//===-- SIInstrInfo.td - SI Instruction Infos -------------*- tablegen -*--===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // Execpt for the NONE field, this must be kept in sync with the SISubtarget enum // in AMDGPUMCInstLower.h def SISubtarget { int NONE = -1; int SI = 0; } //===----------------------------------------------------------------------===// // SI DAG Nodes //===----------------------------------------------------------------------===// def SIload_constant : SDNode<"AMDGPUISD::LOAD_CONSTANT", SDTypeProfile<1, 2, [SDTCisVT<0, f32>, SDTCisVT<1, v4i32>, SDTCisVT<2, i32>]>, [SDNPMayLoad, SDNPMemOperand] >; def SItbuffer_store : SDNode<"AMDGPUISD::TBUFFER_STORE_FORMAT", SDTypeProfile<0, 13, [SDTCisVT<0, v4i32>, // rsrc(SGPR) SDTCisVT<1, iAny>, // vdata(VGPR) SDTCisVT<2, i32>, // num_channels(imm) SDTCisVT<3, i32>, // vaddr(VGPR) SDTCisVT<4, i32>, // soffset(SGPR) SDTCisVT<5, i32>, // inst_offset(imm) SDTCisVT<6, i32>, // dfmt(imm) SDTCisVT<7, i32>, // nfmt(imm) SDTCisVT<8, i32>, // offen(imm) SDTCisVT<9, i32>, // idxen(imm) SDTCisVT<10, i32>, // glc(imm) SDTCisVT<11, i32>, // slc(imm) SDTCisVT<12, i32> // tfe(imm) ]>, [SDNPMayStore, SDNPMemOperand, SDNPHasChain] >; def SIload_input : SDNode<"AMDGPUISD::LOAD_INPUT", SDTypeProfile<1, 3, [SDTCisVT<0, v4f32>, SDTCisVT<1, v4i32>, SDTCisVT<2, i16>, SDTCisVT<3, i32>]> >; class SDSample : SDNode , SDTCisVT<2, v32i8>, SDTCisVT<3, v4i32>, SDTCisVT<4, i32>]> >; def SIsample : SDSample<"AMDGPUISD::SAMPLE">; def SIsampleb : SDSample<"AMDGPUISD::SAMPLEB">; def SIsampled : SDSample<"AMDGPUISD::SAMPLED">; def SIsamplel : SDSample<"AMDGPUISD::SAMPLEL">; def SIconstdata_ptr : SDNode< "AMDGPUISD::CONST_DATA_PTR", SDTypeProfile <1, 0, [SDTCisVT<0, i64>]> >; // Transformation function, extract the lower 32bit of a 64bit immediate def LO32 : SDNodeXFormgetTargetConstant(N->getZExtValue() & 0xffffffff, MVT::i32); }]>; def LO32f : SDNodeXFormgetValueAPF().bitcastToAPInt().trunc(32); return CurDAG->getTargetConstantFP(APFloat(APFloat::IEEEsingle, V), MVT::f32); }]>; // Transformation function, extract the upper 32bit of a 64bit immediate def HI32 : SDNodeXFormgetTargetConstant(N->getZExtValue() >> 32, MVT::i32); }]>; def HI32f : SDNodeXFormgetValueAPF().bitcastToAPInt().lshr(32).trunc(32); return CurDAG->getTargetConstantFP(APFloat(APFloat::IEEEsingle, V), MVT::f32); }]>; def IMM8bitDWORD : PatLeaf <(imm), [{return (N->getZExtValue() & ~0x3FC) == 0;}] >; def as_dword_i32imm : SDNodeXFormgetTargetConstant(N->getZExtValue() >> 2, MVT::i32); }]>; def as_i1imm : SDNodeXFormgetTargetConstant(N->getZExtValue(), MVT::i1); }]>; def as_i8imm : SDNodeXFormgetTargetConstant(N->getZExtValue(), MVT::i8); }]>; def as_i16imm : SDNodeXFormgetTargetConstant(N->getSExtValue(), MVT::i16); }]>; def as_i32imm: SDNodeXFormgetTargetConstant(N->getSExtValue(), MVT::i32); }]>; def IMM8bit : PatLeaf <(imm), [{return isUInt<8>(N->getZExtValue());}] >; def IMM12bit : PatLeaf <(imm), [{return isUInt<12>(N->getZExtValue());}] >; def IMM16bit : PatLeaf <(imm), [{return isUInt<16>(N->getZExtValue());}] >; def IMM32bit : PatLeaf <(imm), [{return isUInt<32>(N->getZExtValue());}] >; def mubuf_vaddr_offset : PatFrag< (ops node:$ptr, node:$offset, node:$imm_offset), (add (add node:$ptr, node:$offset), node:$imm_offset) >; class InlineImm : PatLeaf <(vt imm), [{ return isInlineImmediate(N); }]>; class SGPRImm : PatLeaf().getGeneration() < AMDGPUSubtarget::SOUTHERN_ISLANDS) { return false; } const SIRegisterInfo *SIRI = static_cast(TM.getSubtargetImpl()->getRegisterInfo()); for (SDNode::use_iterator U = N->use_begin(), E = SDNode::use_end(); U != E; ++U) { if (SIRI->isSGPRClass(getOperandRegClass(*U, U.getOperandNo()))) { return true; } } return false; }]>; //===----------------------------------------------------------------------===// // Custom Operands //===----------------------------------------------------------------------===// def FRAMEri32 : Operand { let MIOperandInfo = (ops i32:$ptr, i32imm:$index); } def sopp_brtarget : Operand { let EncoderMethod = "getSOPPBrEncoding"; let OperandType = "OPERAND_PCREL"; } include "SIInstrFormats.td" let OperandType = "OPERAND_IMMEDIATE" in { def offen : Operand { let PrintMethod = "printOffen"; } def idxen : Operand { let PrintMethod = "printIdxen"; } def addr64 : Operand { let PrintMethod = "printAddr64"; } def mbuf_offset : Operand { let PrintMethod = "printMBUFOffset"; } def glc : Operand { let PrintMethod = "printGLC"; } def slc : Operand { let PrintMethod = "printSLC"; } def tfe : Operand { let PrintMethod = "printTFE"; } } // End OperandType = "OPERAND_IMMEDIATE" //===----------------------------------------------------------------------===// // Complex patterns //===----------------------------------------------------------------------===// def DS1Addr1Offset : ComplexPattern; def DS64Bit4ByteAligned : ComplexPattern; def MUBUFAddr32 : ComplexPattern; def MUBUFAddr64 : ComplexPattern; def MUBUFScratch : ComplexPattern; def MUBUFOffset : ComplexPattern; def VOP3Mods0 : ComplexPattern; def VOP3Mods : ComplexPattern; //===----------------------------------------------------------------------===// // SI assembler operands //===----------------------------------------------------------------------===// def SIOperand { int ZERO = 0x80; int VCC = 0x6A; int FLAT_SCR = 0x68; } def SRCMODS { int NONE = 0; } def DSTCLAMP { int NONE = 0; } def DSTOMOD { int NONE = 0; } //===----------------------------------------------------------------------===// // // SI Instruction multiclass helpers. // // Instructions with _32 take 32-bit operands. // Instructions with _64 take 64-bit operands. // // VOP_* instructions can use either a 32-bit or 64-bit encoding. The 32-bit // encoding is the standard encoding, but instruction that make use of // any of the instruction modifiers must use the 64-bit encoding. // // Instructions with _e32 use the 32-bit encoding. // Instructions with _e64 use the 64-bit encoding. // //===----------------------------------------------------------------------===// //===----------------------------------------------------------------------===// // Scalar classes //===----------------------------------------------------------------------===// class SOP1_32 op, string opName, list pattern> : SOP1 < op, (outs SReg_32:$dst), (ins SSrc_32:$src0), opName#" $dst, $src0", pattern >; class SOP1_64 op, string opName, list pattern> : SOP1 < op, (outs SReg_64:$dst), (ins SSrc_64:$src0), opName#" $dst, $src0", pattern >; // 64-bit input, 32-bit output. class SOP1_32_64 op, string opName, list pattern> : SOP1 < op, (outs SReg_32:$dst), (ins SSrc_64:$src0), opName#" $dst, $src0", pattern >; class SOP2_32 op, string opName, list pattern> : SOP2 < op, (outs SReg_32:$dst), (ins SSrc_32:$src0, SSrc_32:$src1), opName#" $dst, $src0, $src1", pattern >; class SOP2_64 op, string opName, list pattern> : SOP2 < op, (outs SReg_64:$dst), (ins SSrc_64:$src0, SSrc_64:$src1), opName#" $dst, $src0, $src1", pattern >; class SOP2_SHIFT_64 op, string opName, list pattern> : SOP2 < op, (outs SReg_64:$dst), (ins SSrc_64:$src0, SSrc_32:$src1), opName#" $dst, $src0, $src1", pattern >; class SOPC_Helper op, RegisterClass rc, ValueType vt, string opName, PatLeaf cond> : SOPC < op, (outs SCCReg:$dst), (ins rc:$src0, rc:$src1), opName#" $dst, $src0, $src1", []>; class SOPC_32 op, string opName, PatLeaf cond = COND_NULL> : SOPC_Helper; class SOPC_64 op, string opName, PatLeaf cond = COND_NULL> : SOPC_Helper; class SOPK_32 op, string opName, list pattern> : SOPK < op, (outs SReg_32:$dst), (ins i16imm:$src0), opName#" $dst, $src0", pattern >; class SOPK_64 op, string opName, list pattern> : SOPK < op, (outs SReg_64:$dst), (ins i16imm:$src0), opName#" $dst, $src0", pattern >; multiclass SMRD_Helper op, string asm, RegisterClass baseClass, RegisterClass dstClass> { def _IMM : SMRD < op, 1, (outs dstClass:$dst), (ins baseClass:$sbase, u32imm:$offset), asm#" $dst, $sbase, $offset", [] >; def _SGPR : SMRD < op, 0, (outs dstClass:$dst), (ins baseClass:$sbase, SReg_32:$soff), asm#" $dst, $sbase, $soff", [] >; } //===----------------------------------------------------------------------===// // Vector ALU classes //===----------------------------------------------------------------------===// // This must always be right before the operand being input modified. def InputMods : OperandWithDefaultOps { let PrintMethod = "printOperandAndMods"; } def InputModsNoDefault : Operand { let PrintMethod = "printOperandAndMods"; } class getNumSrcArgs { int ret = !if (!eq(Src1.Value, untyped.Value), 1, // VOP1 !if (!eq(Src2.Value, untyped.Value), 2, // VOP2 3)); // VOP3 } // Returns the register class to use for the destination of VOP[123C] // instructions for the given VT. class getVALUDstForVT { RegisterClass ret = !if(!eq(VT.Size, 32), VReg_32, VReg_64); } // Returns the register class to use for source 0 of VOP[12C] // instructions for the given VT. class getVOPSrc0ForVT { RegisterClass ret = !if(!eq(VT.Size, 32), VSrc_32, VSrc_64); } // Returns the register class to use for source 1 of VOP[12C] for the // given VT. class getVOPSrc1ForVT { RegisterClass ret = !if(!eq(VT.Size, 32), VReg_32, VReg_64); } // Returns the register classes for the source arguments of a VOP[12C] // instruction for the given SrcVTs. class getInRC32 SrcVT> { list ret = [ getVOPSrc0ForVT.ret, getVOPSrc1ForVT.ret ]; } // Returns the register class to use for sources of VOP3 instructions for the // given VT. class getVOP3SrcForVT { RegisterClass ret = !if(!eq(VT.Size, 32), VSrc_32, VSrc_64); } // Returns the register classes for the source arguments of a VOP3 // instruction for the given SrcVTs. class getInRC64 SrcVT> { list ret = [ getVOP3SrcForVT.ret, getVOP3SrcForVT.ret, getVOP3SrcForVT.ret ]; } // Returns 1 if the source arguments have modifiers, 0 if they do not. class hasModifiers { bit ret = !if(!eq(SrcVT.Value, f32.Value), 1, !if(!eq(SrcVT.Value, f64.Value), 1, 0)); } // Returns the input arguments for VOP[12C] instructions for the given SrcVT. class getIns32 { dag ret = !if(!eq(NumSrcArgs, 1), (ins Src0RC:$src0), // VOP1 !if(!eq(NumSrcArgs, 2), (ins Src0RC:$src0, Src1RC:$src1), // VOP2 (ins))); } // Returns the input arguments for VOP3 instructions for the given SrcVT. class getIns64 { dag ret = !if (!eq(NumSrcArgs, 1), !if (!eq(HasModifiers, 1), // VOP1 with modifiers (ins InputModsNoDefault:$src0_modifiers, Src0RC:$src0, i32imm:$clamp, i32imm:$omod) /* else */, // VOP1 without modifiers (ins Src0RC:$src0) /* endif */ ), !if (!eq(NumSrcArgs, 2), !if (!eq(HasModifiers, 1), // VOP 2 with modifiers (ins InputModsNoDefault:$src0_modifiers, Src0RC:$src0, InputModsNoDefault:$src1_modifiers, Src1RC:$src1, i32imm:$clamp, i32imm:$omod) /* else */, // VOP2 without modifiers (ins Src0RC:$src0, Src1RC:$src1) /* endif */ ) /* NumSrcArgs == 3 */, !if (!eq(HasModifiers, 1), // VOP3 with modifiers (ins InputModsNoDefault:$src0_modifiers, Src0RC:$src0, InputModsNoDefault:$src1_modifiers, Src1RC:$src1, InputModsNoDefault:$src2_modifiers, Src2RC:$src2, i32imm:$clamp, i32imm:$omod) /* else */, // VOP3 without modifiers (ins Src0RC:$src0, Src1RC:$src1, Src2RC:$src2) /* endif */ ))); } // Returns the assembly string for the inputs and outputs of a VOP[12C] // instruction. This does not add the _e32 suffix, so it can be reused // by getAsm64. class getAsm32 { string src1 = ", $src1"; string src2 = ", $src2"; string ret = " $dst, $src0"# !if(!eq(NumSrcArgs, 1), "", src1)# !if(!eq(NumSrcArgs, 3), src2, ""); } // Returns the assembly string for the inputs and outputs of a VOP3 // instruction. class getAsm64 { string src0 = "$src0_modifiers,"; string src1 = !if(!eq(NumSrcArgs, 1), "", " $src1_modifiers,"); string src2 = !if(!eq(NumSrcArgs, 3), " $src2_modifiers,", ""); string ret = !if(!eq(HasModifiers, 0), getAsm32.ret, " $dst, "#src0#src1#src2#" $clamp, $omod"); } class VOPProfile _ArgVT> { field list ArgVT = _ArgVT; field ValueType DstVT = ArgVT[0]; field ValueType Src0VT = ArgVT[1]; field ValueType Src1VT = ArgVT[2]; field ValueType Src2VT = ArgVT[3]; field RegisterClass DstRC = getVALUDstForVT.ret; field RegisterClass Src0RC32 = getVOPSrc0ForVT.ret; field RegisterClass Src1RC32 = getVOPSrc1ForVT.ret; field RegisterClass Src0RC64 = getVOP3SrcForVT.ret; field RegisterClass Src1RC64 = getVOP3SrcForVT.ret; field RegisterClass Src2RC64 = getVOP3SrcForVT.ret; field int NumSrcArgs = getNumSrcArgs.ret; field bit HasModifiers = hasModifiers.ret; field dag Outs = (outs DstRC:$dst); field dag Ins32 = getIns32.ret; field dag Ins64 = getIns64.ret; field string Asm32 = "_e32"#getAsm32.ret; field string Asm64 = getAsm64.ret; } def VOP_F32_F32 : VOPProfile <[f32, f32, untyped, untyped]>; def VOP_F32_F64 : VOPProfile <[f32, f64, untyped, untyped]>; def VOP_F32_I32 : VOPProfile <[f32, i32, untyped, untyped]>; def VOP_F64_F32 : VOPProfile <[f64, f32, untyped, untyped]>; def VOP_F64_F64 : VOPProfile <[f64, f64, untyped, untyped]>; def VOP_F64_I32 : VOPProfile <[f64, i32, untyped, untyped]>; def VOP_I32_F32 : VOPProfile <[i32, f32, untyped, untyped]>; def VOP_I32_F64 : VOPProfile <[i32, f64, untyped, untyped]>; def VOP_I32_I32 : VOPProfile <[i32, i32, untyped, untyped]>; def VOP_F32_F32_F32 : VOPProfile <[f32, f32, f32, untyped]>; def VOP_F32_F32_I32 : VOPProfile <[f32, f32, i32, untyped]>; def VOP_F64_F64_F64 : VOPProfile <[f64, f64, f64, untyped]>; def VOP_F64_F64_I32 : VOPProfile <[f64, f64, i32, untyped]>; def VOP_I32_F32_F32 : VOPProfile <[i32, f32, f32, untyped]>; def VOP_I32_I32_I32 : VOPProfile <[i32, i32, i32, untyped]>; def VOP_I32_I32_I32_VCC : VOPProfile <[i32, i32, i32, untyped]> { let Src0RC32 = VReg_32; } def VOP_I64_I64_I32 : VOPProfile <[i64, i64, i32, untyped]>; def VOP_I64_I64_I64 : VOPProfile <[i64, i64, i64, untyped]>; def VOP_F32_F32_F32_F32 : VOPProfile <[f32, f32, f32, f32]>; def VOP_F64_F64_F64_F64 : VOPProfile <[f64, f64, f64, f64]>; def VOP_I32_I32_I32_I32 : VOPProfile <[i32, i32, i32, i32]>; def VOP_I64_I32_I32_I64 : VOPProfile <[i64, i32, i32, i64]>; class VOP { string OpName = opName; } class VOP2_REV { string RevOp = revOp; bit IsOrig = isOrig; } class AtomicNoRet { string NoRetOp = noRetOp; bit IsRet = isRet; } class SIMCInstr { string PseudoInstr = pseudo; int Subtarget = subtarget; } class VOP3DisableFields { bits<2> src0_modifiers = !if(HasModifiers, ?, 0); bits<2> src1_modifiers = !if(HasModifiers, !if(HasSrc1, ?, 0), 0); bits<2> src2_modifiers = !if(HasModifiers, !if(HasSrc2, ? ,0) ,0); bits<2> omod = !if(HasModifiers, ?, 0); bits<1> clamp = !if(HasModifiers, ?, 0); bits<9> src1 = !if(HasSrc1, ?, 0); bits<9> src2 = !if(HasSrc2, ?, 0); } class VOP3_Pseudo pattern, string opName> : VOP3Common , VOP , SIMCInstr { let isPseudo = 1; } class VOP3_Real_si op, dag outs, dag ins, string asm, string opName> : VOP3 , SIMCInstr; multiclass VOP3_m op, dag outs, dag ins, string asm, list pattern, string opName, int NumSrcArgs, bit HasMods = 1> { def "" : VOP3_Pseudo ; def _si : VOP3_Real_si , VOP3DisableFields; } multiclass VOP3_1_m op, dag outs, dag ins, string asm, list pattern, string opName, bit HasMods = 1> { def "" : VOP3_Pseudo ; def _si : VOP3_Real_si < {1, 1, op{6}, op{5}, op{4}, op{3}, op{2}, op{1}, op{0}}, outs, ins, asm, opName>, VOP3DisableFields<0, 0, HasMods>; } multiclass VOP3_2_m op, dag outs, dag ins, string asm, list pattern, string opName, string revOp, bit HasMods = 1, bit UseFullOp = 0> { def "" : VOP3_Pseudo , VOP2_REV; def _si : VOP3_Real_si , VOP2_REV, VOP3DisableFields<1, 0, HasMods>; } multiclass VOP3b_2_m op, dag outs, dag ins, string asm, list pattern, string opName, string revOp, bit HasMods = 1, bit UseFullOp = 0> { def "" : VOP3_Pseudo , VOP2_REV; // The VOP2 variant puts the carry out into VCC, the VOP3 variant // can write it into any SGPR. We currently don't use the carry out, // so for now hardcode it to VCC as well. let sdst = SIOperand.VCC, Defs = [VCC] in { def _si : VOP3b , VOP3DisableFields<1, 0, HasMods>, SIMCInstr, VOP2_REV; } // End sdst = SIOperand.VCC, Defs = [VCC] } multiclass VOP3_C_m op, dag outs, dag ins, string asm, list pattern, string opName, bit HasMods, bit defExec> { def "" : VOP3_Pseudo ; def _si : VOP3_Real_si < {0, op{7}, op{6}, op{5}, op{4}, op{3}, op{2}, op{1}, op{0}}, outs, ins, asm, opName>, VOP3DisableFields<1, 0, HasMods> { let Defs = !if(defExec, [EXEC], []); } } multiclass VOP1_Helper op, string opName, dag outs, dag ins32, string asm32, list pat32, dag ins64, string asm64, list pat64, bit HasMods> { def _e32 : VOP1 , VOP; defm _e64 : VOP3_1_m ; } multiclass VOP1Inst op, string opName, VOPProfile P, SDPatternOperator node = null_frag> : VOP1_Helper < op, opName, P.Outs, P.Ins32, P.Asm32, [], P.Ins64, P.Asm64, !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0))]), P.HasModifiers >; class VOP2_e32 op, string opName, dag outs, dag ins, string asm, list pattern, string revOp> : VOP2 , VOP , VOP2_REV; multiclass VOP2_Helper op, string opName, dag outs, dag ins32, string asm32, list pat32, dag ins64, string asm64, list pat64, string revOp, bit HasMods> { def _e32 : VOP2_e32 ; defm _e64 : VOP3_2_m < {1, 0, 0, op{5}, op{4}, op{3}, op{2}, op{1}, op{0}}, outs, ins64, opName#"_e64"#asm64, pat64, opName, revOp, HasMods >; } multiclass VOP2Inst op, string opName, VOPProfile P, SDPatternOperator node = null_frag, string revOp = opName> : VOP2_Helper < op, opName, P.Outs, P.Ins32, P.Asm32, [], P.Ins64, P.Asm64, !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0, P.Src1VT:$src1))]), revOp, P.HasModifiers >; multiclass VOP2b_Helper op, string opName, dag outs, dag ins32, string asm32, list pat32, dag ins64, string asm64, list pat64, string revOp, bit HasMods> { def _e32 : VOP2_e32 ; defm _e64 : VOP3b_2_m < {1, 0, 0, op{5}, op{4}, op{3}, op{2}, op{1}, op{0}}, outs, ins64, opName#"_e64"#asm64, pat64, opName, revOp, HasMods >; } multiclass VOP2bInst op, string opName, VOPProfile P, SDPatternOperator node = null_frag, string revOp = opName> : VOP2b_Helper < op, opName, P.Outs, P.Ins32, P.Asm32, [], P.Ins64, P.Asm64, !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0, P.Src1VT:$src1))]), revOp, P.HasModifiers >; multiclass VOPC_Helper op, string opName, dag ins32, string asm32, list pat32, dag out64, dag ins64, string asm64, list pat64, bit HasMods, bit DefExec> { def _e32 : VOPC , VOP { let Defs = !if(DefExec, [EXEC], []); } defm _e64 : VOP3_C_m ; } multiclass VOPCInst op, string opName, VOPProfile P, PatLeaf cond = COND_NULL, bit DefExec = 0> : VOPC_Helper < op, opName, P.Ins32, P.Asm32, [], (outs SReg_64:$dst), P.Ins64, P.Asm64, !if(P.HasModifiers, [(set i1:$dst, (setcc (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers)), cond))], [(set i1:$dst, (setcc P.Src0VT:$src0, P.Src1VT:$src1, cond))]), P.HasModifiers, DefExec >; multiclass VOPC_F32 op, string opName, PatLeaf cond = COND_NULL> : VOPCInst ; multiclass VOPC_F64 op, string opName, PatLeaf cond = COND_NULL> : VOPCInst ; multiclass VOPC_I32 op, string opName, PatLeaf cond = COND_NULL> : VOPCInst ; multiclass VOPC_I64 op, string opName, PatLeaf cond = COND_NULL> : VOPCInst ; multiclass VOPCX op, string opName, VOPProfile P, PatLeaf cond = COND_NULL> : VOPCInst ; multiclass VOPCX_F32 op, string opName, PatLeaf cond = COND_NULL> : VOPCX ; multiclass VOPCX_F64 op, string opName, PatLeaf cond = COND_NULL> : VOPCX ; multiclass VOPCX_I32 op, string opName, PatLeaf cond = COND_NULL> : VOPCX ; multiclass VOPCX_I64 op, string opName, PatLeaf cond = COND_NULL> : VOPCX ; multiclass VOP3_Helper op, string opName, dag outs, dag ins, string asm, list pat, int NumSrcArgs, bit HasMods> : VOP3_m < op, outs, ins, opName#asm, pat, opName, NumSrcArgs, HasMods >; multiclass VOP3Inst op, string opName, VOPProfile P, SDPatternOperator node = null_frag> : VOP3_Helper < op, opName, P.Outs, P.Ins64, P.Asm64, !if(!eq(P.NumSrcArgs, 3), !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers)), (P.Src2VT (VOP3Mods P.Src2VT:$src2, i32:$src2_modifiers))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0, P.Src1VT:$src1, P.Src2VT:$src2))]), !if(!eq(P.NumSrcArgs, 2), !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0, P.Src1VT:$src1))]) /* P.NumSrcArgs == 1 */, !if(P.HasModifiers, [(set P.DstVT:$dst, (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod))))], [(set P.DstVT:$dst, (node P.Src0VT:$src0))]))), P.NumSrcArgs, P.HasModifiers >; multiclass VOP3b_Helper op, RegisterClass vrc, RegisterClass arc, string opName, list pattern> : VOP3b_2_m < op, (outs vrc:$dst0, SReg_64:$dst1), (ins arc:$src0, arc:$src1, arc:$src2, InstFlag:$abs, InstFlag:$clamp, InstFlag:$omod, InstFlag:$neg), opName#" $dst0, $dst1, $src0, $src1, $src2, $abs, $clamp, $omod, $neg", pattern, opName, opName, 1, 1 >; multiclass VOP3b_64 op, string opName, list pattern> : VOP3b_Helper ; multiclass VOP3b_32 op, string opName, list pattern> : VOP3b_Helper ; class Vop3ModPat : Pat< (node (P.Src0VT (VOP3Mods0 P.Src0VT:$src0, i32:$src0_modifiers, i32:$clamp, i32:$omod)), (P.Src1VT (VOP3Mods P.Src1VT:$src1, i32:$src1_modifiers)), (P.Src2VT (VOP3Mods P.Src2VT:$src2, i32:$src2_modifiers))), (Inst i32:$src0_modifiers, P.Src0VT:$src0, i32:$src1_modifiers, P.Src1VT:$src1, i32:$src2_modifiers, P.Src2VT:$src2, i32:$clamp, i32:$omod)>; //===----------------------------------------------------------------------===// // Vector I/O classes //===----------------------------------------------------------------------===// class DS_1A op, dag outs, dag ins, string asm, list pat> : DS { bits<16> offset; // Single load interpret the 2 i8imm operands as a single i16 offset. let offset0 = offset{7-0}; let offset1 = offset{15-8}; } class DS_Load_Helper op, string asm, RegisterClass regClass> : DS_1A < op, (outs regClass:$vdst), (ins i1imm:$gds, VReg_32:$addr, u16imm:$offset), asm#" $vdst, $addr, $offset, [M0]", []> { let data0 = 0; let data1 = 0; let mayLoad = 1; let mayStore = 0; } class DS_Load2_Helper op, string asm, RegisterClass regClass> : DS < op, (outs regClass:$vdst), (ins i1imm:$gds, VReg_32:$addr, u8imm:$offset0, u8imm:$offset1), asm#" $vdst, $addr, $offset0, $offset1, [M0]", []> { let data0 = 0; let data1 = 0; let mayLoad = 1; let mayStore = 0; } class DS_Store_Helper op, string asm, RegisterClass regClass> : DS_1A < op, (outs), (ins i1imm:$gds, VReg_32:$addr, regClass:$data0, u16imm:$offset), asm#" $addr, $data0, $offset [M0]", []> { let data1 = 0; let mayStore = 1; let mayLoad = 0; let vdst = 0; } class DS_Store2_Helper op, string asm, RegisterClass regClass> : DS < op, (outs), (ins i1imm:$gds, VReg_32:$addr, regClass:$data0, regClass:$data1, u8imm:$offset0, u8imm:$offset1), asm#" $addr, $data0, $data1, $offset0, $offset1 [M0]", []> { let mayStore = 1; let mayLoad = 0; let vdst = 0; } // 1 address, 1 data. class DS_1A1D_RET op, string asm, RegisterClass rc, string noRetOp = ""> : DS_1A < op, (outs rc:$vdst), (ins i1imm:$gds, VReg_32:$addr, rc:$data0, u16imm:$offset), asm#" $vdst, $addr, $data0, $offset, [M0]", []>, AtomicNoRet { let data1 = 0; let mayStore = 1; let mayLoad = 1; let hasPostISelHook = 1; // Adjusted to no return version. } // 1 address, 2 data. class DS_1A2D_RET op, string asm, RegisterClass rc, string noRetOp = ""> : DS_1A < op, (outs rc:$vdst), (ins i1imm:$gds, VReg_32:$addr, rc:$data0, rc:$data1, u16imm:$offset), asm#" $vdst, $addr, $data0, $data1, $offset, [M0]", []>, AtomicNoRet { let mayStore = 1; let mayLoad = 1; let hasPostISelHook = 1; // Adjusted to no return version. } // 1 address, 2 data. class DS_1A2D_NORET op, string asm, RegisterClass rc, string noRetOp = asm> : DS_1A < op, (outs), (ins i1imm:$gds, VReg_32:$addr, rc:$data0, rc:$data1, u16imm:$offset), asm#" $addr, $data0, $data1, $offset, [M0]", []>, AtomicNoRet { let mayStore = 1; let mayLoad = 1; } // 1 address, 1 data. class DS_1A1D_NORET op, string asm, RegisterClass rc, string noRetOp = asm> : DS_1A < op, (outs), (ins i1imm:$gds, VReg_32:$addr, rc:$data0, u16imm:$offset), asm#" $addr, $data0, $offset, [M0]", []>, AtomicNoRet { let data1 = 0; let mayStore = 1; let mayLoad = 1; } class MUBUFAddr64Table { bit IsAddr64 = is_addr64; } class MTBUF_Store_Helper op, string asm, RegisterClass regClass> : MTBUF < op, (outs), (ins regClass:$vdata, u16imm:$offset, i1imm:$offen, i1imm:$idxen, i1imm:$glc, i1imm:$addr64, i8imm:$dfmt, i8imm:$nfmt, VReg_32:$vaddr, SReg_128:$srsrc, i1imm:$slc, i1imm:$tfe, SSrc_32:$soffset), asm#" $vdata, $offset, $offen, $idxen, $glc, $addr64, $dfmt," #" $nfmt, $vaddr, $srsrc, $slc, $tfe, $soffset", []> { let mayStore = 1; let mayLoad = 0; } multiclass MUBUF_Load_Helper op, string asm, RegisterClass regClass, ValueType load_vt = i32, SDPatternOperator ld = null_frag> { let lds = 0, mayLoad = 1 in { let addr64 = 0 in { let offen = 0, idxen = 0, vaddr = 0 in { def _OFFSET : MUBUF , MUBUFAddr64Table<0>; } let offen = 1, idxen = 0 in { def _OFFEN : MUBUF ; } let offen = 0, idxen = 1 in { def _IDXEN : MUBUF ; } let offen = 1, idxen = 1 in { def _BOTHEN : MUBUF ; } } let offen = 0, idxen = 0, addr64 = 1, glc = 0, slc = 0, tfe = 0, soffset = 128 /* ZERO */ in { def _ADDR64 : MUBUF , MUBUFAddr64Table<1>; } } } multiclass MUBUF_Store_Helper op, string name, RegisterClass vdataClass, ValueType store_vt, SDPatternOperator st> { let addr64 = 0, lds = 0 in { def "" : MUBUF < op, (outs), (ins vdataClass:$vdata, SReg_128:$srsrc, VReg_32:$vaddr, SSrc_32:$soffset, mbuf_offset:$offset, offen:$offen, idxen:$idxen, glc:$glc, slc:$slc, tfe:$tfe), name#" $vdata, $vaddr, $srsrc, $soffset"#"$offen"#"$idxen"#"$offset"# "$glc"#"$slc"#"$tfe", [] >; let offen = 0, idxen = 0, vaddr = 0 in { def _OFFSET : MUBUF < op, (outs), (ins vdataClass:$vdata, SReg_128:$srsrc, mbuf_offset:$offset, SSrc_32:$soffset, glc:$glc, slc:$slc, tfe:$tfe), name#" $vdata, $srsrc, $soffset"#"$offset"#"$glc"#"$slc"#"$tfe", [(st store_vt:$vdata, (MUBUFOffset v4i32:$srsrc, i32:$soffset, i16:$offset, i1:$glc, i1:$slc, i1:$tfe))] >, MUBUFAddr64Table<0>; } // offen = 0, idxen = 0, vaddr = 0 let offen = 1, idxen = 0 in { def _OFFEN : MUBUF < op, (outs), (ins vdataClass:$vdata, SReg_128:$srsrc, VReg_32:$vaddr, SSrc_32:$soffset, mbuf_offset:$offset, glc:$glc, slc:$slc, tfe:$tfe), name#" $vdata, $vaddr, $srsrc, $soffset offen"#"$offset"# "$glc"#"$slc"#"$tfe", [] >; } // end offen = 1, idxen = 0 } // End addr64 = 0, lds = 0 def _ADDR64 : MUBUF < op, (outs), (ins vdataClass:$vdata, SReg_128:$srsrc, VReg_64:$vaddr, mbuf_offset:$offset), name#" $vdata, $vaddr, $srsrc, 0 addr64"#"$offset", [(st store_vt:$vdata, (MUBUFAddr64 v4i32:$srsrc, i64:$vaddr, i16:$offset))]>, MUBUFAddr64Table<1> { let mayLoad = 0; let mayStore = 1; // Encoding let offen = 0; let idxen = 0; let glc = 0; let addr64 = 1; let lds = 0; let slc = 0; let tfe = 0; let soffset = 128; // ZERO } } class FLAT_Load_Helper op, string asm, RegisterClass regClass> : FLAT { let glc = 0; let slc = 0; let tfe = 0; let mayLoad = 1; } class FLAT_Store_Helper op, string name, RegisterClass vdataClass> : FLAT { let mayLoad = 0; let mayStore = 1; // Encoding let glc = 0; let slc = 0; let tfe = 0; } class MTBUF_Load_Helper op, string asm, RegisterClass regClass> : MTBUF < op, (outs regClass:$dst), (ins u16imm:$offset, i1imm:$offen, i1imm:$idxen, i1imm:$glc, i1imm:$addr64, i8imm:$dfmt, i8imm:$nfmt, VReg_32:$vaddr, SReg_128:$srsrc, i1imm:$slc, i1imm:$tfe, SSrc_32:$soffset), asm#" $dst, $offset, $offen, $idxen, $glc, $addr64, $dfmt," #" $nfmt, $vaddr, $srsrc, $slc, $tfe, $soffset", []> { let mayLoad = 1; let mayStore = 0; } class MIMG_Mask { string Op = op; int Channels = channels; } class MIMG_NoSampler_Helper op, string asm, RegisterClass dst_rc, RegisterClass src_rc> : MIMG < op, (outs dst_rc:$vdata), (ins i32imm:$dmask, i1imm:$unorm, i1imm:$glc, i1imm:$da, i1imm:$r128, i1imm:$tfe, i1imm:$lwe, i1imm:$slc, src_rc:$vaddr, SReg_256:$srsrc), asm#" $vdata, $dmask, $unorm, $glc, $da, $r128," #" $tfe, $lwe, $slc, $vaddr, $srsrc", []> { let SSAMP = 0; let mayLoad = 1; let mayStore = 0; let hasPostISelHook = 1; } multiclass MIMG_NoSampler_Src_Helper op, string asm, RegisterClass dst_rc, int channels> { def _V1 : MIMG_NoSampler_Helper , MIMG_Mask; def _V2 : MIMG_NoSampler_Helper , MIMG_Mask; def _V4 : MIMG_NoSampler_Helper , MIMG_Mask; } multiclass MIMG_NoSampler op, string asm> { defm _V1 : MIMG_NoSampler_Src_Helper ; defm _V2 : MIMG_NoSampler_Src_Helper ; defm _V3 : MIMG_NoSampler_Src_Helper ; defm _V4 : MIMG_NoSampler_Src_Helper ; } class MIMG_Sampler_Helper op, string asm, RegisterClass dst_rc, RegisterClass src_rc> : MIMG < op, (outs dst_rc:$vdata), (ins i32imm:$dmask, i1imm:$unorm, i1imm:$glc, i1imm:$da, i1imm:$r128, i1imm:$tfe, i1imm:$lwe, i1imm:$slc, src_rc:$vaddr, SReg_256:$srsrc, SReg_128:$ssamp), asm#" $vdata, $dmask, $unorm, $glc, $da, $r128," #" $tfe, $lwe, $slc, $vaddr, $srsrc, $ssamp", []> { let mayLoad = 1; let mayStore = 0; let hasPostISelHook = 1; } multiclass MIMG_Sampler_Src_Helper op, string asm, RegisterClass dst_rc, int channels> { def _V1 : MIMG_Sampler_Helper , MIMG_Mask; def _V2 : MIMG_Sampler_Helper , MIMG_Mask; def _V4 : MIMG_Sampler_Helper , MIMG_Mask; def _V8 : MIMG_Sampler_Helper , MIMG_Mask; def _V16 : MIMG_Sampler_Helper , MIMG_Mask; } multiclass MIMG_Sampler op, string asm> { defm _V1 : MIMG_Sampler_Src_Helper; defm _V2 : MIMG_Sampler_Src_Helper; defm _V3 : MIMG_Sampler_Src_Helper; defm _V4 : MIMG_Sampler_Src_Helper; } class MIMG_Gather_Helper op, string asm, RegisterClass dst_rc, RegisterClass src_rc> : MIMG < op, (outs dst_rc:$vdata), (ins i32imm:$dmask, i1imm:$unorm, i1imm:$glc, i1imm:$da, i1imm:$r128, i1imm:$tfe, i1imm:$lwe, i1imm:$slc, src_rc:$vaddr, SReg_256:$srsrc, SReg_128:$ssamp), asm#" $vdata, $dmask, $unorm, $glc, $da, $r128," #" $tfe, $lwe, $slc, $vaddr, $srsrc, $ssamp", []> { let mayLoad = 1; let mayStore = 0; // DMASK was repurposed for GATHER4. 4 components are always // returned and DMASK works like a swizzle - it selects // the component to fetch. The only useful DMASK values are // 1=red, 2=green, 4=blue, 8=alpha. (e.g. 1 returns // (red,red,red,red) etc.) The ISA document doesn't mention // this. // Therefore, disable all code which updates DMASK by setting these two: let MIMG = 0; let hasPostISelHook = 0; } multiclass MIMG_Gather_Src_Helper op, string asm, RegisterClass dst_rc, int channels> { def _V1 : MIMG_Gather_Helper , MIMG_Mask; def _V2 : MIMG_Gather_Helper , MIMG_Mask; def _V4 : MIMG_Gather_Helper , MIMG_Mask; def _V8 : MIMG_Gather_Helper , MIMG_Mask; def _V16 : MIMG_Gather_Helper , MIMG_Mask; } multiclass MIMG_Gather op, string asm> { defm _V1 : MIMG_Gather_Src_Helper; defm _V2 : MIMG_Gather_Src_Helper; defm _V3 : MIMG_Gather_Src_Helper; defm _V4 : MIMG_Gather_Src_Helper; } //===----------------------------------------------------------------------===// // Vector instruction mappings //===----------------------------------------------------------------------===// // Maps an opcode in e32 form to its e64 equivalent def getVOPe64 : InstrMapping { let FilterClass = "VOP"; let RowFields = ["OpName"]; let ColFields = ["Size"]; let KeyCol = ["4"]; let ValueCols = [["8"]]; } // Maps an opcode in e64 form to its e32 equivalent def getVOPe32 : InstrMapping { let FilterClass = "VOP"; let RowFields = ["OpName"]; let ColFields = ["Size"]; let KeyCol = ["8"]; let ValueCols = [["4"]]; } // Maps an original opcode to its commuted version def getCommuteRev : InstrMapping { let FilterClass = "VOP2_REV"; let RowFields = ["RevOp"]; let ColFields = ["IsOrig"]; let KeyCol = ["1"]; let ValueCols = [["0"]]; } def getMaskedMIMGOp : InstrMapping { let FilterClass = "MIMG_Mask"; let RowFields = ["Op"]; let ColFields = ["Channels"]; let KeyCol = ["4"]; let ValueCols = [["1"], ["2"], ["3"] ]; } // Maps an commuted opcode to its original version def getCommuteOrig : InstrMapping { let FilterClass = "VOP2_REV"; let RowFields = ["RevOp"]; let ColFields = ["IsOrig"]; let KeyCol = ["0"]; let ValueCols = [["1"]]; } def isDS : InstrMapping { let FilterClass = "DS"; let RowFields = ["Inst"]; let ColFields = ["Size"]; let KeyCol = ["8"]; let ValueCols = [["8"]]; } def getMCOpcode : InstrMapping { let FilterClass = "SIMCInstr"; let RowFields = ["PseudoInstr"]; let ColFields = ["Subtarget"]; let KeyCol = [!cast(SISubtarget.NONE)]; let ValueCols = [[!cast(SISubtarget.SI)]]; } def getAddr64Inst : InstrMapping { let FilterClass = "MUBUFAddr64Table"; let RowFields = ["NAME"]; let ColFields = ["IsAddr64"]; let KeyCol = ["0"]; let ValueCols = [["1"]]; } // Maps an atomic opcode to its version with a return value. def getAtomicRetOp : InstrMapping { let FilterClass = "AtomicNoRet"; let RowFields = ["NoRetOp"]; let ColFields = ["IsRet"]; let KeyCol = ["0"]; let ValueCols = [["1"]]; } // Maps an atomic opcode to its returnless version. def getAtomicNoRetOp : InstrMapping { let FilterClass = "AtomicNoRet"; let RowFields = ["NoRetOp"]; let ColFields = ["IsRet"]; let KeyCol = ["1"]; let ValueCols = [["0"]]; } include "SIInstructions.td"