//===-- GenericOpcodes.td - Opcodes used with GlobalISel ---*- tablegen -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines the generic opcodes used with GlobalISel. // After instruction selection, these opcodes should not appear. // //===----------------------------------------------------------------------===// //------------------------------------------------------------------------------ // Unary ops. //------------------------------------------------------------------------------ class GenericInstruction : StandardPseudoInstruction { let isPreISelOpcode = 1; } // Provide a variant of an instruction with the same operands, but // different instruction flags. This is intended to provide a // convenient way to define strict floating point variants of ordinary // floating point instructions. class ConstrainedIntruction : GenericInstruction { let OutOperandList = baseInst.OutOperandList; let InOperandList = baseInst.InOperandList; let isCommutable = baseInst.isCommutable; // TODO: Do we need a better way to mark reads from FP mode than // hasSideEffects? let hasSideEffects = 1; let mayRaiseFPException = 1; } // Extend the underlying scalar type of an operation, leaving the high bits // unspecified. def G_ANYEXT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } // Sign extend the underlying scalar type of an operation, copying the sign bit // into the newly-created space. def G_SEXT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } // Sign extend the a value from an arbitrary bit position, copying the sign bit // into all bits above it. This is equivalent to a shl + ashr pair with an // appropriate shift amount. $sz is an immediate (MachineOperand::isImm() // returns true) to allow targets to have some bitwidths legal and others // lowered. This opcode is particularly useful if the target has sign-extension // instructions that are cheaper than the constituent shifts as the optimizer is // able to make decisions on whether it's better to hang on to the G_SEXT_INREG // or to lower it and optimize the individual shifts. def G_SEXT_INREG : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src, untyped_imm_0:$sz); let hasSideEffects = 0; } // Zero extend the underlying scalar type of an operation, putting zero bits // into the newly-created space. def G_ZEXT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } // Truncate the underlying scalar type of an operation. This is equivalent to // G_EXTRACT for scalar types, but acts elementwise on vectors. def G_TRUNC : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_IMPLICIT_DEF : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins); let hasSideEffects = 0; } def G_PHI : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins variable_ops); let hasSideEffects = 0; } def G_FRAME_INDEX : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$src2); let hasSideEffects = 0; } def G_GLOBAL_VALUE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$src); let hasSideEffects = 0; } def G_INTTOPTR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_PTRTOINT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_BITCAST : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } // Only supports scalar result types def G_CONSTANT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$imm); let hasSideEffects = 0; } // Only supports scalar result types def G_FCONSTANT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$imm); let hasSideEffects = 0; } def G_VASTART : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins type0:$list); let hasSideEffects = 0; let mayStore = 1; } def G_VAARG : GenericInstruction { let OutOperandList = (outs type0:$val); let InOperandList = (ins type1:$list, unknown:$align); let hasSideEffects = 0; let mayLoad = 1; let mayStore = 1; } def G_CTLZ : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_CTLZ_ZERO_UNDEF : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_CTTZ : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_CTTZ_ZERO_UNDEF : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_CTPOP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_BSWAP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } def G_BITREVERSE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } def G_ADDRSPACE_CAST : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_BLOCK_ADDR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$ba); let hasSideEffects = 0; } def G_JUMP_TABLE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$jti); let hasSideEffects = 0; } def G_DYN_STACKALLOC : GenericInstruction { let OutOperandList = (outs ptype0:$dst); let InOperandList = (ins type1:$size, i32imm:$align); let hasSideEffects = 1; } def G_FREEZE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } //------------------------------------------------------------------------------ // Binary ops. //------------------------------------------------------------------------------ // Generic addition. def G_ADD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic subtraction. def G_SUB : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic multiplication. def G_MUL : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic signed division. def G_SDIV : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic unsigned division. def G_UDIV : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic signed remainder. def G_SREM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic unsigned remainder. def G_UREM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic bitwise and. def G_AND : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic bitwise or. def G_OR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic bitwise xor. def G_XOR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic left-shift. def G_SHL : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type1:$src2); let hasSideEffects = 0; } // Generic logical right-shift. def G_LSHR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type1:$src2); let hasSideEffects = 0; } // Generic arithmetic right-shift. def G_ASHR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type1:$src2); let hasSideEffects = 0; } /// Funnel 'double' shifts take 3 operands, 2 inputs and the shift amount. /// fshl(X,Y,Z): (X << (Z % bitwidth)) | (Y >> (bitwidth - (Z % bitwidth))) def G_FSHL : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2, type1:$src3); let hasSideEffects = 0; } /// Funnel 'double' shifts take 3 operands, 2 inputs and the shift amount. /// fshr(X,Y,Z): (X << (bitwidth - (Z % bitwidth))) | (Y >> (Z % bitwidth)) def G_FSHR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2, type1:$src3); let hasSideEffects = 0; } // Generic integer comparison. def G_ICMP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$tst, type1:$src1, type1:$src2); let hasSideEffects = 0; } // Generic floating-point comparison. def G_FCMP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$tst, type1:$src1, type1:$src2); let hasSideEffects = 0; } // Generic select def G_SELECT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$tst, type0:$src1, type0:$src2); let hasSideEffects = 0; } // Generic pointer offset. def G_PTR_ADD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type1:$src2); let hasSideEffects = 0; } // Generic pointer mask. type1 should be an integer with the same // bitwidth as the pointer type. def G_PTRMASK : GenericInstruction { let OutOperandList = (outs ptype0:$dst); let InOperandList = (ins ptype0:$src, type1:$bits); let hasSideEffects = 0; } // Generic signed integer minimum. def G_SMIN : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic signed integer maximum. def G_SMAX : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic unsigned integer minimum. def G_UMIN : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic unsigned integer maximum. def G_UMAX : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } //------------------------------------------------------------------------------ // Overflow ops //------------------------------------------------------------------------------ // Generic unsigned addition producing a carry flag. def G_UADDO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic unsigned addition consuming and producing a carry flag. def G_UADDE : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2, type1:$carry_in); let hasSideEffects = 0; } // Generic signed addition producing a carry flag. def G_SADDO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic signed addition consuming and producing a carry flag. def G_SADDE : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2, type1:$carry_in); let hasSideEffects = 0; } // Generic unsigned subtraction producing a carry flag. def G_USUBO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; } // Generic unsigned subtraction consuming and producing a carry flag. def G_USUBE : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2, type1:$carry_in); let hasSideEffects = 0; } // Generic signed subtraction producing a carry flag. def G_SSUBO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; } // Generic signed subtraction consuming and producing a carry flag. def G_SSUBE : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2, type1:$carry_in); let hasSideEffects = 0; } // Generic unsigned multiplication producing a carry flag. def G_UMULO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic signed multiplication producing a carry flag. def G_SMULO : GenericInstruction { let OutOperandList = (outs type0:$dst, type1:$carry_out); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Multiply two numbers at twice the incoming bit width (unsigned) and return // the high half of the result. def G_UMULH : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Multiply two numbers at twice the incoming bit width (signed) and return // the high half of the result. def G_SMULH : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } //------------------------------------------------------------------------------ // Saturating ops //------------------------------------------------------------------------------ // Generic saturating unsigned addition. def G_UADDSAT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic saturating signed addition. def G_SADDSAT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic saturating unsigned subtraction. def G_USUBSAT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic saturating signed subtraction. def G_SSUBSAT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } //------------------------------------------------------------------------------ // Floating Point Unary Ops. //------------------------------------------------------------------------------ def G_FNEG : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } def G_FPEXT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_FPTRUNC : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_FPTOSI : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_FPTOUI : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_SITOFP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_UITOFP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } def G_FABS : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } def G_FCOPYSIGN : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src0, type1:$src1); let hasSideEffects = 0; } def G_FCANONICALIZE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src); let hasSideEffects = 0; } // FMINNUM/FMAXNUM - Perform floating-point minimum or maximum on two // values. // // In the case where a single input is a NaN (either signaling or quiet), // the non-NaN input is returned. // // The return value of (FMINNUM 0.0, -0.0) could be either 0.0 or -0.0. def G_FMINNUM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } def G_FMAXNUM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // FMINNUM_IEEE/FMAXNUM_IEEE - Perform floating-point minimum or maximum on // two values, following the IEEE-754 2008 definition. This differs from // FMINNUM/FMAXNUM in the handling of signaling NaNs. If one input is a // signaling NaN, returns a quiet NaN. def G_FMINNUM_IEEE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } def G_FMAXNUM_IEEE : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // FMINIMUM/FMAXIMUM - NaN-propagating minimum/maximum that also treat -0.0 // as less than 0.0. While FMINNUM_IEEE/FMAXNUM_IEEE follow IEEE 754-2008 // semantics, FMINIMUM/FMAXIMUM follow IEEE 754-2018 draft semantics. def G_FMINIMUM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } def G_FMAXIMUM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } //------------------------------------------------------------------------------ // Floating Point Binary ops. //------------------------------------------------------------------------------ // Generic FP addition. def G_FADD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic FP subtraction. def G_FSUB : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 0; } // Generic FP multiplication. def G_FMUL : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; let isCommutable = 1; } // Generic fused multiply-add instruction. // Behaves like llvm fma intrinsic ie src1 * src2 + src3 def G_FMA : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2, type0:$src3); let hasSideEffects = 0; let isCommutable = 0; } /// Generic FP multiply and add. Perform a * b + c, while getting the /// same result as the separately rounded operations, unlike G_FMA. def G_FMAD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2, type0:$src3); let hasSideEffects = 0; let isCommutable = 0; } // Generic FP division. def G_FDIV : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; } // Generic FP remainder. def G_FREM : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; } // Floating point exponentiation. def G_FPOW : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1, type0:$src2); let hasSideEffects = 0; } // Floating point base-e exponential of a value. def G_FEXP : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point base-2 exponential of a value. def G_FEXP2 : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point base-e logarithm of a value. def G_FLOG : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point base-2 logarithm of a value. def G_FLOG2 : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point base-10 logarithm of a value. def G_FLOG10 : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point ceiling of a value. def G_FCEIL : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point cosine of a value. def G_FCOS : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point sine of a value. def G_FSIN : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point square root of a value. // This returns NaN for negative nonzero values. // NOTE: Unlike libm sqrt(), this never sets errno. In all other respects it's // libm-conformant. def G_FSQRT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point floor of a value. def G_FFLOOR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point round to next integer. def G_FRINT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } // Floating point round to the nearest integer. def G_FNEARBYINT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } //------------------------------------------------------------------------------ // Opcodes for LLVM Intrinsics //------------------------------------------------------------------------------ def G_INTRINSIC_TRUNC : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } def G_INTRINSIC_ROUND : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; } def G_READCYCLECOUNTER : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins); let hasSideEffects = 1; } //------------------------------------------------------------------------------ // Memory ops //------------------------------------------------------------------------------ // Generic load. Expects a MachineMemOperand in addition to explicit // operands. If the result size is larger than the memory size, the // high bits are undefined. If the result is a vector type and larger // than the memory size, the high elements are undefined (i.e. this is // not a per-element, vector anyextload) def G_LOAD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins ptype1:$addr); let hasSideEffects = 0; let mayLoad = 1; } // Generic sign-extended load. Expects a MachineMemOperand in addition to explicit operands. def G_SEXTLOAD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins ptype1:$addr); let hasSideEffects = 0; let mayLoad = 1; } // Generic zero-extended load. Expects a MachineMemOperand in addition to explicit operands. def G_ZEXTLOAD : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins ptype1:$addr); let hasSideEffects = 0; let mayLoad = 1; } // Generic indexed load. Combines a GEP with a load. $newaddr is set to $base + $offset. // If $am is 0 (post-indexed), then the value is loaded from $base; if $am is 1 (pre-indexed) // then the value is loaded from $newaddr. def G_INDEXED_LOAD : GenericInstruction { let OutOperandList = (outs type0:$dst, ptype1:$newaddr); let InOperandList = (ins ptype1:$base, type2:$offset, unknown:$am); let hasSideEffects = 0; let mayLoad = 1; } // Same as G_INDEXED_LOAD except that the load performed is sign-extending, as with G_SEXTLOAD. def G_INDEXED_SEXTLOAD : GenericInstruction { let OutOperandList = (outs type0:$dst, ptype1:$newaddr); let InOperandList = (ins ptype1:$base, type2:$offset, unknown:$am); let hasSideEffects = 0; let mayLoad = 1; } // Same as G_INDEXED_LOAD except that the load performed is zero-extending, as with G_ZEXTLOAD. def G_INDEXED_ZEXTLOAD : GenericInstruction { let OutOperandList = (outs type0:$dst, ptype1:$newaddr); let InOperandList = (ins ptype1:$base, type2:$offset, unknown:$am); let hasSideEffects = 0; let mayLoad = 1; } // Generic store. Expects a MachineMemOperand in addition to explicit operands. def G_STORE : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins type0:$src, ptype1:$addr); let hasSideEffects = 0; let mayStore = 1; } // Combines a store with a GEP. See description of G_INDEXED_LOAD for indexing behaviour. def G_INDEXED_STORE : GenericInstruction { let OutOperandList = (outs ptype0:$newaddr); let InOperandList = (ins type1:$src, ptype0:$base, ptype2:$offset, unknown:$am); let hasSideEffects = 0; let mayStore = 1; } // Generic atomic cmpxchg with internal success check. Expects a // MachineMemOperand in addition to explicit operands. def G_ATOMIC_CMPXCHG_WITH_SUCCESS : GenericInstruction { let OutOperandList = (outs type0:$oldval, type1:$success); let InOperandList = (ins type2:$addr, type0:$cmpval, type0:$newval); let hasSideEffects = 0; let mayLoad = 1; let mayStore = 1; } // Generic atomic cmpxchg. Expects a MachineMemOperand in addition to explicit // operands. def G_ATOMIC_CMPXCHG : GenericInstruction { let OutOperandList = (outs type0:$oldval); let InOperandList = (ins ptype1:$addr, type0:$cmpval, type0:$newval); let hasSideEffects = 0; let mayLoad = 1; let mayStore = 1; } // Generic atomicrmw. Expects a MachineMemOperand in addition to explicit // operands. class G_ATOMICRMW_OP : GenericInstruction { let OutOperandList = (outs type0:$oldval); let InOperandList = (ins ptype1:$addr, type0:$val); let hasSideEffects = 0; let mayLoad = 1; let mayStore = 1; } def G_ATOMICRMW_XCHG : G_ATOMICRMW_OP; def G_ATOMICRMW_ADD : G_ATOMICRMW_OP; def G_ATOMICRMW_SUB : G_ATOMICRMW_OP; def G_ATOMICRMW_AND : G_ATOMICRMW_OP; def G_ATOMICRMW_NAND : G_ATOMICRMW_OP; def G_ATOMICRMW_OR : G_ATOMICRMW_OP; def G_ATOMICRMW_XOR : G_ATOMICRMW_OP; def G_ATOMICRMW_MAX : G_ATOMICRMW_OP; def G_ATOMICRMW_MIN : G_ATOMICRMW_OP; def G_ATOMICRMW_UMAX : G_ATOMICRMW_OP; def G_ATOMICRMW_UMIN : G_ATOMICRMW_OP; def G_ATOMICRMW_FADD : G_ATOMICRMW_OP; def G_ATOMICRMW_FSUB : G_ATOMICRMW_OP; def G_FENCE : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins i32imm:$ordering, i32imm:$scope); let hasSideEffects = 1; } //------------------------------------------------------------------------------ // Variadic ops //------------------------------------------------------------------------------ // Extract a register of the specified size, starting from the block given by // index. This will almost certainly be mapped to sub-register COPYs after // register banks have been selected. def G_EXTRACT : GenericInstruction { let OutOperandList = (outs type0:$res); let InOperandList = (ins type1:$src, untyped_imm_0:$offset); let hasSideEffects = 0; } // Extract multiple registers specified size, starting from blocks given by // indexes. This will almost certainly be mapped to sub-register COPYs after // register banks have been selected. // The output operands are always ordered from lowest bits to highest: // %bits_0_7:(s8), %bits_8_15:(s8), // %bits_16_23:(s8), %bits_24_31:(s8) = G_UNMERGE_VALUES %0:(s32) def G_UNMERGE_VALUES : GenericInstruction { let OutOperandList = (outs type0:$dst0, variable_ops); let InOperandList = (ins type1:$src); let hasSideEffects = 0; } // Insert a smaller register into a larger one at the specified bit-index. def G_INSERT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src, type1:$op, untyped_imm_0:$offset); let hasSideEffects = 0; } // Concatenate multiple registers of the same size into a wider register. // The input operands are always ordered from lowest bits to highest: // %0:(s32) = G_MERGE_VALUES %bits_0_7:(s8), %bits_8_15:(s8), // %bits_16_23:(s8), %bits_24_31:(s8) def G_MERGE_VALUES : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src0, variable_ops); let hasSideEffects = 0; } /// Create a vector from multiple scalar registers. No implicit /// conversion is performed (i.e. the result element type must be the /// same as all source operands) def G_BUILD_VECTOR : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src0, variable_ops); let hasSideEffects = 0; } /// Like G_BUILD_VECTOR, but truncates the larger operand types to fit the /// destination vector elt type. def G_BUILD_VECTOR_TRUNC : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src0, variable_ops); let hasSideEffects = 0; } /// Create a vector by concatenating vectors together. def G_CONCAT_VECTORS : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src0, variable_ops); let hasSideEffects = 0; } // Intrinsic without side effects. def G_INTRINSIC : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins unknown:$intrin, variable_ops); let hasSideEffects = 0; // Conservatively assume this is convergent. If there turnes out to // be a need, there should be separate convergent intrinsic opcode.s let isConvergent = 1; } // Intrinsic with side effects. def G_INTRINSIC_W_SIDE_EFFECTS : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins unknown:$intrin, variable_ops); let hasSideEffects = 1; let mayLoad = 1; let mayStore = 1; // Conservatively assume this is convergent. If there turnes out to // be a need, there should be separate convergent intrinsic opcode.s let isConvergent = 1; } //------------------------------------------------------------------------------ // Branches. //------------------------------------------------------------------------------ // Generic unconditional branch. def G_BR : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins unknown:$src1); let hasSideEffects = 0; let isBranch = 1; let isTerminator = 1; let isBarrier = 1; } // Generic conditional branch. def G_BRCOND : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins type0:$tst, unknown:$truebb); let hasSideEffects = 0; let isBranch = 1; let isTerminator = 1; } // Generic indirect branch. def G_BRINDIRECT : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins type0:$src1); let hasSideEffects = 0; let isBranch = 1; let isTerminator = 1; let isBarrier = 1; let isIndirectBranch = 1; } // Generic branch to jump table entry def G_BRJT : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins ptype0:$tbl, unknown:$jti, type1:$idx); let hasSideEffects = 0; let isBranch = 1; let isTerminator = 1; let isBarrier = 1; let isIndirectBranch = 1; } def G_READ_REGISTER : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins unknown:$register); let hasSideEffects = 1; // Assume convergent. It's probably not worth the effort of somehow // modeling convergent and nonconvergent register accesses. let isConvergent = 1; } def G_WRITE_REGISTER : GenericInstruction { let OutOperandList = (outs); let InOperandList = (ins unknown:$register, type0:$value); let hasSideEffects = 1; // Assume convergent. It's probably not worth the effort of somehow // modeling convergent and nonconvergent register accesses. let isConvergent = 1; } //------------------------------------------------------------------------------ // Vector ops //------------------------------------------------------------------------------ // Generic insertelement. def G_INSERT_VECTOR_ELT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type0:$src, type1:$elt, type2:$idx); let hasSideEffects = 0; } // Generic extractelement. def G_EXTRACT_VECTOR_ELT : GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$src, type2:$idx); let hasSideEffects = 0; } // Generic shufflevector. // // The mask operand should be an IR Constant which exactly matches the // corresponding mask for the IR shufflevector instruction. def G_SHUFFLE_VECTOR: GenericInstruction { let OutOperandList = (outs type0:$dst); let InOperandList = (ins type1:$v1, type1:$v2, unknown:$mask); let hasSideEffects = 0; } //------------------------------------------------------------------------------ // Constrained floating point ops //------------------------------------------------------------------------------ def G_STRICT_FADD : ConstrainedIntruction; def G_STRICT_FSUB : ConstrainedIntruction; def G_STRICT_FMUL : ConstrainedIntruction; def G_STRICT_FDIV : ConstrainedIntruction; def G_STRICT_FREM : ConstrainedIntruction; def G_STRICT_FMA : ConstrainedIntruction; def G_STRICT_FSQRT : ConstrainedIntruction;