mem src2)) (x64_sbbb_rm_raw src1 src2))
(rule 0 (x64_sbb_raw $I16 src1 (is_gpr_mem src2)) (x64_sbbw_rm_raw src1 src2))
(rule 0 (x64_sbb_raw $I32 src1 (is_gpr_mem src2)) (x64_sbbl_rm_raw src1 src2))
(rule 0 (x64_sbb_raw $I64 src1 (is_gpr_mem src2)) (x64_sbbq_rm_raw src1 src2))
;; When the overflow flag is not considered, we can use wider instructions than
;; necessary for 8/16-bit register-to-register operations to avoid CPU false
;; dependencies.
(decl x64_sbb_break_deps (Type Gpr GprMemImm) AssemblerOutputs)
(rule 1 (x64_sbb_break_deps $I8 src1 (is_gpr src2)) (x64_sbbl_rm_raw src1 src2))
(rule 1 (x64_sbb_break_deps $I16 src1 (is_gpr src2)) (x64_sbbl_rm_raw src1 src2))
(rule 0 (x64_sbb_break_deps ty src1 src2) (x64_sbb_raw ty src1 src2))
;; Normal use of the `sbb` instruction consumes previously-produced flags (OF,
;; CF, SF).
(decl x64_sbb_paired (Type Gpr GprMemImm) ConsumesFlags)
(rule (x64_sbb_paired ty src1 src2)
(asm_consume_flags (x64_sbb_break_deps ty src1 src2)))
;; We also use `sbb` to modify flags that all later used.
(decl x64_sbb_chained (Type Gpr GprMemImm) ConsumesAndProducesFlags)
(rule (x64_sbb_chained ty src1 src2)
(asm_chain_flags (x64_sbb_raw ty src1 src2)))
;; We also use `sbb` in side-effecting operations.
(decl x64_sbb_paired_side_effect (Type Gpr GprMemImm) ProducesFlags)
(rule (x64_sbb_paired_side_effect ty src1 src2)
(asm_produce_flags_side_effect (x64_sbb_raw ty src1 src2)))
;; Helper for creating `mul` instructions or `imul` instructions (depending
;; on `signed`). For the 8-bit rules, see `x64_mul8`.
(decl x64_mul_raw (Type bool Gpr GprMem) AssemblerOutputs)
(rule (x64_mul_raw $I16 false src1 src2) (x64_mulw_m_raw src1 src2))
(rule (x64_mul_raw $I32 false src1 src2) (x64_mull_m_raw src1 src2))
(rule (x64_mul_raw $I64 false src1 src2) (x64_mulq_m_raw src1 src2))
(rule (x64_mul_raw $I16 true src1 src2) (x64_imulw_m_raw src1 src2))
(rule (x64_mul_raw $I32 true src1 src2) (x64_imull_m_raw src1 src2))
(rule (x64_mul_raw $I64 true src1 src2) (x64_imulq_m_raw src1 src2))
(decl x64_mul (Type bool Gpr GprMem) ValueRegs)
(rule 0 (x64_mul ty signed src1 src2)
(emit_ret_value_regs (x64_mul_raw ty signed src1 src2)))
;; Special case the `mulx` pattern with the BMI2 instruction set.
;;
;; Note that mulx returns the high bits in the first result and the low bits in
;; the second result, so here the result registers are swapped to match
;; `x64_mul` above.
(rule 1 (x64_mul $I32 false src1 src2)
(if-let true (has_bmi2))
(let ((regs ValueRegs (x64_mulxl_rvm src2 src1)))
(value_regs (value_regs_get regs 1) (value_regs_get regs 0))))
(rule 1 (x64_mul $I64 false src1 src2)
(if-let true (has_bmi2))
(let ((regs ValueRegs (x64_mulxq_rvm src2 src1)))
(value_regs (value_regs_get regs 1) (value_regs_get regs 0))))
(decl x64_mulx_hi (Type Gpr GprMem) Gpr)
(rule (x64_mulx_hi $I32 src1 src2) (x64_mulxl_rvm_hi src2 src1))
(rule (x64_mulx_hi $I64 src1 src2) (x64_mulxq_rvm_hi src2 src1))
(decl x64_mulxl_rvm_hi (GprMem Gpr) Gpr)
(extern constructor x64_mulxl_rvm_hi x64_mulxl_rvm_hi)
(decl x64_mulxq_rvm_hi (GprMem Gpr) Gpr)
(extern constructor x64_mulxq_rvm_hi x64_mulxq_rvm_hi)
(decl x64_mul_lo_with_flags_paired (Type bool Gpr GprMem) ProducesFlags)
(rule (x64_mul_lo_with_flags_paired ty signed src1 src2)
(asm_produce_flags (x64_mul_raw ty signed src1 src2)))
;; Get the invalid register as writable
(decl writable_invalid_gpr () WritableGpr)
(extern constructor writable_invalid_gpr writable_invalid_gpr)
;; Helper for creating `imul` instructions.
(decl x64_imul (Type Gpr GprMem) Gpr)
(rule (x64_imul $I16 src1 src2) (x64_imulw_rm src1 src2))
(rule (x64_imul $I32 src1 src2) (x64_imull_rm src1 src2))
(rule (x64_imul $I64 src1 src2) (x64_imulq_rm src1 src2))
;; Helper for creating `imul` instructions with an immediate operand. Match
;; 8-bit immediates first to allow a smaller instruction encoding.
(decl x64_imul_imm (Type GprMem i32) Gpr)
(rule 2 (x64_imul_imm $I16 src1 (i8_from_i32 src2)) (x64_imulw_rmi_sxb src1 src2))
(rule 2 (x64_imul_imm $I32 src1 (i8_from_i32 src2)) (x64_imull_rmi_sxb src1 src2))
(rule 2 (x64_imul_imm $I64 src1 (i8_from_i32 src2)) (x64_imulq_rmi_sxb src1 src2))
(rule 1 (x64_imul_imm $I16 src1 (i16_from_i32 src2)) (x64_imulw_rmi src1 (i16_cast_unsigned src2)))
(rule 1 (x64_imul_imm $I32 src1 src2) (x64_imull_rmi src1 (i32_cast_unsigned src2)))
(rule 1 (x64_imul_imm $I64 src1 src2) (x64_imulq_rmi_sxl src1 src2))
;; Helper for creating `mul` instructions or `imul` instructions (depending
;; on `signed`) for 8-bit operands.
(decl x64_mul8_raw (bool Gpr GprMem) AssemblerOutputs)
(rule (x64_mul8_raw false src1 src2) (x64_mulb_m_raw src1 src2))
(rule (x64_mul8_raw true src1 src2) (x64_imulb_m_raw src1 src2))
(decl x64_mul8 (bool Gpr GprMem) Gpr)
(rule (x64_mul8 signed src1 src2)
(emit_ret_gpr (x64_mul8_raw signed src1 src2)))
(decl x64_mul8_with_flags_paired (bool Gpr GprMem) ProducesFlags)
(rule (x64_mul8_with_flags_paired signed src1 src2)
(asm_produce_flags (x64_mul8_raw signed src1 src2)))
;; Helper for emitting `and` instructions.
(decl x64_and (Type Gpr GprMemImm) Gpr)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 3 (x64_and $I32 src1 (is_simm8 src2)) (x64_andl_mi_sxb src1 src2))
(rule 3 (x64_and $I64 src1 (is_simm8 src2)) (x64_andq_mi_sxb src1 src2))
;; Match the remaining immediates.
(rule 2 (x64_and $I8 src1 (is_imm8 src2)) (x64_andb_mi src1 src2))
(rule 2 (x64_and $I16 src1 (is_imm16 src2)) (x64_andw_mi src1 src2))
(rule 2 (x64_and $I32 src1 (is_imm32 src2)) (x64_andl_mi src1 src2))
(rule 2 (x64_and $I64 src1 (is_simm32 src2)) (x64_andq_mi_sxl src1 src2))
;; Use wider instructions than necessary for 8/16-bit register-to-register
;; operations to avoid CPU false dependencies.
(rule 1 (x64_and $I8 src1 (is_gpr src2)) (x64_andl_rm src1 src2))
(rule 1 (x64_and $I16 src1 (is_gpr src2)) (x64_andl_rm src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_and $I8 src1 (is_gpr_mem src2)) (x64_andb_rm src1 src2))
(rule 0 (x64_and $I16 src1 (is_gpr_mem src2)) (x64_andw_rm src1 src2))
(rule 0 (x64_and $I32 src1 (is_gpr_mem src2)) (x64_andl_rm src1 src2))
(rule 0 (x64_and $I64 src1 (is_gpr_mem src2)) (x64_andq_rm src1 src2))
;; Helper for emitting raw `or` instructions.
(decl x64_or_raw (Type Gpr GprMemImm) AssemblerOutputs)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 2 (x64_or_raw $I32 src1 (is_simm8 src2)) (x64_orl_mi_sxb_raw src1 src2))
(rule 2 (x64_or_raw $I64 src1 (is_simm8 src2)) (x64_orq_mi_sxb_raw src1 src2))
;; Match the remaining immediates.
(rule 1 (x64_or_raw $I8 src1 (is_imm8 src2)) (x64_orb_mi_raw src1 src2))
(rule 1 (x64_or_raw $I16 src1 (is_imm16 src2)) (x64_orw_mi_raw src1 src2))
(rule 1 (x64_or_raw $I32 src1 (is_imm32 src2)) (x64_orl_mi_raw src1 src2))
(rule 1 (x64_or_raw $I64 src1 (is_simm32 src2)) (x64_orq_mi_sxl_raw src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_or_raw $I8 src1 (is_gpr_mem src2)) (x64_orb_rm_raw src1 src2))
(rule 0 (x64_or_raw $I16 src1 (is_gpr_mem src2)) (x64_orw_rm_raw src1 src2))
(rule 0 (x64_or_raw $I32 src1 (is_gpr_mem src2)) (x64_orl_rm_raw src1 src2))
(rule 0 (x64_or_raw $I64 src1 (is_gpr_mem src2)) (x64_orq_rm_raw src1 src2))
;; When flags are not considered, we can use wider instructions than necessary
;; for 8/16-bit register-to-register operations to avoid CPU false dependencies.
(decl x64_or_break_deps (Type Gpr GprMemImm) AssemblerOutputs)
(rule 1 (x64_or_break_deps $I8 src1 (is_gpr src2)) (x64_orl_rm_raw src1 src2))
(rule 1 (x64_or_break_deps $I16 src1 (is_gpr src2)) (x64_orl_rm_raw src1 src2))
(rule 0 (x64_or_break_deps ty src1 src2) (x64_or_raw ty src1 src2))
;; Normal use of `or` returns a `Gpr` register.
(decl x64_or (Type Gpr GprMemImm) Gpr)
(rule (x64_or ty src1 src2)
(emit_ret_gpr (x64_or_break_deps ty src1 src2)))
;; When using `or` for its flags (SF, ZF, PF), we track that the flags are
;; changed. Note t
(decl x64_or_with_flags_paired_side_effect (Type Gpr GprMemImm) ProducesFlags)
(rule (x64_or_with_flags_paired_side_effect ty src1 src2)
(asm_produce_flags_side_effect (x64_or_raw ty src1 src2)))
;; Helper for emitting `xor` instructions.
(decl x64_xor (Type Gpr GprMemImm) Gpr)
;; Match 8-bit immediates first; allows a smaller instruction encoding.
(rule 3 (x64_xor $I32 src1 (is_simm8 src2)) (x64_xorl_mi_sxb src1 src2))
(rule 3 (x64_xor $I64 src1 (is_simm8 src2)) (x64_xorq_mi_sxb src1 src2))
;; Match the remaining immediates.
(rule 2 (x64_xor $I8 src1 (is_imm8 src2)) (x64_xorb_mi src1 src2))
(rule 2 (x64_xor $I16 src1 (is_imm16 src2)) (x64_xorw_mi src1 src2))
(rule 2 (x64_xor $I32 src1 (is_imm32 src2)) (x64_xorl_mi src1 src2))
(rule 2 (x64_xor $I64 src1 (is_simm32 src2)) (x64_xorq_mi_sxl src1 src2))
;; Use wider instructions than necessary for 8/16-bit register-to-register
;; operations to avoid CPU false dependencies.
(rule 1 (x64_xor $I8 src1 (is_gpr src2)) (x64_xorl_rm src1 src2))
(rule 1 (x64_xor $I16 src1 (is_gpr src2)) (x64_xorl_rm src1 src2))
;; Match the operand size to the instruction width.
(rule 0 (x64_xor $I8 src1 (is_gpr_mem src2)) (x64_xorb_rm src1 src2))
(rule 0 (x64_xor $I16 src1 (is_gpr_mem src2)) (x64_xorw_rm src1 src2))
(rule 0 (x64_xor $I32 src1 (is_gpr_mem src2)) (x64_xorl_rm src1 src2))
(rule 0 (x64_xor $I64 src1 (is_gpr_mem src2)) (x64_xorq_rm src1 src2))
;; Helper for `andn` instructions
;;
;; Note that 8/16-bit versions of these instructions do not exist, so for
;; those bit-widths the 32-bit version of the instruction is used which has the
;; desired semantics for the lower bits of the register.
(decl x64_andn (Type Gpr GprMem) Gpr)
(rule (x64_andn $I8 src1 src2) (x64_andnl_rvm src1 src2))
(rule (x64_andn $I16 src1 src2) (x64_andnl_rvm src1 src2))
(rule (x64_andn $I32 src1 src2) (x64_andnl_rvm src1 src2))
(rule (x64_andn $I64 src1 src2) (x64_andnq_rvm src1 src2))
;; Helper for emitting immediates with an `i64` value. Note that
;; integer constants in ISLE are always parsed as `i128`s; this enables
;; negative numbers to be used as immediates.
(decl imm_i64 (Type i64) Reg)
(rule (imm_i64 ty value)
(imm ty (i64_cast_unsigned value)))
;; Helper for emitting immediates.
;;
;; Note that if `Type` is less than 64-bits then the upper bits of the `imm`
;; argument will be set to zero and lost.
;;
;; Recursion: at most once to implement floats with integer bit patterns.
(decl rec imm (Type u64) Reg)
;; Base case: integers of up to at most 32-bits.
;;
;; FIXME: the immediate argument to this constructor is `u64` but it's logically
;; interpreted as the bit pattern for a signed 32-bit immediate. That means
;; that ideally this would convert the immediate to a 64-bit signed immediate,
;; fallibly convert that to a signed 32-bit integer, and then convert that to
;; unsigned to pass to the raw instruction. In doing so there would be a
;; guarantee that the value in the register is the same logical value as the
;; immediate passed to this constructor. This is not possible today though
;; because literals like `0x8000_0000_u64` don't convert to `i32`.
(rule 0 (imm (fits_in_32 (ty_int ty)) (u32_from_u64 imm)) (x64_movl_oi imm))
;; Base cases for other types
(rule 1 (imm $I64 imm) (x64_movabsq_oi imm))
(rule 1 (imm $F16 (u64_extract_non_zero bits)) (bitcast_gpr_to_xmm 16 (imm $I16 bits)))
(rule 1 (imm $F32 (u64_extract_non_zero bits)) (x64_movd_to_xmm (imm $I32 bits)))
(rule 1 (imm $F64 (u64_extract_non_zero bits)) (x64_movq_to_xmm (imm $I64 bits)))
;; Special case: a 64-bit immediate which sign extends from a 32-bit immediate.
(rule 2 (imm $I64 imm)
(if-let imm32 (i64_try_into_i32 (u64_cast_signed imm)))
(x64_movq_mi_sxl imm32))
;; Special case: a 64-bit immediate which zero extends from a 32-bit immediate.
;;
;; Note that `movl` here will zero-extend the destination register in 64-bit
;; mode which is the zero-extension we want.
(rule 3 (imm $I64 (u32_from_u64 imm32))
(x64_movl_oi imm32))
;; Special case the 0 immediate:
(rule 4 (imm (fits_in_64 (ty_int ty)) 0)
(let ((tmp Gpr (gpr_uninit_value)))
(x64_xor ty tmp tmp)))
(rule 5 (imm ty @ (multi_lane _bits _lanes) 0) (xmm_to_reg (xmm_zero ty)))
(rule 6 (imm ty @ $F16 0) (xmm_zero ty))
(rule 6 (imm ty @ $F32 0) (xmm_zero ty))
(rule 6 (imm ty @ $F64 0) (xmm_zero ty))
;; TODO: use cmpeqp{s,d} for all 1s float immediates
(decl xmm_zero (Type) Xmm)
(rule (xmm_zero ty)
(let ((tmp Xmm (xmm_uninit_value)))
(x64_xor_vector ty tmp tmp)))
;; Helper for creating `rotl` instructions.
(decl x64_rotl (Type Gpr Imm8Gpr) Gpr)
(rule (x64_rotl $I8 src1 (Imm8Gpr.Gpr src2)) (x64_rolb_mc src1 src2))
(rule (x64_rotl $I8 src1 (Imm8Gpr.Imm8 src2)) (x64_rolb_mi src1 src2))
(rule (x64_rotl $I16 src1 (Imm8Gpr.Gpr src2)) (x64_rolw_mc src1 src2))
(rule (x64_rotl $I16 src1 (Imm8Gpr.Imm8 src2)) (x64_rolw_mi src1 src2))
(rule (x64_rotl $I32 src1 (Imm8Gpr.Gpr src2)) (x64_roll_mc src1 src2))
(rule (x64_rotl $I32 src1 (Imm8Gpr.Imm8 src2)) (x64_roll_mi src1 src2))
(rule (x64_rotl $I64 src1 (Imm8Gpr.Gpr src2)) (x64_rolq_mc src1 src2))
(rule (x64_rotl $I64 src1 (Imm8Gpr.Imm8 src2)) (x64_rolq_mi src1 src2))
(rule 1 (x64_rotl $I8 src1 (Imm8Gpr.Imm8 1)) (x64_rolb_m1 src1))
(rule 1 (x64_rotl $I16 src1 (Imm8Gpr.Imm8 1)) (x64_rolw_m1 src1))
(rule 1 (x64_rotl $I32 src1 (Imm8Gpr.Imm8 1)) (x64_roll_m1 src1))
(rule 1 (x64_rotl $I64 src1 (Imm8Gpr.Imm8 1)) (x64_rolq_m1 src1))
(rule 2 (x64_rotl (ty_32_or_64 ty) src (Imm8Gpr.Imm8 imm))
(if-let true (has_bmi2))
(x64_rorx ty src (u8_wrapping_sub (ty_bits ty) imm)))
;; Helper for creating `rotr` instructions.
(decl x64_rotr (Type Gpr Imm8Gpr) Gpr)
(rule (x64_rotr $I8 src1 (Imm8Gpr.Gpr src2)) (x64_rorb_mc src1 src2))
(rule (x64_rotr $I8 src1 (Imm8Gpr.Imm8 src2)) (x64_rorb_mi src1 src2))
(rule (x64_rotr $I16 src1 (Imm8Gpr.Gpr src2)) (x64_rorw_mc src1 src2))
(rule (x64_rotr $I16 src1 (Imm8Gpr.Imm8 src2)) (x64_rorw_mi src1 src2))
(rule (x64_rotr $I32 src1 (Imm8Gpr.Gpr src2)) (x64_rorl_mc src1 src2))
(rule (x64_rotr $I32 src1 (Imm8Gpr.Imm8 src2)) (x64_rorl_mi src1 src2))
(rule (x64_rotr $I64 src1 (Imm8Gpr.Gpr src2)) (x64_rorq_mc src1 src2))
(rule (x64_rotr $I64 src1 (Imm8Gpr.Imm8 src2)) (x64_rorq_mi src1 src2))
(rule 1 (x64_rotr $I8 src1 (Imm8Gpr.Imm8 1)) (x64_rorb_m1 src1))
(rule 1 (x64_rotr $I16 src1 (Imm8Gpr.Imm8 1)) (x64_rorw_m1 src1))
(rule 1 (x64_rotr $I32 src1 (Imm8Gpr.Imm8 1)) (x64_rorl_m1 src1))
(rule 1 (x64_rotr $I64 src1 (Imm8Gpr.Imm8 1)) (x64_rorq_m1 src1))
(rule 2 (x64_rotr (ty_32_or_64 ty) src (Imm8Gpr.Imm8 imm))
(if-let true (has_bmi2))
(x64_rorx ty src imm))
;; Helper for creating `shl` instructions.
(decl x64_shl (Type Gpr Imm8Gpr) Gpr)
(rule (x64_shl $I8 src1 (Imm8Gpr.Gpr src2)) (x64_shlb_mc src1 src2))
(rule (x64_shl $I8 src1 (Imm8Gpr.Imm8 src2)) (x64_shlb_mi src1 src2))
(rule (x64_shl $I16 src1 (Imm8Gpr.Gpr src2)) (x64_shlw_mc src1 src2))
(rule (x64_shl $I16 src1 (Imm8Gpr.Imm8 src2)) (x64_shlw_mi src1 src2))
(rule (x64_shl $I32 src1 (Imm8Gpr.Gpr src2)) (x64_shll_mc src1 src2))
(rule (x64_shl $I32 src1 (Imm8Gpr.Imm8 src2)) (x64_shll_mi src1 src2))
(rule (x64_shl $I64 src1 (Imm8Gpr.Gpr src2)) (x64_shlq_mc src1 src2))
(rule (x64_shl $I64 src1 (Imm8Gpr.Imm8 src2)) (x64_shlq_mi src1 src2))
(rule 1 (x64_shl $I8 src1 (Imm8Gpr.Imm8 1)) (x64_shlb_m1 src1))
(rule 1 (x64_shl $I16 src1 (Imm8Gpr.Imm8 1)) (x64_shlw_m1 src1))
(rule 1 (x64_shl $I32 src1 (Imm8Gpr.Imm8 1)) (x64_shll_m1 src1))
(rule 1 (x64_shl $I64 src1 (Imm8Gpr.Imm8 1)) (x64_shlq_m1 src1))
;; With BMI2 the `shlx` instruction is also available, and it's unconditionally
;; used for registers shifted by registers since it provides more freedom
;; in regalloc since nothing is constrained. Note that the `shlx` instruction
;; doesn't encode an immediate so any immediate-based shift still uses `shl`.
(rule 1 (x64_shl (ty_32_or_64 ty) src1 (Imm8Gpr.Gpr src2))
(if-let true (has_bmi2))
(x64_shlx ty src1 src2))
;; Helper for creating logical shift-right instructions.
(decl x64_shr (Type Gpr Imm8Gpr) Gpr)
(rule (x64_shr $I8 src1 (Imm8Gpr.Gpr src2)) (x64_shrb_mc src1 src2))
(rule (x64_shr $I8 src1 (Imm8Gpr.Imm8 src2)) (x64_shrb_mi src1 src2))
(rule (x64_shr $I16 src1 (Imm8Gpr.Gpr src2)) (x64_shrw_mc src1 src2))
(rule (x64_shr $I16 src1 (Imm8Gpr.Imm8 src2)) (x64_shrw_mi src1 src2))
(rule (x64_shr $I32 src1 (Imm8Gpr.Gpr src2)) (x64_shrl_mc src1 src2))
(rule (x64_shr $I32 src1 (Imm8Gpr.Imm8 src2)) (x64_shrl_mi src1 src2))
(rule (x64_shr $I64 src1 (Imm8Gpr.Gpr src2)) (x64_shrq_mc src1 src2))
(rule (x64_shr $I64 src1 (Imm8Gpr.Imm8 src2)) (x64_shrq_mi src1 src2))
(rule 1 (x64_shr $I8 src1 (Imm8Gpr.Imm8 1)) (x64_shrb_m1 src1))
(rule 1 (x64_shr $I16 src1 (Imm8Gpr.Imm8 1)) (x64_shrw_m1 src1))
(rule 1 (x64_shr $I32 src1 (Imm8Gpr.Imm8 1)) (x64_shrl_m1 src1))
(rule 1 (x64_shr $I64 src1 (Imm8Gpr.Imm8 1)) (x64_shrq_m1 src1))
;; see `x64_shl` for more info about this rule
(rule 1 (x64_shr (ty_32_or_64 ty) src1 (Imm8Gpr.Gpr src2))
(if-let true (has_bmi2))
(x64_shrx ty src1 src2))
;; Helper for creating arithmetic shift-right instructions.
(decl x64_sar (Type Gpr Imm8Gpr) Gpr)
(rule (x64_sar $I8 src1 (Imm8Gpr.Gpr src2)) (x64_sarb_mc src1 src2))
(rule (x64_sar $I8 src1 (Imm8Gpr.Imm8 src2)) (x64_sarb_mi src1 src2))
(rule (x64_sar $I16 src1 (Imm8Gpr.Gpr src2)) (x64_sarw_mc src1 src2))
(rule (x64_sar $I16 src1 (Imm8Gpr.Imm8 src2)) (x64_sarw_mi src1 src2))
(rule (x64_sar $I32 src1 (Imm8Gpr.Gpr src2)) (x64_sarl_mc src1 src2))
(rule (x64_sar $I32 src1 (Imm8Gpr.Imm8 src2)) (x64_sarl_mi src1 src2))
(rule (x64_sar $I64 src1 (Imm8Gpr.Gpr src2)) (x64_sarq_mc src1 src2))
(rule (x64_sar $I64 src1 (Imm8Gpr.Imm8 src2)) (x64_sarq_mi src1 src2))
(rule 1 (x64_sar $I8 src1 (Imm8Gpr.Imm8 1)) (x64_sarb_m1 src1))
(rule 1 (x64_sar $I16 src1 (Imm8Gpr.Imm8 1)) (x64_sarw_m1 src1))
(rule 1 (x64_sar $I32 src1 (Imm8Gpr.Imm8 1)) (x64_sarl_m1 src1))
(rule 1 (x64_sar $I64 src1 (Imm8Gpr.Imm8 1)) (x64_sarq_m1 src1))
;; see `x64_shl` for more info about this rule
(rule 1 (x64_sar (ty_32_or_64 ty) src1 (Imm8Gpr.Gpr src2))
(if-let true (has_bmi2))
(x64_sarx ty src1 src2))
;; Helper for creating `shld` instructions.
(decl x64_shld (Type Gpr Gpr u8) Gpr)
;; NB: i8 is intentionally missing here as x64 doesn't have such an instruction
(rule (x64_shld $I16 src1 src2 amt) (x64_shldw_mri src1 src2 amt))
(rule (x64_shld $I32 src1 src2 amt) (x64_shldl_mri src1 src2 amt))
(rule (x64_shld $I64 src1 src2 amt) (x64_shldq_mri src1 src2 amt))
;; Helper for creating zeroing-of-high-bits instructions bzhi
(decl x64_bzhi (Type GprMem Gpr) Gpr)
(rule (x64_bzhi $I32 src1 src2) (x64_bzhil_rmv src1 src2))
(rule (x64_bzhi $I64 src1 src2) (x64_bzhiq_rmv src1 src2))
;; Helper for creating byteswap instructions.
;; In x64, 32- and 64-bit registers use BSWAP instruction, and
;; for 16-bit registers one must instead use xchg or rol/ror
(decl x64_bswap (Type Gpr) Gpr)
(rule (x64_bswap $I32 src) (x64_bswapl_o src))
(rule (x64_bswap $I64 src) (x64_bswapq_o src))
;; Helper for creating `cmp` instructions.
(decl x64_cmp (Type Gpr GprMemImm) ProducesFlags)
;; If the rhs is an immediate try to use the 8-bit form if the immediate fits.
(rule 2 (x64_cmp $I16 src1 (is_simm8 src2)) (x64_cmpw_mi_sxb src1 src2))
(rule 2 (x64_cmp $I32 src1 (is_simm8 src2)) (x64_cmpl_mi_sxb src1 src2))
(rule 2 (x64_cmp $I64 src1 (is_simm8 src2)) (x64_cmpq_mi_sxb src1 src2))
;; Base case: rhs is an immediate
(rule 1 (x64_cmp $I8 src1 (is_imm8 src2)) (x64_cmpb_mi src1 src2))
(rule 1 (x64_cmp $I16 src1 (is_imm16 src2)) (x64_cmpw_mi src1 src2))
(rule 1 (x64_cmp $I32 src1 (is_imm32 src2)) (x64_cmpl_mi src1 src2))
(rule 1 (x64_cmp $I64 src1 (is_simm32 src2)) (x64_cmpq_mi src1 src2))
;; Base case: rhs is a GprMem operand.
(rule 0 (x64_cmp $I8 src1 (is_gpr_mem src2)) (x64_cmpb_rm src1 src2))
(rule 0 (x64_cmp $I16 src1 (is_gpr_mem src2)) (x64_cmpw_rm src1 src2))
(rule 0 (x64_cmp $I32 src1 (is_gpr_mem src2)) (x64_cmpl_rm src1 src2))
(rule 0 (x64_cmp $I64 src1 (is_gpr_mem src2)) (x64_cmpq_rm src1 src2))
;; Helper for creating floating-point comparison instructions (`UCOMIS[S|D]`).
(decl x64_ucomis (Type Xmm XmmMem) ProducesFlags)
(rule (x64_ucomis $F32 src1 src2) (x64_ucomiss_a_or_avx src1 src2))
(rule (x64_ucomis $F64 src1 src2) (x64_ucomisd_a_or_avx src1 src2))
;; Helper for creating `test` instructions.
(decl x64_test (Type Gpr GprMemImm) ProducesFlags)
(rule 1 (x64_test $I8 src1 (is_imm8 src2)) (x64_testb_mi src1 src2))
(rule 1 (x64_test $I16 src1 (is_imm16 src2)) (x64_testw_mi src1 src2))
(rule 1 (x64_test $I32 src1 (is_imm32 src2)) (x64_testl_mi src1 src2))
(rule 1 (x64_test $I64 src1 (is_simm32 src2)) (x64_testq_mi src1 src2))
(rule 0 (x64_test $I8 src1 (is_gpr_mem src2)) (x64_testb_mr src2 src1))
(rule 0 (x64_test $I16 src1 (is_gpr_mem src2)) (x64_testw_mr src2 src1))
(rule 0 (x64_test $I32 src1 (is_gpr_mem src2)) (x64_testl_mr src2 src1))
(rule 0 (x64_test $I64 src1 (is_gpr_mem src2)) (x64_testq_mr src2 src1))
;; Helper for creating `ptest` instructions.
(decl x64_ptest (Xmm XmmMem) ProducesFlags)
(rule (x64_ptest src1 src2) (x64_ptest_rm_or_avx src1 src2))
;; Helper for creating `cmove` instructions. Note that these instructions do not
;; always result in a single emitted x86 instruction; e.g., XmmCmove uses jumps
;; to conditionally move the selected value into an XMM register.
;;
;; Also note that 8/16-bit conditional moves use the 32-bit instruction variant
;; since that is semantically equivalent and helps break data dependencies by
;; defining the entire register.
;;
;; Also note that the mnemonics used in `CC` don't always match those used in
;; the instruction variants and that is intentiona. This is due to the fact
;; that the Intel manual (and assemblers) support multiple mnemonics for the
;; same instruction but disassemblers only print one mnemonic and that's the
;; name used here.
(decl cmove (Type CC GprMem Gpr) ConsumesFlags)
(rule 0 (cmove (fits_in_32 _) (CC.O) c a) (x64_cmovol_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NO) c a) (x64_cmovnol_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.B) c a) (x64_cmovbl_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NB) c a) (x64_cmovael_rm a c)) ;; nb == ae
(rule 0 (cmove (fits_in_32 _) (CC.Z) c a) (x64_cmovel_rm a c)) ;; z == e
(rule 0 (cmove (fits_in_32 _) (CC.NZ) c a) (x64_cmovnel_rm a c)) ;; nz == ne
(rule 0 (cmove (fits_in_32 _) (CC.BE) c a) (x64_cmovbel_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NBE) c a) (x64_cmoval_rm a c)) ;; nbe == a
(rule 0 (cmove (fits_in_32 _) (CC.S) c a) (x64_cmovsl_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NS) c a) (x64_cmovnsl_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.L) c a) (x64_cmovll_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NL) c a) (x64_cmovgel_rm a c)) ;; nl == ge
(rule 0 (cmove (fits_in_32 _) (CC.LE) c a) (x64_cmovlel_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NLE) c a) (x64_cmovgl_rm a c)) ;; nle == g
(rule 0 (cmove (fits_in_32 _) (CC.P) c a) (x64_cmovpl_rm a c))
(rule 0 (cmove (fits_in_32 _) (CC.NP) c a) (x64_cmovnpl_rm a c))
(rule 1 (cmove $I64 (CC.O) c a) (x64_cmovoq_rm a c))
(rule 1 (cmove $I64 (CC.NO) c a) (x64_cmovnoq_rm a c))
(rule 1 (cmove $I64 (CC.B) c a) (x64_cmovbq_rm a c))
(rule 1 (cmove $I64 (CC.NB) c a) (x64_cmovaeq_rm a c)) ;; nb == ae
(rule 1 (cmove $I64 (CC.Z) c a) (x64_cmoveq_rm a c)) ;; z == e
(rule 1 (cmove $I64 (CC.NZ) c a) (x64_cmovneq_rm a c)) ;; nz == ne
(rule 1 (cmove $I64 (CC.BE) c a) (x64_cmovbeq_rm a c))
(rule 1 (cmove $I64 (CC.NBE) c a) (x64_cmovaq_rm a c)) ;; nbe == a
(rule 1 (cmove $I64 (CC.S) c a) (x64_cmovsq_rm a c))
(rule 1 (cmove $I64 (CC.NS) c a) (x64_cmovnsq_rm a c))
(rule 1 (cmove $I64 (CC.L) c a) (x64_cmovlq_rm a c))
(rule 1 (cmove $I64 (CC.NL) c a) (x64_cmovgeq_rm a c)) ;; nl == ge
(rule 1 (cmove $I64 (CC.LE) c a) (x64_cmovleq_rm a c))
(rule 1 (cmove $I64 (CC.NLE) c a) (x64_cmovgq_rm a c)) ;; nle == g
(rule 1 (cmove $I64 (CC.P) c a) (x64_cmovpq_rm a c))
(rule 1 (cmove $I64 (CC.NP) c a) (x64_cmovnpq_rm a c))
(decl cmove_xmm (Type CC Xmm Xmm) ConsumesFlags)
(rule (cmove_xmm ty cc consequent alternative)
(let ((dst WritableXmm (temp_writable_xmm)))
(ConsumesFlags.ConsumesFlagsReturnsReg
(MInst.XmmCmove ty cc consequent alternative dst)
dst)))
;; Helper for creating `setcc` instructions.
;;
;; Note that the mnemonics here don't always match exactly with the raw
;; instruction and that's intentional. The Intel manual documents multiple
;; mnemonics for the same opcode and the ones in Cranelift (CC.*) don't
;; match the ones that Capstone disassembles to (which the assembler matches).
(decl x64_setcc (CC) ConsumesFlags)
(rule (x64_setcc (CC.O)) (x64_seto_m))
(rule (x64_setcc (CC.NO)) (x64_setno_m))
(rule (x64_setcc (CC.B)) (x64_setb_m))
(rule (x64_setcc (CC.NB)) (x64_setae_m)) ;; nb == ae
(rule (x64_setcc (CC.Z)) (x64_sete_m)) ;; z == e
(rule (x64_setcc (CC.NZ)) (x64_setne_m)) ;; nz == ne
(rule (x64_setcc (CC.BE)) (x64_setbe_m))
(rule (x64_setcc (CC.NBE)) (x64_seta_m)) ;; nbe == a
(rule (x64_setcc (CC.S)) (x64_sets_m))
(rule (x64_setcc (CC.NS)) (x64_setns_m))
(rule (x64_setcc (CC.L)) (x64_setl_m))
(rule (x64_setcc (CC.NL)) (x64_setge_m)) ;; nl == ge
(rule (x64_setcc (CC.LE)) (x64_setle_m))
(rule (x64_setcc (CC.NLE)) (x64_setg_m)) ;; nle == g
(rule (x64_setcc (CC.P)) (x64_setp_m))
(rule (x64_setcc (CC.NP)) (x64_setnp_m))
;; Helper for creating `setcc` instructions, when the flags producer will
;; also return a value.
(decl x64_setcc_paired (CC) ConsumesFlags)
(rule (x64_setcc_paired cc) (consumes_flags_with_producer (x64_setcc cc)))
(decl consumes_flags_with_producer (ConsumesFlags) ConsumesFlags)
(rule (consumes_flags_with_producer (ConsumesFlags.ConsumesFlagsReturnsReg flags reg))
(ConsumesFlags.ConsumesFlagsReturnsResultWithProducer flags reg))
;; Helpers for creating vector `add` instructions.
(decl x64_addss (Xmm XmmMem) Xmm)
(rule (x64_addss src1 src2) (x64_addss_a_or_avx src1 src2))
(decl x64_addsd (Xmm XmmMem) Xmm)
(rule (x64_addsd src1 src2) (x64_addsd_a_or_avx src1 src2))
(decl x64_addps (Xmm XmmMem) Xmm)
(rule (x64_addps src1 src2) (x64_addps_a_or_avx src1 src2))
(decl x64_addpd (Xmm XmmMem) Xmm)
(rule (x64_addpd src1 src2) (x64_addpd_a_or_avx src1 src2))
(decl x64_paddb (Xmm XmmMem) Xmm)
(rule (x64_paddb src1 src2) (x64_paddb_a_or_avx src1 src2))
(decl x64_paddw (Xmm XmmMem) Xmm)
(rule (x64_paddw src1 src2) (x64_paddw_a_or_avx src1 src2))
(decl x64_paddd (Xmm XmmMem) Xmm)
(rule (x64_paddd src1 src2) (x64_paddd_a_or_avx src1 src2))
(decl x64_paddq (Xmm XmmMem) Xmm)
(rule (x64_paddq src1 src2) (x64_paddq_a_or_avx src1 src2))
(decl x64_paddsb (Xmm XmmMem) Xmm)
(rule (x64_paddsb src1 src2) (x64_paddsb_a_or_avx src1 src2))
(decl x64_paddsw (Xmm XmmMem) Xmm)
(rule (x64_paddsw src1 src2) (x64_paddsw_a_or_avx src1 src2))
(decl x64_phaddw (Xmm XmmMem) Xmm)
(rule (x64_phaddw src1 src2) (x64_phaddw_a_or_avx src1 src2))
(decl x64_phaddd (Xmm XmmMem) Xmm)
(rule (x64_phaddd src1 src2) (x64_phaddd_a_or_avx src1 src2))
(decl x64_paddusb (Xmm XmmMem) Xmm)
(rule (x64_paddusb src1 src2) (x64_paddusb_a_or_avx src1 src2))
(decl x64_paddusw (Xmm XmmMem) Xmm)
(rule (x64_paddusw src1 src2) (x64_paddusw_a_or_avx src1 src2))
;; Helpers for creating vector `sub` instructions.
(decl x64_subss (Xmm XmmMem) Xmm)
(rule (x64_subss src1 src2) (x64_subss_a_or_avx src1 src2))
(decl x64_subsd (Xmm XmmMem) Xmm)
(rule (x64_subsd src1 src2) (x64_subsd_a_or_avx src1 src2))
(decl x64_subps (Xmm XmmMem) Xmm)
(rule (x64_subps src1 src2) (x64_subps_a_or_avx src1 src2))
(decl x64_subpd (Xmm XmmMem) Xmm)
(rule (x64_subpd src1 src2) (x64_subpd_a_or_avx src1 src2))
(decl x64_psubb (Xmm XmmMem) Xmm)
(rule (x64_psubb src1 src2) (x64_psubb_a_or_avx src1 src2))
(decl x64_psubw (Xmm XmmMem) Xmm)
(rule (x64_psubw src1 src2) (x64_psubw_a_or_avx src1 src2))
(decl x64_psubd (Xmm XmmMem) Xmm)
(rule (x64_psubd src1 src2) (x64_psubd_a_or_avx src1 src2))
(decl x64_psubq (Xmm XmmMem) Xmm)
(rule (x64_psubq src1 src2) (x64_psubq_a_or_avx src1 src2))
(decl x64_psubsb (Xmm XmmMem) Xmm)
(rule (x64_psubsb src1 src2) (x64_psubsb_a_or_avx src1 src2))
(decl x64_psubsw (Xmm XmmMem) Xmm)
(rule (x64_psubsw src1 src2) (x64_psubsw_a_or_avx src1 src2))
(decl x64_psubusb (Xmm XmmMem) Xmm)
(rule (x64_psubusb src1 src2) (x64_psubusb_a_or_avx src1 src2))
(decl x64_psubusw (Xmm XmmMem) Xmm)
(rule (x64_psubusw src1 src2) (x64_psubusw_a_or_avx src1 src2))
;; Helpers for creating `pavg*` instructions.
(decl x64_pavgb (Xmm XmmMem) Xmm)
(rule (x64_pavgb src1 src2) (x64_pavgb_a_or_avx src1 src2))
(decl x64_pavgw (Xmm XmmMem) Xmm)
(rule (x64_pavgw src1 src2) (x64_pavgw_a_or_avx src1 src2))
;; Helpers for creating vector `and` instructions.
(decl x64_pand (Xmm XmmMem) Xmm)
(rule (x64_pand src1 src2) (x64_pand_a_or_avx src1 src2))
(decl x64_andps (Xmm XmmMem) Xmm)
(rule (x64_andps src1 src2) (x64_andps_a_or_avx src1 src2))
(decl x64_andpd (Xmm XmmMem) Xmm)
(rule (x64_andpd src1 src2) (x64_andpd_a_or_avx src1 src2))
;; Helpers for creating vector `or` instructions.
(decl x64_por (Xmm XmmMem) Xmm)
(rule (x64_por src1 src2) (x64_por_a_or_avx src1 src2))
(decl x64_orps (Xmm XmmMem) Xmm)
(rule (x64_orps src1 src2) (x64_orps_a_or_avx src1 src2))
(decl x64_orpd (Xmm XmmMem) Xmm)
(rule (x64_orpd src1 src2) (x64_orpd_a_or_avx src1 src2))
;; Helpers for creating vector `xor` instructions.
(decl x64_pxor (Xmm XmmMem) Xmm)
(rule (x64_pxor src1 src2) (x64_pxor_a_or_avx src1 src2))
(decl x64_xorps (Xmm XmmMem) Xmm)
(rule (x64_xorps src1 src2) (x64_xorps_a_or_avx src1 src2))
(decl x64_xorpd (Xmm XmmMem) Xmm)
(rule (x64_xorpd src1 src2) (x64_xorpd_a_or_avx src1 src2))
;; Helpers for creating vector `andn` instructions.
(decl x64_andnps (Xmm XmmMem) Xmm)
(rule (x64_andnps src1 src2) (x64_andnps_a_or_avx src1 src2))
(decl x64_andnpd (Xmm XmmMem) Xmm)
(rule (x64_andnpd src1 src2) (x64_andnpd_a_or_avx src1 src2))
(decl x64_pandn (Xmm XmmMem) Xmm)
(rule (x64_pandn src1 src2) (x64_pandn_a_or_avx src1 src2))
;; Helper for creating vector `mul` instructions.
(decl x64_mulss (Xmm XmmMem) Xmm)
(rule (x64_mulss src1 src2) (x64_mulss_a_or_avx src1 src2))
(decl x64_mulsd (Xmm XmmMem) Xmm)
(rule (x64_mulsd src1 src2) (x64_mulsd_a_or_avx src1 src2))
(decl x64_mulps (Xmm XmmMem) Xmm)
(rule (x64_mulps src1 src2) (x64_mulps_a_or_avx src1 src2))
(decl x64_mulpd (Xmm XmmMem) Xmm)
(rule (x64_mulpd src1 src2) (x64_mulpd_a_or_avx src1 src2))
(decl x64_pmullw (Xmm XmmMem) Xmm)
(rule (x64_pmullw src1 src2) (x64_pmullw_a_or_avx src1 src2))
(decl x64_pmulld (Xmm XmmMem) Xmm)
(rule (x64_pmulld src1 src2) (x64_pmulld_a_or_avx src1 src2))
(decl x64_pmulhw (Xmm XmmMem) Xmm)
(rule (x64_pmulhw src1 src2) (x64_pmulhw_a_or_avx src1 src2))
(decl x64_pmulhrsw (Xmm XmmMem) Xmm)
(rule (x64_pmulhrsw src1 src2) (x64_pmulhrsw_a_or_avx src1 src2))
(decl x64_pmulhuw (Xmm XmmMem) Xmm)
(rule (x64_pmulhuw src1 src2) (x64_pmulhuw_a_or_avx src1 src2))
(decl x64_pmuldq (Xmm XmmMem) Xmm)
(rule (x64_pmuldq src1 src2) (x64_pmuldq_a_or_avx src1 src2))
(decl x64_pmuludq (Xmm XmmMem) Xmm)
(rule (x64_pmuludq src1 src2) (x64_pmuludq_a_or_avx src1 src2))
;; Helpers for creating vector `div` instructions.
(decl x64_divss (Xmm XmmMem) Xmm)
(rule (x64_divss src1 src2) (x64_divss_a_or_avx src1 src2))
(decl x64_divsd (Xmm XmmMem) Xmm)
(rule (x64_divsd src1 src2) (x64_divsd_a_or_avx src1 src2))
(decl x64_divps (Xmm XmmMem) Xmm)
(rule (x64_divps src1 src2) (x64_divps_a_or_avx src1 src2))
(decl x64_divpd (Xmm XmmMem) Xmm)
(rule (x64_divpd src1 src2) (x64_divpd_a_or_avx src1 src2))
;; Helpers for creating `unpack` instructions.
(decl x64_punpckhwd (Xmm XmmMem) Xmm)
(rule (x64_punpckhwd src1 src2) (x64_punpckhwd_a_or_avx src1 src2))
(decl x64_punpcklwd (Xmm XmmMem) Xmm)
(rule (x64_punpcklwd src1 src2) (x64_punpcklwd_a_or_avx src1 src2))
(decl x64_punpckldq (Xmm XmmMem) Xmm)
(rule (x64_punpckldq src1 src2) (x64_punpckldq_a_or_avx src1 src2))
(decl x64_punpckhdq (Xmm XmmMem) Xmm)
(rule (x64_punpckhdq src1 src2) (x64_punpckhdq_a_or_avx src1 src2))
(decl x64_punpcklqdq (Xmm XmmMem) Xmm)
(rule (x64_punpcklqdq src1 src2) (x64_punpcklqdq_a_or_avx src1 src2))
(decl x64_punpckhqdq (Xmm XmmMem) Xmm)
(rule (x64_punpckhqdq src1 src2) (x64_punpckhqdq_a_or_avx src1 src2))
(decl x64_unpcklps (Xmm XmmMem) Xmm)
(rule (x64_unpcklps src1 src2) (x64_unpcklps_a_or_avx src1 src2))
(decl x64_unpcklpd (Xmm XmmMem) Xmm)
(rule (x64_unpcklpd src1 src2) (x64_unpcklpd_a_or_avx src1 src2))
(decl x64_unpckhps (Xmm XmmMem) Xmm)
(rule (x64_unpckhps src1 src2) (x64_unpckhps_a_or_avx src1 src2))
(decl x64_punpcklbw (Xmm XmmMem) Xmm)
(rule (x64_punpcklbw src1 src2) (x64_punpcklbw_a_or_avx src1 src2))
(decl x64_punpckhbw (Xmm XmmMem) Xmm)
(rule (x64_punpckhbw src1 src2) (x64_punpckhbw_a_or_avx src1 src2))
;; Helper for creating `blendvpd` instructions.
(decl x64_blendvpd (Xmm XmmMem Xmm) Xmm)
(rule 0 (x64_blendvpd src1 src2 mask) (x64_blendvpd_rm0 src1 src2 mask))
(rule 1 (x64_blendvpd src1 src2 mask)
(if-let true (has_avx))
(x64_vblendvpd_rvmr src1 src2 mask))
;; Helper for creating `blendvps` instructions.
(decl x64_blendvps (Xmm XmmMem Xmm) Xmm)
(rule 0 (x64_blendvps src1 src2 mask) (x64_blendvps_rm0 src1 src2 mask))
(rule 1 (x64_blendvps src1 src2 mask)
(if-let true (has_avx))
(x64_vblendvps_rvmr src1 src2 mask))
;; Helper for creating `pblendvb` instructions.
(decl x64_pblendvb (Xmm XmmMem Xmm) Xmm)
(rule 0 (x64_pblendvb src1 src2 mask) (x64_pblendvb_rm src1 src2 mask))
(rule 1 (x64_pblendvb src1 src2 mask)
(if-let true (has_avx))
(x64_vpblendvb_rvmr src1 src2 mask))
;; Helper for creating `pblendw` instructions.
(decl x64_pblendw (Xmm XmmMem u8) Xmm)
(rule (x64_pblendw src1 src2 imm) (x64_pblendw_rmi_or_avx src1 src2 imm))
;; Helper for creating `movsd`/`movss` instructions which create a new vector
;; register where the upper bits are from the first operand and the low
;; bits are from the second operand.
;;
;; Note that the second argument here is specifically `Xmm` instead of `XmmMem`
;; because there is no encoding of a 3-operand form of `movsd` and otherwise
;; when used as a load instruction it wipes out the entire destination register
;; which defeats the purpose of this being a 2-operand instruction.
(decl x64_movsd_regmove (Xmm Xmm) Xmm)
(rule (x64_movsd_regmove src1 src2) (x64_movsd_a_r_or_avx src1 src2))
(decl x64_movss_regmove (Xmm Xmm) Xmm)
(rule (x64_movss_regmove src1 src2) (x64_movss_a_r_or_avx src1 src2))
;; Helper for creating `movlhps` instructions.
(decl x64_movlhps (Xmm Xmm) Xmm)
(rule (x64_movlhps src1 src2) (x64_movlhps_rm_or_avx src1 src2))
;; Helpers for creating `pmaxs*` instructions.
(decl x64_pmaxs (Type Xmm XmmMem) Xmm)
(rule (x64_pmaxs $I8X16 x y) (x64_pmaxsb_a_or_avx x y))
(rule (x64_pmaxs $I16X8 x y) (x64_pmaxsw_a_or_avx x y))
(rule (x64_pmaxs $I32X4 x y) (x64_pmaxsd_a_or_avx x y))
;; No $I64X2 version (PMAXSQ) in SSE4.1.
;; Helpers for creating `pmins*` instructions.
(decl x64_pmins (Type Xmm XmmMem) Xmm)
(rule (x64_pmins $I8X16 x y) (x64_pminsb_a_or_avx x y))
(rule (x64_pmins $I16X8 x y) (x64_pminsw_a_or_avx x y))
(rule (x64_pmins $I32X4 x y) (x64_pminsd_a_or_avx x y))
;; No $I64X2 version (PMINSQ) in SSE4.1.
;; Helpers for creating `pmaxu*` instructions.
(decl x64_pmaxu (Type Xmm XmmMem) Xmm)
(rule (x64_pmaxu $I8X16 x y) (x64_pmaxub_a_or_avx x y))
(rule (x64_pmaxu $I16X8 x y) (x64_pmaxuw_a_or_avx x y))
(rule (x64_pmaxu $I32X4 x y) (x64_pmaxud_a_or_avx x y))
;; No $I64X2 version (PMAXUQ) in SSE4.1.
;; Helper for creating `pminu*` instructions.
(decl x64_pminu (Type Xmm XmmMem) Xmm)
(rule (x64_pminu $I8X16 x y) (x64_pminub_a_or_avx x y))
(rule (x64_pminu $I16X8 x y) (x64_pminuw_a_or_avx x y))
(rule (x64_pminu $I32X4 x y) (x64_pminud_a_or_avx x y))
;; No $I64X2 version (PMINUQ) in SSE4.1.
;; Helper for creating `packsswb` instructions.
(decl x64_packsswb (Xmm XmmMem) Xmm)
(rule (x64_packsswb src1 src2) (x64_packsswb_a_or_avx src1 src2))
;; Helper for creating `packssdw` instructions.
(decl x64_packssdw (Xmm XmmMem) Xmm)
(rule (x64_packssdw src1 src2) (x64_packssdw_a_or_avx src1 src2))
;; Helper for creating `packuswb` instructions.
(decl x64_packuswb (Xmm XmmMem) Xmm)
(rule (x64_packuswb src1 src2) (x64_packuswb_a_or_avx src1 src2))
;; Helper for creating `packusdw` instructions.
(decl x64_packusdw (Xmm XmmMem) Xmm)
(rule (x64_packusdw src1 src2) (x64_packusdw_a_or_avx src1 src2))
;; Helper for creating `palignr` instructions.
(decl x64_palignr (Xmm XmmMem u8) Xmm)
(rule (x64_palignr src1 src2 imm) (x64_palignr_a_or_avx src1 src2 imm))
;; Helpers for creating `cmpp*` instructions.
(decl x64_cmpp (Type Xmm XmmMem FcmpImm) Xmm)
(rule (x64_cmpp $F32X4 x y imm) (x64_cmpps x y imm))
(rule (x64_cmpp $F64X2 x y imm) (x64_cmppd x y imm))
(decl x64_cmpps (Xmm XmmMem FcmpImm) Xmm)
(rule 1 (x64_cmpps src1 src2 imm)
(if-let true (has_avx))
(x64_vcmpps_b src1 src2 (encode_fcmp_imm imm)))
(rule 0 (x64_cmpps src1 src2 imm) (x64_cmpps_a src1 src2 (encode_fcmp_imm imm)))
;; Note that `Size32` is intentional despite this being used for 64-bit
;; operations, since this presumably induces the correct encoding of the
;; instruction.
(decl x64_cmppd (Xmm XmmMem FcmpImm) Xmm)
(rule 1 (x64_cmppd src1 src2 imm)
(if-let true (has_avx))
(x64_vcmppd_b src1 src2 (encode_fcmp_imm imm)))
(rule 0 (x64_cmppd src1 src2 imm) (x64_cmppd_a src1 src2 (encode_fcmp_imm imm)))
;; Helper for creating `pinsrb` instructions.
(decl x64_pinsrb (Xmm GprMem u8) Xmm)
(rule 1 (x64_pinsrb src1 src2 lane)
(if-let true (has_avx))
(x64_vpinsrb_b src1 src2 lane))
(rule 0 (x64_pinsrb src1 src2 lane) (x64_pinsrb_a src1 src2 lane))
;; Helper for creating `pinsrw` instructions.
(decl x64_pinsrw (Xmm GprMem u8) Xmm)
(rule 1 (x64_pinsrw src1 src2 lane)
(if-let true (has_avx))
(x64_vpinsrw_b src1 src2 lane))
(rule 0 (x64_pinsrw src1 src2 lane) (x64_pinsrw_a src1 src2 lane))
;; Helper for creating `pinsrd` instructions.
(decl x64_pinsrd (Xmm GprMem u8) Xmm)
(rule 1 (x64_pinsrd src1 src2 lane)
(if-let true (has_avx))
(x64_vpinsrd_b src1 src2 lane))
(rule 0 (x64_pinsrd src1 src2 lane) (x64_pinsrd_a src1 src2 lane))
;; Helper for creating `pinsrq` instructions.
(decl x64_pinsrq (Xmm GprMem u8) Xmm)
(rule 1 (x64_pinsrq src1 src2 lane)
(if-let true (has_avx))
(x64_vpinsrq_b src1 src2 lane))
(rule 0 (x64_pinsrq src1 src2 lane) (x64_pinsrq_a src1 src2 lane))
;; Helper for creating `roundss` instructions.
(decl x64_roundss (XmmMem RoundImm) Xmm)
(rule 1 (x64_roundss src1 round)
(if-let true (has_avx))
(x64_vroundss_rvmi (xmm_zero $F32X4) src1 (encode_round_imm round)))
(rule 0 (x64_roundss src1 round)
(x64_roundss_rmi src1 (encode_round_imm round)))
;; Helper for creating `roundsd` instructions.
(decl x64_roundsd (XmmMem RoundImm) Xmm)
(rule 1 (x64_roundsd src1 round)
(if-let true (has_avx))
(x64_vroundsd_rvmi (xmm_zero $F64X2) src1 (encode_round_imm round)))
(rule 0 (x64_roundsd src1 round)
(x64_roundsd_rmi src1 (encode_round_imm round)))
;; Helper for creating `roundps` instructions.
(decl x64_roundps (XmmMem RoundImm) Xmm)
(rule 1 (x64_roundps src1 round)
(if-let true (has_avx))
(x64_vroundps_rmi src1 (encode_round_imm round)))
(rule (x64_roundps src1 round)
(x64_roundps_rmi src1 (encode_round_imm round)))
;; Helper for creating `roundpd` instructions.
(decl x64_roundpd (XmmMem RoundImm) Xmm)
(rule 1 (x64_roundpd src1 round)
(if-let true (has_avx))
(x64_vroundpd_rmi src1 (encode_round_imm round)))
(rule 0 (x64_roundpd src1 round)
(x64_roundpd_rmi src1 (encode_round_imm round)))
;; Helper for creating `pmaddwd` instructions.
(decl x64_pmaddwd (Xmm XmmMem) Xmm)
(rule 0 (x64_pmaddwd src1 src2) (x64_pmaddwd_a_or_avx src1 src2))
(decl x64_pmaddubsw (Xmm XmmMem) Xmm)
(rule (x64_pmaddubsw src1 src2) (x64_pmaddubsw_a_or_avx src1 src2))
;; Helper for creating `insertps` instructions.
(decl x64_insertps (Xmm XmmMem u8) Xmm)
(rule 0 (x64_insertps src1 src2 lane) (x64_insertps_a_or_avx src1 src2 lane))
;; Helper for creating `pshufd` instructions.
(decl x64_pshufd (XmmMem u8) Xmm)
(rule (x64_pshufd src imm) (x64_pshufd_a src imm))
(rule 1 (x64_pshufd src imm)
(if-let true (has_avx))
(x64_vpshufd_a src imm))
;; Helper for creating `pshufb` instructions.
(decl x64_pshufb (Xmm XmmMem) Xmm)
(rule (x64_pshufb src1 src2) (x64_pshufb_a_or_avx src1 src2))
;; Helper for creating `shufpd` instructions.
(decl x64_shufpd (Xmm XmmMem u8) Xmm)
(rule (x64_shufpd src1 src2 byte) (x64_shufpd_a_or_avx src1 src2 byte))
;; Helper for creating `shufps` instructions.
(decl x64_shufps (Xmm XmmMem u8) Xmm)
(rule (x64_shufps src1 src2 byte) (x64_shufps_a_or_avx src1 src2 byte))
;; Helper for creating `pshuflw` instructions.
(decl x64_pshuflw (XmmMem u8) Xmm)
(rule (x64_pshuflw src imm) (x64_pshuflw_a src imm))
(rule 1 (x64_pshuflw src imm)
(if-let true (has_avx))
(x64_vpshuflw_a src imm))
;; Helper for creating `pshufhw` instructions.
(decl x64_pshufhw (XmmMem u8) Xmm)
(rule (x64_pshufhw src imm) (x64_pshufhw_a src imm))
(rule 1 (x64_pshufhw src imm)
(if-let true (has_avx))
(x64_vpshufhw_a src imm))
;; Helper for creating `vcvtudq2ps` instructions.
(decl x64_vcvtudq2ps (XmmMem) Xmm)
(rule (x64_vcvtudq2ps src) (x64_vcvtudq2ps_a src))
;; Helper for creating `vpabsq` instructions.
(decl x64_vpabsq (XmmMem) Xmm)
(rule (x64_vpabsq src) (x64_vpabsq_c src))
;; Helper for creating `vpopcntb` instructions.
(decl x64_vpopcntb (XmmMem) Xmm)
(rule (x64_vpopcntb src) (x64_vpopcntb_a src))
;; Helper for creating `vpmullq` instructions.
;;
;; Requires AVX-512 vl and dq.
(decl x64_vpmullq (Xmm XmmMem) Xmm)
(rule (x64_vpmullq src1 src2) (x64_vpmullq_c src1 src2))
;; Helper for creating `vpermi2b` instructions.
;;
;; Requires AVX-512 vl and vbmi extensions.
(decl x64_vpermi2b (Xmm Xmm XmmMem) Xmm)
(rule (x64_vpermi2b src1 src2 src3) (x64_vpermi2b_a src1 src2 src3))
;; Helpers for creating vector `shift` instructions.
(decl x64_psllw (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psllw src1 (is_xmm_mem src2)) (x64_psllw_a_or_avx src1 src2))
(rule 0 (x64_psllw src1 (is_imm8_xmm src2)) (x64_psllw_b_or_avx src1 src2))
(decl x64_pslld (Xmm XmmMemImm) Xmm)
(rule 1 (x64_pslld src1 (is_xmm_mem src2)) (x64_pslld_a_or_avx src1 src2))
(rule 0 (x64_pslld src1 (is_imm8_xmm src2)) (x64_pslld_b_or_avx src1 src2))
(decl x64_psllq (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psllq src1 (is_xmm_mem src2)) (x64_psllq_a_or_avx src1 src2))
(rule 0 (x64_psllq src1 (is_imm8_xmm src2)) (x64_psllq_b_or_avx src1 src2))
(decl x64_psrlw (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psrlw src1 (is_xmm_mem src2)) (x64_psrlw_a_or_avx src1 src2))
(rule 0 (x64_psrlw src1 (is_imm8_xmm src2)) (x64_psrlw_b_or_avx src1 src2))
(decl x64_psrld (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psrld src1 (is_xmm_mem src2)) (x64_psrld_a_or_avx src1 src2))
(rule 0 (x64_psrld src1 (is_imm8_xmm src2)) (x64_psrld_b_or_avx src1 src2))
(decl x64_psrlq (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psrlq src1 (is_xmm_mem src2)) (x64_psrlq_a_or_avx src1 src2))
(rule 0 (x64_psrlq src1 (is_imm8_xmm src2)) (x64_psrlq_b_or_avx src1 src2))
(decl x64_psraw (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psraw src1 (is_xmm_mem src2)) (x64_psraw_a_or_avx src1 src2))
(rule 0 (x64_psraw src1 (is_imm8_xmm src2)) (x64_psraw_b_or_avx src1 src2))
(decl x64_psrad (Xmm XmmMemImm) Xmm)
(rule 1 (x64_psrad src1 (is_xmm_mem src2)) (x64_psrad_a_or_avx src1 src2))
(rule 0 (x64_psrad src1 (is_imm8_xmm src2)) (x64_psrad_b_or_avx src1 src2))
;; Helper for creating `vpsraq` instructions.
(decl x64_vpsraq (Xmm XmmMem) Xmm)
(rule (x64_vpsraq src1 src2) (x64_vpsraq_g src1 src2))
;; Helper for creating `vpsraq` instructions.
(decl x64_vpsraq_imm (XmmMem u8) Xmm)
(rule (x64_vpsraq_imm src imm) (x64_vpsraq_f src imm))
;; Helper for creating `pextr*` instructions.
(decl x64_pextrb (Xmm u8) Gpr)
(rule (x64_pextrb src lane) (x64_pextrb_a_or_avx src lane))
(decl x64_pextrb_store (SyntheticAmode Xmm u8) SideEffectNoResult)
(rule (x64_pextrb_store addr src lane) (x64_pextrb_a_mem_or_avx addr src lane))
(decl x64_pextrw (Xmm u8) Gpr)
(rule (x64_pextrw src lane) (x64_pextrw_a_or_avx src lane))
(decl x64_pextrw_store (SyntheticAmode Xmm u8) SideEffectNoResult)
(rule (x64_pextrw_store addr src lane) (x64_pextrw_b_mem_or_avx addr src lane))
(decl x64_pextrd (Xmm u8) Gpr)
(rule (x64_pextrd src lane) (x64_pextrd_a_or_avx src lane))
(decl x64_pextrd_store (SyntheticAmode Xmm u8) SideEffectNoResult)
(rule (x64_pextrd_store addr src lane) (x64_pextrd_a_mem_or_avx addr src lane))
(decl x64_pextrq (Xmm u8) Gpr)
(rule (x64_pextrq src lane) (x64_pextrq_a_or_avx src lane))
(decl x64_pextrq_store (SyntheticAmode Xmm u8) SideEffectNoResult)
(rule (x64_pextrq_store addr src lane) (x64_pextrq_a_mem_or_avx addr src lane))
;; Helper for creating `pmovmskb` instructions.
(decl x64_pmovmskb (Xmm) Gpr)
(rule (x64_pmovmskb src) (x64_pmovmskb_rm src))
(rule 1 (x64_pmovmskb src)
(if-let true (has_avx))
(x64_vpmovmskb_rm src))
;; Helper for creating `movmskps` instructions.
(decl x64_movmskps (Xmm) Gpr)
(rule (x64_movmskps src) (x64_movmskps_rm src))
(rule 1 (x64_movmskps src)
(if-let true (has_avx))
(x64_vmovmskps_rm src))
;; Helper for creating `movmskpd` instructions.
(decl x64_movmskpd (Xmm) Gpr)
(rule (x64_movmskpd src) (x64_movmskpd_rm src))
(rule 1 (x64_movmskpd src)
(if-let true (has_avx))
(x64_vmovmskpd_rm src))
;; Helper for creating `not` instructions.
(decl x64_not (Type Gpr) Gpr)
(rule (x64_not $I8 src) (x64_notb_m src))
(rule (x64_not $I16 src) (x64_notw_m src))
(rule (x64_not $I32 src) (x64_notl_m src))
(rule (x64_not $I64 src) (x64_notq_m src))
;; Helpers for creating `neg` instructions.
(decl x64_neg_raw (Type Gpr) AssemblerOutputs)
(rule (x64_neg_raw $I8 src) (x64_negb_m_raw src))
(rule (x64_neg_raw $I16 src) (x64_negw_m_raw src))
(rule (x64_neg_raw $I32 src) (x64_negl_m_raw src))
(rule (x64_neg_raw $I64 src) (x64_negq_m_raw src))
(decl x64_neg (Type Gpr) Gpr)
(rule (x64_neg ty src)
(emit_ret_gpr (x64_neg_raw ty src)))
(decl x64_neg_paired (Type Gpr) ProducesFlags)
(rule (x64_neg_paired ty src)
(asm_produce_flags (x64_neg_raw ty src)))
(spec (x64_lea ty amode)
(provide (= result amode))
(require (or (= ty 32) (= ty 64))))
(decl x64_lea (Type SyntheticAmode) Gpr)
(rule (x64_lea $I16 addr) (x64_leaw_rm addr))
(rule (x64_lea $I32 addr) (x64_leal_rm addr))
(rule (x64_lea $I64 addr) (x64_leaq_rm addr))
;; Helper for creating `lzcnt` instructions.
(decl x64_lzcnt (Type GprMem) Gpr)
(rule (x64_lzcnt $I16 src) (x64_lzcntw_rm src))
(rule (x64_lzcnt $I32 src) (x64_lzcntl_rm src))
(rule (x64_lzcnt $I64 src) (x64_lzcntq_rm src))
;; Helper for creating `tzcnt` instructions.
(decl x64_tzcnt (Type GprMem) Gpr)
(rule (x64_tzcnt $I16 src) (x64_tzcntw_a src))
(rule (x64_tzcnt $I32 src) (x64_tzcntl_a src))
(rule (x64_tzcnt $I64 src) (x64_tzcntq_a src))
;; Helper for creating `bsr` instructions.
(decl x64_bsr (Type GprMem) ProducesFlags)
(rule (x64_bsr $I16 src) (asm_produce_flags (x64_bsrw_rm_raw src)))
(rule (x64_bsr $I32 src) (asm_produce_flags (x64_bsrl_rm_raw src)))
(rule (x64_bsr $I64 src) (asm_produce_flags (x64_bsrq_rm_raw src)))
;; Helper for creating `bsr + cmov` instruction pairs that produce the
;; result of the `bsr`, or `alt` if the input was zero.
(decl bsr_or_else (Type Gpr Gpr) Gpr)
(rule (bsr_or_else ty src alt)
(let ((bsr ProducesFlags (x64_bsr ty src))
;; Manually extract the result from the bsr, then ignore
;; it below, since we need to thread it into the cmove
;; before we pass the cmove to with_flags_reg.
(bsr_result Gpr (produces_flags_get_reg bsr))
(cmove ConsumesFlags (cmove ty (CC.Z) alt bsr_result)))
(with_flags_reg (produces_flags_ignore bsr) cmove)))
;; Helper for creating `bsf` instructions.
(decl x64_bsf (Type GprMem) ProducesFlags)
(rule (x64_bsf $I16 src) (asm_produce_flags (x64_bsfw_rm_raw src)))
(rule (x64_bsf $I32 src) (asm_produce_flags (x64_bsfl_rm_raw src)))
(rule (x64_bsf $I64 src) (asm_produce_flags (x64_bsfq_rm_raw src)))
;; Helper for creating `bsf + cmov` instruction pairs that produce the
;; result of the `bsf`, or `alt` if the input was zero.
(decl bsf_or_else (Type Gpr Gpr) Gpr)
(rule (bsf_or_else ty src alt)
(let ((bsf ProducesFlags (x64_bsf ty src))
;; Manually extract the result from the bsf, then ignore
;; it below, since we need to thread it into the cmove
;; before we pass the cmove to with_flags_reg.
(bsf_result Gpr (produces_flags_get_reg bsf))
(cmove ConsumesFlags (cmove ty (CC.Z) alt bsf_result)))
(with_flags_reg (produces_flags_ignore bsf) cmove)))
;; Helper for creating `blsi` instructions.
(decl x64_blsi (Type GprMem) Gpr)
(rule (x64_blsi $I32 src) (x64_blsil_vm src))
(rule (x64_blsi $I64 src) (x64_blsiq_vm src))
;; Helper for creating `blsmsk` instructions.
(decl x64_blsmsk (Type GprMem) Gpr)
(rule (x64_blsmsk $I32 src) (x64_blsmskl_vm src))
(rule (x64_blsmsk $I64 src) (x64_blsmskq_vm src))
;; Helper for creating `blsr` instructions.
(decl x64_blsr (Type GprMem) Gpr)
(rule (x64_blsr $I32 src) (x64_blsrl_vm src))
(rule (x64_blsr $I64 src) (x64_blsrq_vm src))
;; Helper for creating `bt` instructions.
(decl x64_bt (Type GprMem Gpr) ProducesFlags)
(rule (x64_bt $I16 src1 src2) (x64_btw_mr src1 src2))
(rule (x64_bt $I32 src1 src2) (x64_btl_mr src1 src2))
(rule (x64_bt $I64 src1 src2) (x64_btq_mr src1 src2))
;; Helper for creating `bt` instructions.
(decl x64_bt_imm (Type GprMem u8) ProducesFlags)
(rule (x64_bt_imm $I16 src imm) (x64_btw_mi src imm))
(rule (x64_bt_imm $I32 src imm) (x64_btl_mi src imm))
(rule (x64_bt_imm $I64 src imm) (x64_btq_mi src imm))
;; Helper for creating `sarx` instructions.
(decl x64_sarx (Type GprMem Gpr) Gpr)
(rule (x64_sarx $I32 val amt) (x64_sarxl_rmv val amt))
(rule (x64_sarx $I64 val amt) (x64_sarxq_rmv val amt))
;; Helper for creating `shrx` instructions.
(decl x64_shrx (Type GprMem Gpr) Gpr)
(rule (x64_shrx $I32 val amt) (x64_shrxl_rmv val amt))
(rule (x64_shrx $I64 val amt) (x64_shrxq_rmv val amt))
;; Helper for creating `shlx` instructions.
(decl x64_shlx (Type GprMem Gpr) Gpr)
(rule (x64_shlx $I32 val amt) (x64_shlxl_rmv val amt))
(rule (x64_shlx $I64 val amt) (x64_shlxq_rmv val amt))
;; Helper for creating `rorx` instructions.
(decl x64_rorx (Type GprMem u8) Gpr)
(rule (x64_rorx $I32 src imm) (x64_rorxl_rmi src imm))
(rule (x64_rorx $I64 src imm) (x64_rorxq_rmi src imm))
;; Helper for creating `popcnt` instructions.
(decl x64_popcnt (Type GprMem) Gpr)
(rule (x64_popcnt $I16 src) (x64_popcntw_rm src))
(rule (x64_popcnt $I32 src) (x64_popcntl_rm src))
(rule (x64_popcnt $I64 src) (x64_popcntq_rm src))
;; Helpers for creating `min*` instructions.
(decl x64_minss (Xmm XmmMem) Xmm)
(rule (x64_minss src1 src2) (x64_minss_a_or_avx src1 src2))
(decl x64_minsd (Xmm XmmMem) Xmm)
(rule (x64_minsd src1 src2) (x64_minsd_a_or_avx src1 src2))
(decl x64_minps (Xmm XmmMem) Xmm)
(rule (x64_minps src1 src2) (x64_minps_a_or_avx src1 src2))
(decl x64_minpd (Xmm XmmMem) Xmm)
(rule (x64_minpd src1 src2) (x64_minpd_a_or_avx src1 src2))
(decl x64_maxss (Xmm XmmMem) Xmm)
(rule (x64_maxss src1 src2) (x64_maxss_a_or_avx src1 src2))
(decl x64_maxsd (Xmm XmmMem) Xmm)
(rule (x64_maxsd src1 src2) (x64_maxsd_a_or_avx src1 src2))
(decl x64_maxps (Xmm XmmMem) Xmm)
(rule (x64_maxps src1 src2) (x64_maxps_a_or_avx src1 src2))
(decl x64_maxpd (Xmm XmmMem) Xmm)
(rule (x64_maxpd src1 src2) (x64_maxpd_a_or_avx src1 src2))
;; Helper for creating `vfmadd213*` instructions
(decl x64_vfmadd213 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfmadd213 $F32 a b c) (x64_vfmadd213ss_a a b c))
(rule (x64_vfmadd213 $F64 a b c) (x64_vfmadd213sd_a a b c))
(rule (x64_vfmadd213 $F32X4 a b c) (x64_vfmadd213ps_a a b c))
(rule (x64_vfmadd213 $F64X2 a b c) (x64_vfmadd213pd_a a b c))
;; Helper for creating `vfmadd132*` instructions
(decl x64_vfmadd132 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfmadd132 $F32 a b c) (x64_vfmadd132ss_a a b c))
(rule (x64_vfmadd132 $F64 a b c) (x64_vfmadd132sd_a a b c))
(rule (x64_vfmadd132 $F32X4 a b c) (x64_vfmadd132ps_a a b c))
(rule (x64_vfmadd132 $F64X2 a b c) (x64_vfmadd132pd_a a b c))
;; Helper for creating `vfnmadd213*` instructions
(decl x64_vfnmadd213 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfnmadd213 $F32 a b c) (x64_vfnmadd213ss_a a b c))
(rule (x64_vfnmadd213 $F64 a b c) (x64_vfnmadd213sd_a a b c))
(rule (x64_vfnmadd213 $F32X4 a b c) (x64_vfnmadd213ps_a a b c))
(rule (x64_vfnmadd213 $F64X2 a b c) (x64_vfnmadd213pd_a a b c))
;; Helper for creating `vfnmadd132*` instructions
(decl x64_vfnmadd132 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfnmadd132 $F32 a b c) (x64_vfnmadd132ss_a a b c))
(rule (x64_vfnmadd132 $F64 a b c) (x64_vfnmadd132sd_a a b c))
(rule (x64_vfnmadd132 $F32X4 a b c) (x64_vfnmadd132ps_a a b c))
(rule (x64_vfnmadd132 $F64X2 a b c) (x64_vfnmadd132pd_a a b c))
;; Helper for creating `vfmsub213*` instructions
(decl x64_vfmsub213 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfmsub213 $F32 a b c) (x64_vfmsub213ss_a a b c))
(rule (x64_vfmsub213 $F64 a b c) (x64_vfmsub213sd_a a b c))
(rule (x64_vfmsub213 $F32X4 a b c) (x64_vfmsub213ps_a a b c))
(rule (x64_vfmsub213 $F64X2 a b c) (x64_vfmsub213pd_a a b c))
;; Helper for creating `vfmsub132*` instructions
(decl x64_vfmsub132 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfmsub132 $F32 a b c) (x64_vfmsub132ss_a a b c))
(rule (x64_vfmsub132 $F64 a b c) (x64_vfmsub132sd_a a b c))
(rule (x64_vfmsub132 $F32X4 a b c) (x64_vfmsub132ps_a a b c))
(rule (x64_vfmsub132 $F64X2 a b c) (x64_vfmsub132pd_a a b c))
;; Helper for creating `vfnmsub213*` instructions
(decl x64_vfnmsub213 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfnmsub213 $F32 a b c) (x64_vfnmsub213ss_a a b c))
(rule (x64_vfnmsub213 $F64 a b c) (x64_vfnmsub213sd_a a b c))
(rule (x64_vfnmsub213 $F32X4 a b c) (x64_vfnmsub213ps_a a b c))
(rule (x64_vfnmsub213 $F64X2 a b c) (x64_vfnmsub213pd_a a b c))
;; Helper for creating `vfnmsub132*` instructions
(decl x64_vfnmsub132 (Type Xmm Xmm XmmMem) Xmm)
(rule (x64_vfnmsub132 $F32 a b c) (x64_vfnmsub132ss_a a b c))
(rule (x64_vfnmsub132 $F64 a b c) (x64_vfnmsub132sd_a a b c))
(rule (x64_vfnmsub132 $F32X4 a b c) (x64_vfnmsub132ps_a a b c))
(rule (x64_vfnmsub132 $F64X2 a b c) (x64_vfnmsub132pd_a a b c))
;; Note, the `vfmsub231` and `vfnmsub231*` instructions are omitted, because
;; instruction selection happens before register allocation and therefore there
;; is no benefit to a a third permutation
;; Helper for creating `sqrtss` instructions.
;;
;; NB: the square-root operation technically only has one operand but this
;; instruction has two. This is to reflect how the square root operation copies
;; the upper bits of the first register and only performs the square root
;; operation on the low bits of the second register. This introduces
;; a data-dependency on the contents of the first register which is modeled
;; here.
(decl x64_sqrtss (Xmm XmmMem) Xmm)
(rule (x64_sqrtss x y) (x64_sqrtss_a_or_avx x y))
;; Helper for creating `sqrtsd` instructions.
;;
;; NB: see `x64_sqrtss` for explanation of why this has two args.
(decl x64_sqrtsd (Xmm XmmMem) Xmm)
(rule 0 (x64_sqrtsd x y) (x64_sqrtsd_a_or_avx x y))
;; Helper for creating `sqrtps` instructions.
(decl x64_sqrtps (XmmMem) Xmm)
(rule (x64_sqrtps x) (x64_sqrtps_a_or_avx x))
;; Helper for creating `sqrtpd` instructions.
(decl x64_sqrtpd (XmmMem) Xmm)
(rule (x64_sqrtpd x) (x64_sqrtpd_a_or_avx x))
;; Helper for creating `reciprocal` instructions.
;;
;; Helper for creating `rcpps` instructions.
(decl x64_rcpps (XmmMem) Xmm)
(rule (x64_rcpps x) (x64_rcpps_rm_or_avx x))
;; Helper for creating `rcpss` instructions.
(decl x64_rcpss (XmmMem) Xmm)
(rule (x64_rcpss x) (x64_rcpss_rm x))
;; Helper for creating `vrsqrtss` instructions.
(decl x64_vrcpss (Xmm XmmMem) Xmm)
(rule (x64_vrcpss x y) (x64_vrcpss_rvm x y))
;; Helper for creating `rsqrtps` instructions.
(decl x64_rsqrtps (XmmMem) Xmm)
(rule (x64_rsqrtps x) (x64_rsqrtps_rm_or_avx x))
;; Helper for creating `rsqrtss` instructions.
(decl x64_rsqrtss (XmmMem) Xmm)
(rule (x64_rsqrtss x) (x64_rsqrtss_rm x))
;; Helper for creating `vrsqrtss` instructions.
(decl x64_vrsqrtss (Xmm XmmMem) Xmm)
(rule (x64_vrsqrtss x y) (x64_vrsqrtss_rvm x y))
;; Helper for creating `cvtss2sd` instructions.
;;
;; NB: see `x64_sqrtss` for why this has two args (same reasoning, different op)
(decl x64_cvtss2sd (Xmm XmmMem) Xmm)
(rule 1 (x64_cvtss2sd x y)
(if-let true (has_avx))
(x64_vcvtss2sd_b x y))
(rule 0 (x64_cvtss2sd x y) (x64_cvtss2sd_a x y))
;; Helper for creating `cvtsd2ss` instructions.
;;
;; NB: see `x64_sqrtss` for why this has two args (same reasoning, different op)
(decl x64_cvtsd2ss (Xmm XmmMem) Xmm)
(rule 1 (x64_cvtsd2ss x y)
(if-let true (has_avx))
(x64_vcvtsd2ss_b x y))
(rule 0 (x64_cvtsd2ss x y) (x64_cvtsd2ss_a x y))
;; Helper for creating `cvtdq2ps` instructions.
(decl x64_cvtdq2ps (XmmMem) Xmm)
(rule 1 (x64_cvtdq2ps x)
(if-let true (has_avx))
(x64_vcvtdq2ps_a x))
(rule (x64_cvtdq2ps x) (x64_cvtdq2ps_a x))
;; Helper for creating `cvtps2pd` instructions.
(decl x64_cvtps2pd (XmmMem) Xmm)
(rule 1 (x64_cvtps2pd x)
(if-let true (has_avx))
(x64_vcvtps2pd_a x))
(rule 0 (x64_cvtps2pd x) (x64_cvtps2pd_a x))
;; Helper for creating `cvtpd2ps` instructions.
(decl x64_cvtpd2ps (XmmMem) Xmm)
(rule 1 (x64_cvtpd2ps x)
(if-let true (has_avx))
(x64_vcvtpd2ps_a x))
(rule 0 (x64_cvtpd2ps x) (x64_cvtpd2ps_a x))
;; Helper for creating `cvtdq2pd` instructions.
(decl x64_cvtdq2pd (XmmMem) Xmm)
(rule 1 (x64_cvtdq2pd x)
(if-let true (has_avx))
(x64_vcvtdq2pd_a x))
(rule 0 (x64_cvtdq2pd x) (x64_cvtdq2pd_a x))
;; Helper for creating `cvtsi2ss` instructions.
(decl x64_cvtsi2ss (Type Xmm GprMem) Xmm)
(rule 1 (x64_cvtsi2ss $I32 x y)
(if-let true (has_avx))
(x64_vcvtsi2ssl_b x y))
(rule 1 (x64_cvtsi2ss $I64 x y)
(if-let true (has_avx))
(x64_vcvtsi2ssq_b x y))
(rule 0 (x64_cvtsi2ss $I32 x y) (x64_cvtsi2ssl_a x y))
(rule 0 (x64_cvtsi2ss $I64 x y) (x64_cvtsi2ssq_a x y))
;; Helper for creating `cvtsi2sd` instructions.
(decl x64_cvtsi2sd (Type Xmm GprMem) Xmm)
(rule 1 (x64_cvtsi2sd $I32 x y)
(if-let true (has_avx))
(x64_vcvtsi2sdl_b x y))
(rule 1 (x64_cvtsi2sd $I64 x y)
(if-let true (has_avx))
(x64_vcvtsi2sdq_b x y))
(rule 0 (x64_cvtsi2sd $I32 x y) (x64_cvtsi2sdl_a x y))
(rule 0 (x64_cvtsi2sd $I64 x y) (x64_cvtsi2sdq_a x y))
;; Helper for creating `cvttps2dq` instructions.
(decl x64_cvttps2dq (XmmMem) Xmm)
(rule 1 (x64_cvttps2dq x)
(if-let true (has_avx))
(x64_vcvttps2dq_a x))
(rule 0 (x64_cvttps2dq x) (x64_cvttps2dq_a x))
;; Helper for creating `cvttpd2dq` instructions.
(decl x64_cvttpd2dq (XmmMem) Xmm)
(rule 1 (x64_cvttpd2dq x)
(if-let true (has_avx))
(x64_vcvttpd2dq_a x))
(rule 0 (x64_cvttpd2dq x) (x64_cvttpd2dq_a x))
;; Helpers for creating `pcmpeq*` instructions.
(decl x64_pcmpeq (Type Xmm XmmMem) Xmm)
(rule (x64_pcmpeq $I8X16 x y) (x64_pcmpeqb x y))
(rule (x64_pcmpeq $I16X8 x y) (x64_pcmpeqw x y))
(rule (x64_pcmpeq $I32X4 x y) (x64_pcmpeqd x y))
(rule (x64_pcmpeq $I64X2 x y)
(if-let true (has_sse41))
(x64_pcmpeqq x y))
;; Without SSE 4.1 there's no access to `pcmpeqq`, so it's emulated by comparing
;; 32-bit lanes instead. The upper and lower halves of the 32-bit comparison are
;; swapped and then these two results are and'd together. This way only if both
;; 32-bit values were equal is the result all ones, otherwise the result is
;; all zeros if either 32-bit comparison was zero.
(rule -1 (x64_pcmpeq $I64X2 x y)
(let ((cmp32 Xmm (x64_pcmpeqd x y))
(cmp32_swapped Xmm (x64_pshufd cmp32 0b10_11_00_01)))
(x64_pand cmp32 cmp32_swapped)))
;; Helpers for creating `pcmpeq*` instructions.
(decl x64_pcmpeqb (Xmm XmmMem) Xmm)
(rule (x64_pcmpeqb x y) (x64_pcmpeqb_a_or_avx x y))
(decl x64_pcmpeqw (Xmm XmmMem) Xmm)
(rule (x64_pcmpeqw x y) (x64_pcmpeqw_a_or_avx x y))
(decl x64_pcmpeqd (Xmm XmmMem) Xmm)
(rule (x64_pcmpeqd x y) (x64_pcmpeqd_a_or_avx x y))
(decl x64_pcmpeqq (Xmm XmmMem) Xmm)
(rule (x64_pcmpeqq x y) (x64_pcmpeqq_a_or_avx x y))
;; Helpers for creating `pcmpgt*` instructions.
(decl x64_pcmpgt (Type Xmm XmmMem) Xmm)
(rule (x64_pcmpgt $I8X16 x y) (x64_pcmpgtb_a_or_avx x y))
(rule (x64_pcmpgt $I16X8 x y) (x64_pcmpgtw_a_or_avx x y))
(rule (x64_pcmpgt $I32X4 x y) (x64_pcmpgtd_a_or_avx x y))
;; AVX has a single-instruction lowering; we do not use the `or_avx` suffix so
;; we can match a non-AVX/SSE4.2 below.
(rule 2 (x64_pcmpgt $I64X2 x y)
(if-let true (has_avx))
(x64_vpcmpgtq_b x y))
;; SSE4.2 also gives a single-instruction for this lowering, but prior to that
;; it's a bit more complicated.
(rule 1 (x64_pcmpgt $I64X2 x y)
(if-let true (use_sse42))
(x64_pcmpgtq_a x y))
;; Without SSE4.2 a 64-bit comparison is expanded to a number of instructions.
;; The basic idea is to delegate to a 32-bit comparison and work with the
;; results from there. The comparison to execute is:
;;
;; [ xhi ][ xlo ] > [ yhi ][ ylo ]
;;
;; If xhi != yhi, then the result is whatever the result of that comparison is.
;; If xhi == yhi, then the result is the unsigned comparison of xlo/ylo since
;; the 64-bit value is positive. To achieve this as part of the same comparison
;; the upper bit of `xlo` and `ylo` is flipped to change the sign when compared
;; as a 32-bit signed number. The result here is then:
;;
;; * if xlo and yhi had the same upper bit, then the unsigned comparison should
;; be the same as comparing the flipped versions as signed.
;; * if xlo had an upper bit of 0 and ylo had an upper bit of 1, then xlo > ylo
;; is false. When flipping the bits xlo becomes negative and ylo becomes
;; positive when compared as 32-bits, so the result is the same.
;; * if xlo had an upper bit of 1 and ylo had an upper bit of 0, then xlo > ylo
;; is true. When flipping the bits xlo becomes positive and ylo becomes
;; negative when compared as 32-bits, so the result is the same.
;;
;; Given all that the sequence here is to flip the upper bits of xlo and ylo,
;; then compare the masked results for equality and for gt. If the upper 32-bits
;; are not equal then the gt result for the upper bits is used. If the upper
;; 32-bits are equal then the lower 32-bits comparison is used instead.
(rule 0 (x64_pcmpgt $I64X2 x y)
(let (
(mask Xmm (x64_movdqu_load (emit_u128_le_const 0x00000000_80000000_00000000_80000000)))
(x_masked Xmm (x64_pxor mask x))
(y_masked Xmm (x64_pxor mask y))
(cmp32 Xmm (x64_pcmpgtd_a x_masked y_masked))
(low_halves_gt Xmm (x64_pshufd cmp32 0xa0))
(high_halves_gt Xmm (x64_pshufd cmp32 0xf5))
(cmp_eq Xmm (x64_pcmpeqd x_masked y_masked))
(high_halves_eq Xmm (x64_pshufd cmp_eq 0xf5))
(low_gt_and_high_eq Xmm (x64_pand low_halves_gt high_halves_eq))
)
(x64_por low_gt_and_high_eq high_halves_gt)))
(decl x64_add_mem (Type SyntheticAmode Value) SideEffectNoResult)
(spec (x64_add_mem ty addr val)
(provide (= result (store_effect
(extract 79 64 addr)
ty
(conv_to ty (bvadd (load_effect (extract 79 64 addr) ty (extract 63 0 addr)) (conv_to ty val)))
(extract 63 0 addr))
)
)
(require (or (= ty 32) (= ty 64)))
)
;; `add mem, reg`
(rule 0 (x64_add_mem $I8 addr val) (x64_addb_mr_mem addr val))
(rule 0 (x64_add_mem $I16 addr val) (x64_addw_mr_mem addr val))
(rule 0 (x64_add_mem $I32 addr val) (x64_addl_mr_mem addr val))
(rule 0 (x64_add_mem $I64 addr val) (x64_addq_mr_mem addr val))
;; `add mem, imm`
(rule 1 (x64_add_mem $I8 addr (u8_from_iconst val)) (x64_addb_mi_mem addr val))
(rule 1 (x64_add_mem $I16 addr (u16_from_iconst val)) (x64_addw_mi_mem addr val))
(rule 1 (x64_add_mem $I32 addr (u32_from_iconst val)) (x64_addl_mi_mem addr val))
(rule 1 (x64_add_mem $I64 addr (i32_from_iconst val)) (x64_addq_mi_sxl_mem addr val))
(rule 2 (x64_add_mem $I32 addr (i8_from_iconst val)) (x64_addl_mi_sxb_mem addr val))
(rule 2 (x64_add_mem $I64 addr (i8_from_iconst val)) (x64_addq_mi_sxb_mem addr val))
(decl x64_sub_mem (Type SyntheticAmode Value) SideEffectNoResult)
;; `sub mem, reg`
(rule 0 (x64_sub_mem $I8 addr val) (x64_subb_mr_mem addr val))
(rule 0 (x64_sub_mem $I16 addr val) (x64_subw_mr_mem addr val))
(rule 0 (x64_sub_mem $I32 addr val) (x64_subl_mr_mem addr val))
(rule 0 (x64_sub_mem $I64 addr val) (x64_subq_mr_mem addr val))
;; `sub mem, imm`
(rule 1 (x64_sub_mem $I8 addr (u8_from_iconst val)) (x64_subb_mi_mem addr val))
(rule 1 (x64_sub_mem $I16 addr (u16_from_iconst val)) (x64_subw_mi_mem addr val))
(rule 1 (x64_sub_mem $I32 addr (u32_from_iconst val)) (x64_subl_mi_mem addr val))
(rule 1 (x64_sub_mem $I64 addr (i32_from_iconst val)) (x64_subq_mi_sxl_mem addr val))
(rule 2 (x64_sub_mem $I32 addr (i8_from_iconst val)) (x64_subl_mi_sxb_mem addr val))
(rule 2 (x64_sub_mem $I64 addr (i8_from_iconst val)) (x64_subq_mi_sxb_mem addr val))
(decl x64_and_mem (Type SyntheticAmode Value) SideEffectNoResult)
;; `and mem, imm`
(rule (x64_and_mem $I8 addr val) (x64_andb_mr_mem addr val))
(rule (x64_and_mem $I16 addr val) (x64_andw_mr_mem addr val))
(rule (x64_and_mem $I32 addr val) (x64_andl_mr_mem addr val))
(rule (x64_and_mem $F32 addr val) (x64_andl_mr_mem addr val))
(rule (x64_and_mem $I64 addr val) (x64_andq_mr_mem addr val))
(rule (x64_and_mem $F64 addr val) (x64_andq_mr_mem addr val))
;; `and mem, imm`
(rule 1 (x64_and_mem $I8 addr (u8_from_iconst val)) (x64_andb_mi_mem addr val))
(rule 1 (x64_and_mem $I16 addr (u16_from_iconst val)) (x64_andw_mi_mem addr val))
(rule 1 (x64_and_mem $I32 addr (u32_from_iconst val)) (x64_andl_mi_mem addr val))
(rule 1 (x64_and_mem $I64 addr (i32_from_iconst val)) (x64_andq_mi_sxl_mem addr val))
(rule 2 (x64_and_mem $I32 addr (i8_from_iconst val)) (x64_andl_mi_sxb_mem addr val))
(rule 2 (x64_and_mem $I64 addr (i8_from_iconst val)) (x64_andq_mi_sxb_mem addr val))
(decl x64_or_mem (Type SyntheticAmode Value) SideEffectNoResult)
;; `or mem, reg`
(rule 0 (x64_or_mem $I8 addr val) (x64_orb_mr_mem addr val))
(rule 0 (x64_or_mem $I16 addr val) (x64_orw_mr_mem addr val))
(rule 0 (x64_or_mem $I32 addr val) (x64_orl_mr_mem addr val))
(rule 0 (x64_or_mem $F32 addr val) (x64_orl_mr_mem addr val))
(rule 0 (x64_or_mem $I64 addr val) (x64_orq_mr_mem addr val))
(rule 0 (x64_or_mem $F64 addr val) (x64_orq_mr_mem addr val))
;; `or mem, imm`
(rule 1 (x64_or_mem $I8 addr (u8_from_iconst val)) (x64_orb_mi_mem addr val))
(rule 1 (x64_or_mem $I16 addr (u16_from_iconst val)) (x64_orw_mi_mem addr val))
(rule 1 (x64_or_mem $I32 addr (u32_from_iconst val)) (x64_orl_mi_mem addr val))
(rule 1 (x64_or_mem $I64 addr (i32_from_iconst val)) (x64_orq_mi_sxl_mem addr val))
(rule 2 (x64_or_mem $I32 addr (i8_from_iconst val)) (x64_orl_mi_sxb_mem addr val))
(rule 2 (x64_or_mem $I64 addr (i8_from_iconst val)) (x64_orq_mi_sxb_mem addr val))
(decl x64_xor_mem (Type SyntheticAmode Value) SideEffectNoResult)
;; `xor mem, reg`
(rule 0 (x64_xor_mem $I8 addr val) (x64_xorb_mr_mem addr val))
(rule 0 (x64_xor_mem $I16 addr val) (x64_xorw_mr_mem addr val))
(rule 0 (x64_xor_mem $I32 addr val) (x64_xorl_mr_mem addr val))
(rule 0 (x64_xor_mem $F32 addr val) (x64_xorl_mr_mem addr val))
(rule 0 (x64_xor_mem $I64 addr val) (x64_xorq_mr_mem addr val))
(rule 0 (x64_xor_mem $F64 addr val) (x64_xorq_mr_mem addr val))
;; `xor mem, imm`
(rule 1 (x64_xor_mem $I8 addr (u8_from_iconst val)) (x64_xorb_mi_mem addr val))
(rule 1 (x64_xor_mem $I16 addr (u16_from_iconst val)) (x64_xorw_mi_mem addr val))
(rule 1 (x64_xor_mem $I32 addr (u32_from_iconst val)) (x64_xorl_mi_mem addr val))
(rule 1 (x64_xor_mem $I64 addr (i32_from_iconst val)) (x64_xorq_mi_sxl_mem addr val))
(rule 2 (x64_xor_mem $I32 addr (i8_from_iconst val)) (x64_xorl_mi_sxb_mem addr val))
(rule 2 (x64_xor_mem $I64 addr (i8_from_iconst val)) (x64_xorq_mi_sxb_mem addr val))
;; Trap if the condition code supplied is set.
(decl trap_if (CC TrapCode) ConsumesFlags)
(rule (trap_if cc tc)
(ConsumesFlags.ConsumesFlagsSideEffect (MInst.TrapIf cc tc)))
;; Trap if both of the condition codes supplied are set.
(decl trap_if_and (CC CC TrapCode) ConsumesFlags)
(rule (trap_if_and cc1 cc2 tc)
(ConsumesFlags.ConsumesFlagsSideEffect (MInst.TrapIfAnd cc1 cc2 tc)))
;; Trap if either of the condition codes supplied are set.
(decl trap_if_or (CC CC TrapCode) ConsumesFlags)
(rule (trap_if_or cc1 cc2 tc)
(ConsumesFlags.ConsumesFlagsSideEffect (MInst.TrapIfOr cc1 cc2 tc)))
;; Helper for creating `movddup` instructions
(decl x64_movddup (XmmMem) Xmm)
(rule (x64_movddup src) (x64_movddup_a src))
(rule 1 (x64_movddup src)
(if-let true (has_avx))
(x64_vmovddup_a src))
;; Helpers for creating `vpbroadcast*` instructions.
(decl x64_vpbroadcastb (XmmMem) Xmm)
(rule (x64_vpbroadcastb src) (x64_vpbroadcastb_a src))
(decl x64_vpbroadcastw (XmmMem) Xmm)
(rule (x64_vpbroadcastw src) (x64_vpbroadcastw_a src))
(decl x64_vpbroadcastd (XmmMem) Xmm)
(rule (x64_vpbroadcastd src) (x64_vpbroadcastd_a src))
(decl x64_vbroadcastss (XmmMem) Xmm)
(rule 1 (x64_vbroadcastss (is_xmm src)) (x64_vbroadcastss_a_r src))
(rule 0 (x64_vbroadcastss (is_mem src)) (x64_vbroadcastss_a_m src))
;;;; Jumps ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Unconditional jump.
(decl jmp_known (MachLabel) SideEffectNoResult)
(rule (jmp_known target)
(SideEffectNoResult.Inst (MInst.JmpKnown target)))
;; Conditional jump based on the condition code.
(decl jmp_cond (CC MachLabel MachLabel) ConsumesFlags)
(rule (jmp_cond cc taken not_taken)
(ConsumesFlags.ConsumesFlagsSideEffect (MInst.JmpCond cc taken not_taken)))
;; Conditional jump based on the OR of two condition codes.
(decl jmp_cond_or (CC CC MachLabel MachLabel) ConsumesFlags)
(rule (jmp_cond_or cc1 cc2 taken not_taken)
(ConsumesFlags.ConsumesFlagsSideEffect (MInst.JmpCondOr cc1 cc2 taken not_taken)))
;; Conditional jump based on a `CondResult`
;;
;; Recursion: at most to convert `And` into `Or`.
(decl rec jmp_cond_result (CondResult MachLabel MachLabel) SideEffectNoResult)
(rule (jmp_cond_result (CondResult.CC producer cc) taken not_taken)
(with_flags_side_effect producer (jmp_cond cc taken not_taken)))
(rule (jmp_cond_result cond @ (CondResult.And _ _ _) taken not_taken)
(jmp_cond_result (cond_invert cond) not_taken taken))
(rule (jmp_cond_result (CondResult.Or producer cc1 cc2) taken not_taken)
(with_flags_side_effect producer
(jmp_cond_or cc1 cc2 taken not_taken)))
;; Emit the compound instruction that does:
;;
;; lea $jt, %rA
;; movsbl [%rA, %rIndex, 2], %rB
;; add %rB, %rA
;; j *%rA
;; [jt entries]
;;
;; This must be *one* instruction in the vcode because we cannot allow regalloc
;; to insert any spills/fills in the middle of the sequence; otherwise, the
;; lea PC-rel offset to the jumptable would be incorrect. (The alternative
;; is to introduce a relocation pass for inlined jumptables, which is much
;; worse.)
(decl jmp_table_seq (Type Gpr MachLabel BoxVecMachLabel) SideEffectNoResult)
(rule (jmp_table_seq ty idx default_target jt_targets)
(let (
;; This temporary is used as a signed integer of 64-bits (to hold
;; addresses).
(tmp1 WritableGpr (temp_writable_gpr))
;; This temporary is used as a signed integer of 32-bits (for the
;; wasm-table index) and then 64-bits (address addend). The small
;; lie about the I64 type is benign, since the temporary is dead
;; after this instruction (and its Cranelift type is thus unused).
(tmp2 WritableGpr (temp_writable_gpr)))
(SideEffectNoResult.Inst
(MInst.JmpTableSeq idx tmp1 tmp2 default_target jt_targets))))
;;;; Comparisons ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Representation of the result of a conditional instruction.
;;
;; Each variant here has what produces some condition flags in addition to
;; what condition code is being tested as a result of whatever produced the
;; flags.
;;
;; This type is intended to be a "narrow waist" for anything producing a
;; conditional which `icmp` might flow into for example. The `is_nonzero_cmp`
;; constructor is the main constructor of this type which takes any arbitrary
;; value used in a conditional-like location. There are further refined
;; constructors such as `emit_{cmp,fcmp}` which work specifically on the shapes
;; of `icmp` and `fcmp` CLIF instructions. Everything produces this type, and
;; then decisions about what instructions to emit flow from this type.
(type CondResult
(enum
;; The given condition code must be set.
(CC (producer ProducesFlags) (cc CC))
;; Both condition codes must be set.
(And (producer ProducesFlags) (cc1 CC) (cc2 CC))
;; Either of the conditions codes must be set.
(Or (producer ProducesFlags) (cc1 CC) (cc2 CC))))
;; Inverts a `CondResult` to have the opposite meaning.
(decl cond_invert (CondResult) CondResult)
(rule (cond_invert (CondResult.CC flags cc)) (CondResult.CC flags (cc_invert cc)))
(rule (cond_invert (CondResult.Or flags cc1 cc2)) (CondResult.And flags (cc_invert cc1) (cc_invert cc2)))
(rule (cond_invert (CondResult.And flags cc1 cc2)) (CondResult.Or flags (cc_invert cc1) (cc_invert cc2)))
;; Converts a `Value` to a `CondResult` with the condition being tested if
;; `Value` is nonzero.
;;
;; Note that this is used as the base entry case for instruction lowering such
;; as `select` and `brif`. The `Value` here is expected to, via CLIF validation,
;; have an integer type (and it can be I128)
(decl is_nonzero (Value) CondResult)
;; Base case: fits in one GPR, use `x64_test`
(rule (is_nonzero val @ (value_type (is_single_register_gpr_type ty)))
(let ((gpr Gpr val)) (CondResult.CC (x64_test ty gpr gpr) (CC.NZ))))
;; Base case: i128
(rule 1 (is_nonzero val @ (value_type $I128))
(let ((lo Gpr (value_regs_get_gpr val 0))
(hi Gpr (value_regs_get_gpr val 1)))
(CondResult.CC
(x64_produce_flags_side_effect (ProduceFlagsSideEffectOp.Or) $I64 lo hi)
(CC.NZ))))
;; Special case some instructions where lowerings directly produce condition
;; codes.
(rule 2 (is_nonzero (vall_true vec)) (is_vall_true vec))
(rule 2 (is_nonzero (vany_true vec)) (is_vany_true vec))
(rule 2 (is_nonzero (uextend (vall_true vec))) (is_vall_true vec))
(rule 2 (is_nonzero (uextend (vany_true vec))) (is_vany_true vec))
(rule 2 (is_nonzero (band a @ (value_type (ty_int (fits_in_64 ty))) b))
(is_nonzero_band ty a b))
;; Like `is_nonzero` but with additional specializations for compare
;; operators. We break this out from `is_nonzero` because we want to
;; avoid unbounded recursion.
(decl is_nonzero_cmp (Value) CondResult)
(rule 1 (is_nonzero_cmp (fcmp cc a b)) (emit_fcmp cc a b))
(rule 1 (is_nonzero_cmp (icmp cc a b)) (emit_cmp cc a b))
(rule 1 (is_nonzero_cmp (uextend (fcmp cc a b))) (emit_fcmp cc a b))
(rule 1 (is_nonzero_cmp (uextend (icmp cc a b))) (emit_cmp cc a b))
(rule 0 (is_nonzero_cmp val) (is_nonzero val))
(decl is_nonzero_band (Type Value Value) CondResult)
(rule 0 (is_nonzero_band ty a b) (CondResult.CC (x64_test ty a b) (CC.NZ)))
;; If a value is and'd with an immediate that has exactly one bit set then this
;; can pattern-match to the native `bt` instruction. Note that to have the
;; same semantics this requires that `a` is in a register which forces `bt` to
;; use modulo semantics for the second operand `b`, thus `put_in_gpr` is
;; manually used.
(rule 1 (is_nonzero_band (ty_32_or_64 ty) a (ishl (u64_from_iconst 1) b))
(CondResult.CC (x64_bt ty (put_in_gpr a) b) (CC.B)))
;; If a value is and'd one shifted by a variable value that matches `bt` as
;; well.
(rule 1 (is_nonzero_band $I64 a (u64_from_iconst (bt_imm n)))
(CondResult.CC (x64_bt_imm $I64 a n) (CC.B)))
;; If what we're testing against is a 32-bit integer then this is a candidate
;; for both the `test` and `bt` instructions (only `bt` if the integer as one
;; bit set). According to [1] the `test` instruction has a higher throughput
;; at least historically than the `bt` instruction so here `test` is explicitly
;; favored over `bt`, even if `bt` were applicable. Note that LLVM also looks to
;; favor `bt` as well.
;;
;; [1]: https://github.com/bytecodealliance/wasmtime/pull/11128#discussion_r2164888415
(rule 2 (is_nonzero_band ty a b @ (i32_from_iconst _))
(CondResult.CC (x64_test ty a b) (CC.NZ)))
;; Helper to test whether the `u64` input has a single bit set, and if so
;; yields the bit position of where that bit is set. Used in the lowering of
;; `x64_bt_imm` above.
(decl bt_imm (u8) u64)
(extern extractor bt_imm bt_imm)
;; Lower a CondResult to a boolean value in a register.
(decl lower_cond_bool (CondResult) Gpr)
(rule (lower_cond_bool (CondResult.CC producer cc))
(value_regs_get_gpr (with_flags producer (x64_setcc cc)) 0))
(rule (lower_cond_bool (CondResult.And producer cc1 cc2))
(let ((maybe ValueRegs (with_flags producer
(consumes_flags_concat
(x64_setcc cc1)
(x64_setcc cc2))))
(maybe0 Gpr (value_regs_get_gpr maybe 0))
(maybe1 Gpr (value_regs_get_gpr maybe 1)))
(x64_and $I8 maybe0 maybe1)))
(rule (lower_cond_bool (CondResult.Or producer cc1 cc2))
(let ((maybe ValueRegs (with_flags producer
(consumes_flags_concat
(x64_setcc cc1)
(x64_setcc cc2))))
(maybe0 Gpr (value_regs_get_gpr maybe 0))
(maybe1 Gpr (value_regs_get_gpr maybe 1)))
(x64_or $I8 maybe0 maybe1)))
;; Helper to transform an `icmp` node into a `CondResult`.
;;
;; Note that via CLIF validation the two values here should have the same type.
(decl emit_cmp (IntCC Value Value) CondResult)
;; For GPR-held values we only need to emit `CMP`.
(rule 0 (emit_cmp cc a @ (value_type ty) b) (CondResult.CC (x64_cmp ty a b) cc))
;; As a special case, swap the arguments to the comparison when the LHS is a
;; constant. This ensures that we avoid moving the constant into a register when
;; performing the comparison.
(rule 1 (emit_cmp cc (and (simm32_from_value a) (value_type ty)) b)
(CondResult.CC (x64_cmp ty b a) (intcc_swap_args cc)))
;; Special case: use the test instruction for comparisons with 0.
(rule 2 (emit_cmp cc a @ (value_type ty) (u64_from_iconst 0))
(let ((a Gpr (put_in_reg a)))
(CondResult.CC (x64_test ty a a) cc)))
(rule 3 (emit_cmp cc (u64_from_iconst 0) b @ (value_type ty))
(let ((b Gpr (put_in_reg b)))
(CondResult.CC (x64_test ty b b) (intcc_swap_args cc))))
;; For I128 values (held in two GPRs), the instruction sequences depend on what
;; kind of condition is tested.
(rule 4 (emit_cmp cc a @ (value_type $I128) b)
(let ((a_lo Gpr (value_regs_get_gpr a 0))
(a_hi Gpr (value_regs_get_gpr a 1))
(b_lo Gpr (value_regs_get_gpr b 0))
(b_hi Gpr (value_regs_get_gpr b 1)))
(emit_cmp_i128 cc a_hi a_lo b_hi b_lo)))
;; For direct equality comparisons to zero transform the other operand into a
;; nonzero comparison and then invert the whole conditional to test for zero.
(rule 5 (emit_cmp (IntCC.Equal) a (u64_from_iconst 0)) (cond_invert (is_nonzero a)))
(rule 6 (emit_cmp (IntCC.Equal) (u64_from_iconst 0) a) (cond_invert (is_nonzero a)))
(rule 5 (emit_cmp (IntCC.NotEqual) a (u64_from_iconst 0)) (is_nonzero a))
(rule 6 (emit_cmp (IntCC.NotEqual) (u64_from_iconst 0) a) (is_nonzero a))
; Recursion: at most one to eliminate "or equal" cases.
(decl rec emit_cmp_i128 (CC Gpr Gpr Gpr Gpr) CondResult)
;; Eliminate cases which compare something "or equal" by swapping arguments.
(rule 2 (emit_cmp_i128 (CC.NLE) a_hi a_lo b_hi b_lo)
(emit_cmp_i128 (CC.L) b_hi b_lo a_hi a_lo))
(rule 2 (emit_cmp_i128 (CC.LE) a_hi a_lo b_hi b_lo)
(emit_cmp_i128 (CC.NL) b_hi b_lo a_hi a_lo))
(rule 2 (emit_cmp_i128 (CC.NBE) a_hi a_lo b_hi b_lo)
(emit_cmp_i128 (CC.B) b_hi b_lo a_hi a_lo))
(rule 2 (emit_cmp_i128 (CC.BE) a_hi a_lo b_hi b_lo)
(emit_cmp_i128 (CC.NB) b_hi b_lo a_hi a_lo))
;; 128-bit strict equality/inequality can't be easily tested using subtraction
;; but we can quickly determine whether any bits are different instead.
(rule 1 (emit_cmp_i128 (cc_nz_or_z cc) a_hi a_lo b_hi b_lo)
(let ((same_lo Reg (x64_xor $I64 a_lo b_lo))
(same_hi Reg (x64_xor $I64 a_hi b_hi)))
(CondResult.CC
(x64_produce_flags_side_effect (ProduceFlagsSideEffectOp.Or) $I64 same_lo same_hi)
cc)))
;; The only cases left are L/NL/B/NB which we can implement with a sub/sbb
;; sequence. But since we don't care about anything but the flags we can
;; replace the sub with cmp, which avoids clobbering one of the registers.
(rule 0 (emit_cmp_i128 cc a_hi a_lo b_hi b_lo)
(CondResult.CC
(produces_flags_concat
(x64_cmpq_rm a_lo b_lo)
(x64_produce_flags_side_effect (ProduceFlagsSideEffectOp.Sbb) $I64 a_hi b_hi))
cc))
;; CLIF's `fcmp` instruction always operates on XMM registers--both scalar and
;; vector. For the scalar versions, we use the flag-setting behavior of the
;; `UCOMIS*`.
;;
;; Checking the result of `UCOMIS*` is unfortunately difficult in some cases
;; because we do not have a single condition code to check for the condition
;; (i.e., `eq`, `le`, `gt`, etc.) *and* orderedness. Instead, we must check
;; the flags multiple times. The UCOMIS* documentation (see Intel's Software
;; Developer's Manual, volume 2, chapter 4)
;; is helpful:
;; - unordered assigns Z = 1, P = 1, C = 1
;; - greater than assigns Z = 0, P = 0, C = 0
;; - less than assigns Z = 0, P = 0, C = 1
;; - equal assigns Z = 1, P = 0, C = 0
(decl emit_fcmp (FloatCC Value Value) CondResult)
(rule (emit_fcmp (FloatCC.Equal) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.And (x64_ucomis ty a b) (CC.NP) (CC.Z)))
(rule (emit_fcmp (FloatCC.NotEqual) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.Or (x64_ucomis ty a b) (CC.P) (CC.NZ)))
;; Some scalar lowerings correspond to one condition code.
(rule (emit_fcmp (FloatCC.Ordered) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.NP)))
(rule (emit_fcmp (FloatCC.Unordered) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.P)))
(rule (emit_fcmp (FloatCC.OrderedNotEqual) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.NZ)))
(rule (emit_fcmp (FloatCC.UnorderedOrEqual) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.Z)))
(rule (emit_fcmp (FloatCC.GreaterThan) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.NBE)))
(rule (emit_fcmp (FloatCC.GreaterThanOrEqual) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.NB)))
(rule (emit_fcmp (FloatCC.UnorderedOrLessThan) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.B)))
(rule (emit_fcmp (FloatCC.UnorderedOrLessThanOrEqual) a @ (value_type (ty_scalar_float ty)) b)
(CondResult.CC (x64_ucomis ty a b) (CC.BE)))
;; Other scalar lowerings are made possible by flipping the operands and
;; reversing the condition code.
(rule (emit_fcmp (FloatCC.LessThan) a @ (value_type (ty_scalar_float ty)) b)
;; Same flags as `GreaterThan`.
(CondResult.CC (x64_ucomis ty b a) (CC.NBE)))
(rule (emit_fcmp (FloatCC.LessThanOrEqual) a @ (value_type (ty_scalar_float ty)) b)
;; Same flags as `GreaterThanOrEqual`.
(CondResult.CC (x64_ucomis ty b a) (CC.NB)))
(rule (emit_fcmp (FloatCC.UnorderedOrGreaterThan) a @ (value_type (ty_scalar_float ty)) b)
;; Same flags as `UnorderedOrLessThan`.
(CondResult.CC (x64_ucomis ty b a) (CC.B)))
(rule (emit_fcmp (FloatCC.UnorderedOrGreaterThanOrEqual) a @ (value_type (ty_scalar_float ty)) b)
;; Same flags as `UnorderedOrLessThanOrEqual`.
(CondResult.CC (x64_ucomis ty b a) (CC.BE)))
;;;; Type Guards ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; A type guard for matching ints and bools up to 64 bits, or 64 bit references.
(decl ty_int_bool_or_ref () Type)
(extern extractor ty_int_bool_or_ref ty_int_bool_or_ref)
;;;; Atomics ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl x64_cmpxchg (Type Gpr Gpr SyntheticAmode) Gpr)
(rule (x64_cmpxchg $I8 expected replacement addr) (x64_lock_cmpxchgb_mr addr replacement expected))
(rule (x64_cmpxchg $I16 expected replacement addr) (x64_lock_cmpxchgw_mr addr replacement expected))
(rule (x64_cmpxchg $I32 expected replacement addr) (x64_lock_cmpxchgl_mr addr replacement expected))
(rule (x64_cmpxchg $I64 expected replacement addr) (x64_lock_cmpxchgq_mr addr replacement expected))
(decl x64_cmpxchg16b (ValueRegs ValueRegs SyntheticAmode) ValueRegs)
(rule (x64_cmpxchg16b expected replacement addr)
(let ((expected_low Gpr (value_regs_get_gpr expected 0))
(expected_high Gpr (value_regs_get_gpr expected 1))
(replacement_low Gpr (value_regs_get_gpr replacement 0))
(replacement_high Gpr (value_regs_get_gpr replacement 1)))
(x64_lock_cmpxchg16b_m expected_low expected_high replacement_low replacement_high addr)))
(decl x64_xadd (Type SyntheticAmode Gpr) Gpr)
(rule (x64_xadd $I8 addr operand) (x64_lock_xaddb_mr addr operand))
(rule (x64_xadd $I16 addr operand) (x64_lock_xaddw_mr addr operand))
(rule (x64_xadd $I32 addr operand) (x64_lock_xaddl_mr addr operand))
(rule (x64_xadd $I64 addr operand) (x64_lock_xaddq_mr addr operand))
(decl x64_xchg (Type SyntheticAmode Gpr) Gpr)
(rule (x64_xchg $I8 addr operand) (x64_xchgb_rm operand addr))
(rule (x64_xchg $I16 addr operand) (x64_xchgw_rm operand addr))
(rule (x64_xchg $I32 addr operand) (x64_xchgl_rm operand addr))
(rule (x64_xchg $I64 addr operand) (x64_xchgq_rm operand addr))
(decl x64_lock_add (OperandSize SyntheticAmode Gpr) SideEffectNoResult)
(rule (x64_lock_add (OperandSize.Size8) addr reg) (x64_lock_addb_mr_mem addr reg))
(rule (x64_lock_add (OperandSize.Size16) addr reg) (x64_lock_addw_mr_mem addr reg))
(rule (x64_lock_add (OperandSize.Size32) addr reg) (x64_lock_addl_mr_mem addr reg))
(rule (x64_lock_add (OperandSize.Size64) addr reg) (x64_lock_addq_mr_mem addr reg))
(decl x64_lock_sub (OperandSize SyntheticAmode Gpr) SideEffectNoResult)
(rule (x64_lock_sub (OperandSize.Size8) addr reg) (x64_lock_subb_mr_mem addr reg))
(rule (x64_lock_sub (OperandSize.Size16) addr reg) (x64_lock_subw_mr_mem addr reg))
(rule (x64_lock_sub (OperandSize.Size32) addr reg) (x64_lock_subl_mr_mem addr reg))
(rule (x64_lock_sub (OperandSize.Size64) addr reg) (x64_lock_subq_mr_mem addr reg))
(decl x64_lock_and (OperandSize SyntheticAmode Gpr) SideEffectNoResult)
(rule (x64_lock_and (OperandSize.Size8) addr reg) (x64_lock_andb_mr_mem addr reg))
(rule (x64_lock_and (OperandSize.Size16) addr reg) (x64_lock_andw_mr_mem addr reg))
(rule (x64_lock_and (OperandSize.Size32) addr reg) (x64_lock_andl_mr_mem addr reg))
(rule (x64_lock_and (OperandSize.Size64) addr reg) (x64_lock_andq_mr_mem addr reg))
(decl x64_lock_or (OperandSize SyntheticAmode Gpr) SideEffectNoResult)
(rule (x64_lock_or (OperandSize.Size8) addr reg) (x64_lock_orb_mr_mem addr reg))
(rule (x64_lock_or (OperandSize.Size16) addr reg) (x64_lock_orw_mr_mem addr reg))
(rule (x64_lock_or (OperandSize.Size32) addr reg) (x64_lock_orl_mr_mem addr reg))
(rule (x64_lock_or (OperandSize.Size64) addr reg) (x64_lock_orq_mr_mem addr reg))
(decl x64_lock_xor (OperandSize SyntheticAmode Gpr) SideEffectNoResult)
(rule (x64_lock_xor (OperandSize.Size8) addr reg) (x64_lock_xorb_mr_mem addr reg))
(rule (x64_lock_xor (OperandSize.Size16) addr reg) (x64_lock_xorw_mr_mem addr reg))
(rule (x64_lock_xor (OperandSize.Size32) addr reg) (x64_lock_xorl_mr_mem addr reg))
(rule (x64_lock_xor (OperandSize.Size64) addr reg) (x64_lock_xorq_mr_mem addr reg))
(decl x64_atomic_rmw_seq (Type AtomicRmwSeqOp SyntheticAmode Gpr) Gpr)
(rule (x64_atomic_rmw_seq ty op mem input)
(let ((dst WritableGpr (temp_writable_gpr))
(tmp WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.AtomicRmwSeq ty op mem input tmp dst))))
dst))
(decl x64_atomic_128_rmw_seq (AtomicRmwOp SyntheticAmode ValueRegs) ValueRegs)
(rule (x64_atomic_128_rmw_seq op mem input)
(let ((dst_low WritableGpr (temp_writable_gpr))
(dst_high WritableGpr (temp_writable_gpr))
(tmp_low WritableGpr (temp_writable_gpr))
(tmp_high WritableGpr (temp_writable_gpr))
(input_low Gpr (value_regs_get_gpr input 0))
(input_high Gpr (value_regs_get_gpr input 1))
(_ Unit (emit (MInst.Atomic128RmwSeq (atomic_128_rmw_seq_op op) mem input_low input_high tmp_low tmp_high dst_low dst_high))))
(value_regs dst_low dst_high)))
(rule 1 (x64_atomic_128_rmw_seq (AtomicRmwOp.Xchg) mem input)
(let ((dst_low WritableGpr (temp_writable_gpr))
(dst_high WritableGpr (temp_writable_gpr))
(input_low Gpr (value_regs_get_gpr input 0))
(input_high Gpr (value_regs_get_gpr input 1))
(_ Unit (emit (MInst.Atomic128XchgSeq mem input_low input_high dst_low dst_high))))
(value_regs dst_low dst_high)))
(decl x64_atomic_128_store_seq (SyntheticAmode ValueRegs) SideEffectNoResult)
(rule (x64_atomic_128_store_seq mem input)
(let ((dst_low WritableGpr (temp_writable_gpr))
(dst_high WritableGpr (temp_writable_gpr))
(input_low Gpr (value_regs_get_gpr input 0))
(input_high Gpr (value_regs_get_gpr input 1)))
(SideEffectNoResult.Inst (MInst.Atomic128XchgSeq mem input_low input_high dst_low dst_high))))
(type AtomicRmwSeqOp
(enum And
Nand
Or
Xor
Umin
Umax
Smin
Smax))
(decl atomic_rmw_seq_op (AtomicRmwOp) AtomicRmwSeqOp)
(rule (atomic_rmw_seq_op (AtomicRmwOp.And)) (AtomicRmwSeqOp.And))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Nand)) (AtomicRmwSeqOp.Nand))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Or)) (AtomicRmwSeqOp.Or))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Xor)) (AtomicRmwSeqOp.Xor))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Umin)) (AtomicRmwSeqOp.Umin))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Umax)) (AtomicRmwSeqOp.Umax))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Smin)) (AtomicRmwSeqOp.Smin))
(rule (atomic_rmw_seq_op (AtomicRmwOp.Smax)) (AtomicRmwSeqOp.Smax))
(type Atomic128RmwSeqOp
(enum Add
Sub
And
Nand
Or
Xor
Umin
Umax
Smin
Smax))
(decl atomic_128_rmw_seq_op (AtomicRmwOp) Atomic128RmwSeqOp)
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Add)) (Atomic128RmwSeqOp.Add))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Sub)) (Atomic128RmwSeqOp.Sub))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.And)) (Atomic128RmwSeqOp.And))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Nand)) (Atomic128RmwSeqOp.Nand))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Or)) (Atomic128RmwSeqOp.Or))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Xor)) (Atomic128RmwSeqOp.Xor))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Umin)) (Atomic128RmwSeqOp.Umin))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Umax)) (Atomic128RmwSeqOp.Umax))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Smin)) (Atomic128RmwSeqOp.Smin))
(rule (atomic_128_rmw_seq_op (AtomicRmwOp.Smax)) (Atomic128RmwSeqOp.Smax))
;;;; Casting ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl bitcast_xmm_to_gpr (u8 Xmm) Gpr)
(rule (bitcast_xmm_to_gpr 16 src)
(x64_pextrw src 0))
(rule (bitcast_xmm_to_gpr 32 src)
(x64_movd_to_gpr src))
(rule (bitcast_xmm_to_gpr 64 src)
(x64_movq_to_gpr src))
(decl bitcast_xmm_to_gprs (Xmm) ValueRegs)
(rule (bitcast_xmm_to_gprs src)
(value_regs (x64_movq_to_gpr src) (x64_movq_to_gpr (x64_pshufd src 0b11101110))))
;; This rule zeroes out the upper bits of the XMM register; we need this to
;; avoid undefined bits in scaler_to_vector.
(decl bitcast_gpr_to_xmm (u8 Gpr) Xmm)
(rule (bitcast_gpr_to_xmm 16 src)
(x64_pinsrw (xmm_zero $I16X8) src 0))
(rule (bitcast_gpr_to_xmm 32 src)
(x64_movd_to_xmm src))
(rule (bitcast_gpr_to_xmm 64 src)
(x64_movq_to_xmm src))
(decl bitcast_gprs_to_xmm (ValueRegs) Xmm)
(rule (bitcast_gprs_to_xmm src)
(x64_punpcklqdq (x64_movq_to_xmm (value_regs_get_gpr src 0)) (x64_movq_to_xmm (value_regs_get_gpr src 1))))
;;;; Stack Addresses ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl stack_addr_impl (StackSlot Offset32) Gpr)
(rule (stack_addr_impl stack_slot offset)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (abi_stackslot_addr dst stack_slot offset))))
dst))
;;;; Division/Remainders ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Helper for creating `CheckedSRemSeq` instructions.
(decl x64_checked_srem_seq (OperandSize Gpr Gpr Gpr) ValueRegs)
(rule (x64_checked_srem_seq size dividend_lo dividend_hi divisor)
(let ((dst_quotient WritableGpr (temp_writable_gpr))
(dst_remainder WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CheckedSRemSeq size dividend_lo dividend_hi divisor dst_quotient dst_remainder))))
(value_regs dst_quotient dst_remainder)))
(decl x64_checked_srem_seq8 (Gpr Gpr) Gpr)
(rule (x64_checked_srem_seq8 dividend divisor)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CheckedSRemSeq8 dividend divisor dst))))
dst))
;; Helper for creating `Div` instructions
;;
;; Two registers are returned through `ValueRegs` where the first is the
;; quotient and the second is the remainder.
(decl x64_div (Type Gpr Gpr GprMem TrapCode) ValueRegs)
(rule (x64_div $I16 lo hi divisor code) (x64_divw_m lo hi divisor code))
(rule (x64_div $I32 lo hi divisor code) (x64_divl_m lo hi divisor code))
(rule (x64_div $I64 lo hi divisor code) (x64_divq_m lo hi divisor code))
(decl x64_idiv (Type Gpr Gpr GprMem TrapCode) ValueRegs)
(rule (x64_idiv $I16 lo hi divisor code) (x64_idivw_m lo hi divisor code))
(rule (x64_idiv $I32 lo hi divisor code) (x64_idivl_m lo hi divisor code))
(rule (x64_idiv $I64 lo hi divisor code) (x64_idivq_m lo hi divisor code))
;;;; Pinned Register ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl read_pinned_gpr () Gpr)
(rule (read_pinned_gpr)
(mov_from_preg (preg_pinned)))
(decl write_pinned_gpr (Gpr) SideEffectNoResult)
(rule (write_pinned_gpr val)
(mov_to_preg (preg_pinned) val))
;;;; Shuffle ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Produce a mask suitable for use with `pshufb` for permuting the argument to
;; shuffle, when the arguments are the same (i.e. `shuffle a a mask`). This will
;; map all indices in the range 0..31 to the range 0..15.
(decl shuffle_0_31_mask (VecMask) VCodeConstant)
(extern constructor shuffle_0_31_mask shuffle_0_31_mask)
;; Produce a mask suitable for use with `pshufb` for permuting the lhs of a
;; `shuffle` operation (lanes 0-15).
(decl shuffle_0_15_mask (VecMask) VCodeConstant)
(extern constructor shuffle_0_15_mask shuffle_0_15_mask)
;; Produce a mask suitable for use with `pshufb` for permuting the rhs of a
;; `shuffle` operation (lanes 16-31).
(decl shuffle_16_31_mask (VecMask) VCodeConstant)
(extern constructor shuffle_16_31_mask shuffle_16_31_mask)
;; Produce a permutation suitable for use with `vpermi2b`, for permuting two
;; I8X16 vectors simultaneously.
;;
;; NOTE: `vpermi2b` will mask the indices in each lane to 5 bits when indexing
;; into vectors, so this constructor makes no effort to handle indices that are
;; larger than 31. If you are lowering a clif opcode like `shuffle` that has
;; special behavior for out of bounds indices (emitting a `0` in the resulting
;; vector in the case of `shuffle`) you'll need to handle that behavior
;; separately.
(decl perm_from_mask (VecMask) VCodeConstant)
(extern constructor perm_from_mask perm_from_mask)
;; If the mask that would be given to `shuffle` contains any out-of-bounds
;; indices, return a mask that will zero those.
(decl perm_from_mask_with_zeros (VCodeConstant VCodeConstant) VecMask)
(extern extractor perm_from_mask_with_zeros perm_from_mask_with_zeros)
;;;; TLS Values ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Helper for emitting ElfTlsGetAddr.
(decl elf_tls_get_addr (ExternalName) Gpr)
(rule (elf_tls_get_addr name)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.ElfTlsGetAddr name dst))))
dst))
;; Helper for emitting MachOTlsGetAddr.
(decl macho_tls_get_addr (ExternalName) Gpr)
(rule (macho_tls_get_addr name)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.MachOTlsGetAddr name dst))))
dst))
;; Helper for emitting CoffTlsGetAddr.
(decl coff_tls_get_addr (ExternalName) Gpr)
(rule (coff_tls_get_addr name)
(let ((dst WritableGpr (temp_writable_gpr))
(tmp WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.CoffTlsGetAddr name dst tmp))))
dst))
;;;; Label Addresses ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(decl x64_label_address (MachLabel) Gpr)
(rule (x64_label_address label)
(let ((dst WritableGpr (temp_writable_gpr))
(_ Unit (emit (MInst.LabelAddress dst label))))
dst))
;;;; Automatic conversions ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(convert Gpr InstOutput output_gpr)
(convert Value Gpr put_in_gpr)
(convert Value GprMem put_in_gpr_mem)
(convert Value GprMemImm put_in_gpr_mem_imm)
(convert Value RegMem put_in_reg_mem)
(convert Value RegMemImm put_in_reg_mem_imm)
(convert Gpr GprMemImm gpr_to_gpr_mem_imm)
(convert Gpr GprMem gpr_to_gpr_mem)
(convert Gpr Reg gpr_to_reg)
(convert GprMem RegMem gpr_mem_to_reg_mem)
(convert Reg Gpr gpr_new)
(convert WritableGpr Gpr writable_gpr_to_gpr)
(convert RegMemImm GprMemImm gpr_mem_imm_new)
(convert RegMem GprMem reg_mem_to_gpr_mem)
(convert RegMem RegMemImm reg_mem_to_reg_mem_imm)
(convert Reg GprMem reg_to_gpr_mem)
(convert Reg GprMemImm reg_to_gpr_mem_imm)
(convert WritableGpr WritableReg writable_gpr_to_reg)
(convert WritableGpr Reg writable_gpr_to_r_reg)
(convert WritableGpr GprMem writable_gpr_to_gpr_mem)
(convert WritableGpr GprMemImm writable_gpr_to_gpr_mem_imm)
(convert WritableGpr ValueRegs writable_gpr_to_value_regs)
(convert Xmm InstOutput output_xmm)
(convert Value Xmm put_in_xmm)
(convert Value XmmMem put_in_xmm_mem)
(convert Value XmmMemAligned put_in_xmm_mem_aligned)
(convert Value XmmMemImm put_in_xmm_mem_imm)
(convert Xmm Reg xmm_to_reg)
(convert Xmm RegMem xmm_to_reg_mem)
(convert Reg Xmm xmm_new)
(convert Reg XmmMem reg_to_xmm_mem)
(convert Reg RegMemImm reg_to_reg_mem_imm)
(convert RegMem XmmMem reg_mem_to_xmm_mem)
(convert Xmm XmmMem xmm_to_xmm_mem)
(convert Xmm XmmMemImm xmm_to_xmm_mem_imm)
(convert Xmm XmmMemAligned xmm_to_xmm_mem_aligned)
(convert XmmMem XmmMemImm xmm_mem_to_xmm_mem_imm)
(convert XmmMem RegMem xmm_mem_to_reg_mem)
(convert RegMemImm XmmMemImm xmm_mem_imm_new)
(convert WritableXmm Xmm writable_xmm_to_xmm)
(convert WritableXmm WritableReg writable_xmm_to_reg)
(convert WritableXmm Reg writable_xmm_to_r_reg)
(convert WritableXmm XmmMem writable_xmm_to_xmm_mem)
(convert WritableXmm XmmMemAligned writable_xmm_to_xmm_mem_aligned)
(convert WritableXmm ValueRegs writable_xmm_to_value_regs)
;; Note that these conversions will introduce a `movupd` instruction if
;; the memory location is not aligned to a 16-byte boundary. This is primarily
;; used to convert `XmmMem` inputs, which themselves were typically created
;; via the `put_in_xmm_mem` constructor, into operands of SSE instructions.
;; Most pre-AVX instructions working with 16-bytes of data (e.g. full xmm
;; registers) require 16-byte alignment.
(convert XmmMem XmmMemAligned xmm_mem_to_xmm_mem_aligned)
(convert XmmMemImm XmmMemAlignedImm xmm_mem_imm_to_xmm_mem_aligned_imm)
(convert Gpr Imm8Gpr gpr_to_imm8_gpr)
(convert Amode SyntheticAmode amode_to_synthetic_amode)
(convert Amode GprMem amode_to_gpr_mem)
(convert SyntheticAmode GprMem synthetic_amode_to_gpr_mem)
(convert Amode XmmMem amode_to_xmm_mem)
(convert SyntheticAmode XmmMem synthetic_amode_to_xmm_mem)
(convert Amode XmmMemAligned amode_to_xmm_mem_aligned)
(convert SyntheticAmode XmmMemAligned synthetic_amode_to_xmm_mem_aligned)
(convert VCodeConstant SyntheticAmode const_to_synthetic_amode)
(convert VCodeConstant XmmMem const_to_xmm_mem)
(convert VCodeConstant RegMem const_to_reg_mem)
(convert IntCC CC intcc_to_cc)
(convert SinkableLoad RegMem sink_load_to_reg_mem)
(convert SinkableLoad GprMem sink_load_to_gpr_mem)
(convert SinkableLoad RegMemImm sink_load_to_reg_mem_imm)
(convert SinkableLoad GprMemImm sink_load_to_gpr_mem_imm)
(convert SinkableLoad XmmMem sink_load_to_xmm_mem)
(convert SinkableLoad SyntheticAmode sink_load)
(decl reg_to_xmm_mem (Reg) XmmMem)
(rule (reg_to_xmm_mem r)
(xmm_to_xmm_mem (xmm_new r)))
(decl xmm_to_reg_mem (Reg) XmmMem)
(rule (xmm_to_reg_mem r)
(RegMem.Reg (xmm_to_reg r)))
(decl writable_gpr_to_r_reg (WritableGpr) Reg)
(rule (writable_gpr_to_r_reg w_gpr)
(writable_reg_to_reg (writable_gpr_to_reg w_gpr)))
(decl writable_gpr_to_gpr_mem (WritableGpr) GprMem)
(rule (writable_gpr_to_gpr_mem w_gpr)
(gpr_to_gpr_mem w_gpr))
(decl writable_gpr_to_gpr_mem_imm (WritableGpr) GprMemImm)
(rule (writable_gpr_to_gpr_mem_imm w_gpr)
(gpr_to_gpr_mem_imm w_gpr))
(decl writable_gpr_to_value_regs (WritableGpr) ValueRegs)
(rule (writable_gpr_to_value_regs w_gpr)
(value_reg w_gpr))
(decl writable_xmm_to_r_reg (WritableXmm) Reg)
(rule (writable_xmm_to_r_reg w_xmm)
(writable_reg_to_reg (writable_xmm_to_reg w_xmm)))
(decl writable_xmm_to_xmm_mem (WritableXmm) XmmMem)
(rule (writable_xmm_to_xmm_mem w_xmm)
(xmm_to_xmm_mem (writable_xmm_to_xmm w_xmm)))
(decl writable_xmm_to_xmm_mem_aligned (WritableXmm) XmmMemAligned)
(rule (writable_xmm_to_xmm_mem_aligned w_xmm)
(xmm_to_xmm_mem_aligned (writable_xmm_to_xmm w_xmm)))
(decl writable_xmm_to_value_regs (WritableXmm) ValueRegs)
(rule (writable_xmm_to_value_regs w_xmm)
(value_reg w_xmm))
(decl synthetic_amode_to_gpr_mem (SyntheticAmode) GprMem)
(spec (amode_to_gpr_mem amode)
(provide (= result amode)))
(decl amode_to_gpr_mem (Amode) GprMem)
(rule (amode_to_gpr_mem amode)
(amode_to_synthetic_amode amode))
(rule (synthetic_amode_to_gpr_mem amode)
(synthetic_amode_to_reg_mem amode))
(decl amode_to_xmm_mem (Amode) XmmMem)
(rule (amode_to_xmm_mem amode)
(amode_to_synthetic_amode amode))
(decl synthetic_amode_to_xmm_mem (SyntheticAmode) XmmMem)
(rule (synthetic_amode_to_xmm_mem amode)
(synthetic_amode_to_reg_mem amode))
(decl const_to_synthetic_amode (VCodeConstant) SyntheticAmode)
(extern constructor const_to_synthetic_amode const_to_synthetic_amode)
(decl const_to_xmm_mem (VCodeConstant) XmmMem)
(rule (const_to_xmm_mem c) (const_to_synthetic_amode c))
(decl const_to_reg_mem (VCodeConstant) RegMem)
(rule (const_to_reg_mem c) (RegMem.Mem (const_to_synthetic_amode c)))
(decl xmm_to_xmm_mem_aligned (Xmm) XmmMemAligned)
(rule (xmm_to_xmm_mem_aligned reg) (xmm_mem_to_xmm_mem_aligned reg))
(decl amode_to_xmm_mem_aligned (Amode) XmmMemAligned)
(rule (amode_to_xmm_mem_aligned mode) (amode_to_xmm_mem mode))
(decl synthetic_amode_to_xmm_mem_aligned (SyntheticAmode) XmmMemAligned)
(rule (synthetic_amode_to_xmm_mem_aligned mode) (synthetic_amode_to_xmm_mem mode))
(decl put_in_xmm_mem_aligned (Value) XmmMemAligned)
(rule (put_in_xmm_mem_aligned val) (put_in_xmm_mem val))
(decl mov_to_preg (PReg Gpr) SideEffectNoResult)
(rule (mov_to_preg dst src)
(SideEffectNoResult.Inst (MInst.MovToPReg src dst)))
(decl preg_rbp () PReg)
(extern constructor preg_rbp preg_rbp)
(decl preg_rsp () PReg)
(extern constructor preg_rsp preg_rsp)
(decl preg_pinned () PReg)
(extern constructor preg_pinned preg_pinned)
(decl x64_rbp () Reg)
(rule (x64_rbp)
(mov_from_preg (preg_rbp)))
(decl x64_rsp () Reg)
(rule (x64_rsp)
(mov_from_preg (preg_rsp)))
;;;; Helpers for Emitting LibCalls ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
(type LibCall extern
(enum
FmaF32
FmaF64
CeilF32
CeilF64
FloorF32
FloorF64
NearestF32
NearestF64
TruncF32
TruncF64
X86Pshufb))
(decl libcall_1 (LibCall Reg) Reg)
(extern constructor libcall_1 libcall_1)
(decl libcall_2 (LibCall Reg Reg) Reg)
(extern constructor libcall_2 libcall_2)
(decl libcall_3 (LibCall Reg Reg Reg) Reg)
(extern constructor libcall_3 libcall_3)
;; Helper for creating a `SequencePoint` instruction.
(decl x64_sequence_point () SideEffectNoResult)
(rule (x64_sequence_point)
(SideEffectNoResult.Inst (MInst.SequencePoint)))