/
SIInstructions.td
3643 lines (3102 loc) · 120 KB
/
SIInstructions.td
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//===-- SIInstructions.td - SI Instruction Definitions --------------------===//
//
// 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 was originally auto-generated from a GPU register header file and
// all the instruction definitions were originally commented out. Instructions
// that are not yet supported remain commented out.
//===----------------------------------------------------------------------===//
class GCNPat<dag pattern, dag result> : Pat<pattern, result>, GCNPredicateControl {
}
class UniformSextInreg<ValueType VT> : PatFrag<
(ops node:$src),
(sext_inreg $src, VT),
[{ return !N->isDivergent(); }]>;
class DivergentSextInreg<ValueType VT> : PatFrag<
(ops node:$src),
(sext_inreg $src, VT),
[{ return N->isDivergent(); }]>;
include "SOPInstructions.td"
include "VOPInstructions.td"
include "SMInstructions.td"
include "FLATInstructions.td"
include "BUFInstructions.td"
include "EXPInstructions.td"
include "LDSDIRInstructions.td"
include "VINTERPInstructions.td"
//===----------------------------------------------------------------------===//
// VINTRP Instructions
//===----------------------------------------------------------------------===//
// Used to inject printing of "_e32" suffix for VI (there are "_e64" variants for VI)
def VINTRPDst : VINTRPDstOperand <VGPR_32>;
let Uses = [MODE, M0, EXEC] in {
// FIXME: Specify SchedRW for VINTRP instructions.
multiclass V_INTERP_P1_F32_m : VINTRP_m <
0x00000000,
(outs VINTRPDst:$vdst),
(ins VGPR_32:$vsrc, Attr:$attr, AttrChan:$attrchan),
"v_interp_p1_f32$vdst, $vsrc, $attr$attrchan",
[(set f32:$vdst, (int_amdgcn_interp_p1 f32:$vsrc,
(i32 timm:$attrchan), (i32 timm:$attr), M0))]
>;
let OtherPredicates = [has32BankLDS, isNotGFX90APlus] in {
defm V_INTERP_P1_F32 : V_INTERP_P1_F32_m;
} // End OtherPredicates = [has32BankLDS, isNotGFX90APlus]
let OtherPredicates = [has16BankLDS, isNotGFX90APlus],
Constraints = "@earlyclobber $vdst", isAsmParserOnly=1 in {
defm V_INTERP_P1_F32_16bank : V_INTERP_P1_F32_m;
} // End OtherPredicates = [has32BankLDS, isNotGFX90APlus],
// Constraints = "@earlyclobber $vdst", isAsmParserOnly=1
let OtherPredicates = [isNotGFX90APlus] in {
let DisableEncoding = "$src0", Constraints = "$src0 = $vdst" in {
defm V_INTERP_P2_F32 : VINTRP_m <
0x00000001,
(outs VINTRPDst:$vdst),
(ins VGPR_32:$src0, VGPR_32:$vsrc, Attr:$attr, AttrChan:$attrchan),
"v_interp_p2_f32$vdst, $vsrc, $attr$attrchan",
[(set f32:$vdst, (int_amdgcn_interp_p2 f32:$src0, f32:$vsrc,
(i32 timm:$attrchan), (i32 timm:$attr), M0))]>;
} // End DisableEncoding = "$src0", Constraints = "$src0 = $vdst"
defm V_INTERP_MOV_F32 : VINTRP_m <
0x00000002,
(outs VINTRPDst:$vdst),
(ins InterpSlot:$vsrc, Attr:$attr, AttrChan:$attrchan),
"v_interp_mov_f32$vdst, $vsrc, $attr$attrchan",
[(set f32:$vdst, (int_amdgcn_interp_mov (i32 timm:$vsrc),
(i32 timm:$attrchan), (i32 timm:$attr), M0))]>;
} // End OtherPredicates = [isNotGFX90APlus]
} // End Uses = [MODE, M0, EXEC]
//===----------------------------------------------------------------------===//
// Pseudo Instructions
//===----------------------------------------------------------------------===//
def ATOMIC_FENCE : SPseudoInstSI<
(outs), (ins i32imm:$ordering, i32imm:$scope),
[(atomic_fence (i32 timm:$ordering), (i32 timm:$scope))],
"ATOMIC_FENCE $ordering, $scope"> {
let hasSideEffects = 1;
let maybeAtomic = 1;
}
let hasSideEffects = 0, mayLoad = 0, mayStore = 0, Uses = [EXEC] in {
// For use in patterns
def V_CNDMASK_B64_PSEUDO : VOP3Common <(outs VReg_64:$vdst),
(ins VSrc_b64:$src0, VSrc_b64:$src1, SSrc_b64:$src2), "", []> {
let isPseudo = 1;
let isCodeGenOnly = 1;
let usesCustomInserter = 1;
}
// 64-bit vector move instruction. This is mainly used by the
// SIFoldOperands pass to enable folding of inline immediates.
def V_MOV_B64_PSEUDO : VPseudoInstSI <(outs VReg_64:$vdst),
(ins VSrc_b64:$src0)> {
let isReMaterializable = 1;
let isAsCheapAsAMove = 1;
let isMoveImm = 1;
let SchedRW = [Write64Bit];
let Size = 16; // Needs maximum 2 v_mov_b32 instructions 8 byte long each.
let UseNamedOperandTable = 1;
}
// 64-bit vector move with dpp. Expanded post-RA.
def V_MOV_B64_DPP_PSEUDO : VOP_DPP_Pseudo <"v_mov_b64_dpp", VOP_I64_I64> {
let Size = 16; // Requires two 8-byte v_mov_b32_dpp to complete.
}
// 64-bit scalar move immediate instruction. This is used to avoid subregs
// initialization and allow rematerialization.
def S_MOV_B64_IMM_PSEUDO : SPseudoInstSI <(outs SReg_64:$sdst),
(ins i64imm:$src0)> {
let isReMaterializable = 1;
let isAsCheapAsAMove = 1;
let isMoveImm = 1;
let SchedRW = [WriteSALU, Write64Bit];
let Size = 16; // Needs maximum 2 s_mov_b32 instructions 8 byte long each.
let Uses = [];
}
// Pseudoinstruction for @llvm.amdgcn.wqm. It is turned into a copy after the
// WQM pass processes it.
def WQM : PseudoInstSI <(outs unknown:$vdst), (ins unknown:$src0)>;
// Pseudoinstruction for @llvm.amdgcn.softwqm. Like @llvm.amdgcn.wqm it is
// turned into a copy by WQM pass, but does not seed WQM requirements.
def SOFT_WQM : PseudoInstSI <(outs unknown:$vdst), (ins unknown:$src0)>;
// Pseudoinstruction for @llvm.amdgcn.strict.wwm. It is turned into a copy post-RA, so
// that the @earlyclobber is respected. The @earlyclobber is to make sure that
// the instruction that defines $src0 (which is run in Whole Wave Mode) doesn't
// accidentally clobber inactive channels of $vdst.
let Constraints = "@earlyclobber $vdst" in {
def STRICT_WWM : PseudoInstSI <(outs unknown:$vdst), (ins unknown:$src0)>;
def STRICT_WQM : PseudoInstSI <(outs unknown:$vdst), (ins unknown:$src0)>;
}
} // End let hasSideEffects = 0, mayLoad = 0, mayStore = 0, Uses = [EXEC]
def ENTER_STRICT_WWM : SPseudoInstSI <(outs SReg_1:$sdst), (ins i64imm:$src0)> {
let Uses = [EXEC];
let Defs = [EXEC, SCC];
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
def EXIT_STRICT_WWM : SPseudoInstSI <(outs SReg_1:$sdst), (ins SReg_1:$src0)> {
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
def ENTER_STRICT_WQM : SPseudoInstSI <(outs SReg_1:$sdst), (ins i64imm:$src0)> {
let Uses = [EXEC];
let Defs = [EXEC, SCC];
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
def EXIT_STRICT_WQM : SPseudoInstSI <(outs SReg_1:$sdst), (ins SReg_1:$src0)> {
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
let usesCustomInserter = 1 in {
def S_INVERSE_BALLOT_U32 : SPseudoInstSI <(outs SReg_32:$sdst), (ins SSrc_b32:$mask)>;
def S_INVERSE_BALLOT_U64 : SPseudoInstSI <(outs SReg_64:$sdst), (ins SSrc_b64:$mask)>;
} // End usesCustomInserter = 1
// PSEUDO_WM is treated like STRICT_WWM/STRICT_WQM without exec changes.
def ENTER_PSEUDO_WM : SPseudoInstSI <(outs), (ins)> {
let Uses = [EXEC];
let Defs = [EXEC];
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
def EXIT_PSEUDO_WM : SPseudoInstSI <(outs), (ins)> {
let hasSideEffects = 0;
let mayLoad = 0;
let mayStore = 0;
}
// Pseudo instructions used for @llvm.fptrunc.round upward
// and @llvm.fptrunc.round downward.
// These intrinsics will be legalized to G_FPTRUNC_ROUND_UPWARD
// and G_FPTRUNC_ROUND_DOWNWARD before being lowered to
// FPTRUNC_UPWARD_PSEUDO and FPTRUNC_DOWNWARD_PSEUDO.
// The final codegen is done in the ModeRegister pass.
let Uses = [MODE, EXEC] in {
def FPTRUNC_UPWARD_PSEUDO : VPseudoInstSI <(outs VGPR_32:$vdst),
(ins VGPR_32:$src0),
[(set f16:$vdst, (SIfptrunc_round_upward f32:$src0))]>;
def FPTRUNC_DOWNWARD_PSEUDO : VPseudoInstSI <(outs VGPR_32:$vdst),
(ins VGPR_32:$src0),
[(set f16:$vdst, (SIfptrunc_round_downward f32:$src0))]>;
} // End Uses = [MODE, EXEC]
// Invert the exec mask and overwrite the inactive lanes of dst with inactive,
// restoring it after we're done.
let Defs = [SCC], isConvergent = 1 in {
def V_SET_INACTIVE_B32 : VPseudoInstSI <(outs VGPR_32:$vdst),
(ins VSrc_b32: $src, VSrc_b32:$inactive),
[(set i32:$vdst, (int_amdgcn_set_inactive i32:$src, i32:$inactive))]> {
}
def V_SET_INACTIVE_B64 : VPseudoInstSI <(outs VReg_64:$vdst),
(ins VSrc_b64: $src, VSrc_b64:$inactive),
[(set i64:$vdst, (int_amdgcn_set_inactive i64:$src, i64:$inactive))]> {
}
} // End Defs = [SCC]
let usesCustomInserter = 1, Defs = [VCC, EXEC] in {
def V_ADD_U64_PSEUDO : VPseudoInstSI <
(outs VReg_64:$vdst), (ins VSrc_b64:$src0, VSrc_b64:$src1),
[(set VReg_64:$vdst, (DivergentBinFrag<add> i64:$src0, i64:$src1))]
>;
def V_SUB_U64_PSEUDO : VPseudoInstSI <
(outs VReg_64:$vdst), (ins VSrc_b64:$src0, VSrc_b64:$src1),
[(set VReg_64:$vdst, (DivergentBinFrag<sub> i64:$src0, i64:$src1))]
>;
} // End usesCustomInserter = 1, Defs = [VCC, EXEC]
let usesCustomInserter = 1, Defs = [SCC] in {
def S_ADD_U64_PSEUDO : SPseudoInstSI <
(outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b64:$src1),
[(set SReg_64:$sdst, (UniformBinFrag<add> i64:$src0, i64:$src1))]
>;
def S_SUB_U64_PSEUDO : SPseudoInstSI <
(outs SReg_64:$sdst), (ins SSrc_b64:$src0, SSrc_b64:$src1),
[(set SReg_64:$sdst, (UniformBinFrag<sub> i64:$src0, i64:$src1))]
>;
def S_ADD_CO_PSEUDO : SPseudoInstSI <
(outs SReg_32:$sdst, SSrc_i1:$scc_out), (ins SSrc_b32:$src0, SSrc_b32:$src1, SSrc_i1:$scc_in)
>;
def S_SUB_CO_PSEUDO : SPseudoInstSI <
(outs SReg_32:$sdst, SSrc_i1:$scc_out), (ins SSrc_b32:$src0, SSrc_b32:$src1, SSrc_i1:$scc_in)
>;
def S_UADDO_PSEUDO : SPseudoInstSI <
(outs SReg_32:$sdst, SSrc_i1:$scc_out), (ins SSrc_b32:$src0, SSrc_b32:$src1)
>;
def S_USUBO_PSEUDO : SPseudoInstSI <
(outs SReg_32:$sdst, SSrc_i1:$scc_out), (ins SSrc_b32:$src0, SSrc_b32:$src1)
>;
} // End usesCustomInserter = 1, Defs = [SCC]
let usesCustomInserter = 1 in {
def GET_GROUPSTATICSIZE : SPseudoInstSI <(outs SReg_32:$sdst), (ins),
[(set SReg_32:$sdst, (int_amdgcn_groupstaticsize))]>;
} // End let usesCustomInserter = 1, SALU = 1
// Wrap an instruction by duplicating it, except for setting isTerminator.
class WrapTerminatorInst<SOP_Pseudo base_inst> : SPseudoInstSI<
base_inst.OutOperandList,
base_inst.InOperandList> {
let Uses = base_inst.Uses;
let Defs = base_inst.Defs;
let isTerminator = 1;
let isAsCheapAsAMove = base_inst.isAsCheapAsAMove;
let hasSideEffects = base_inst.hasSideEffects;
let UseNamedOperandTable = base_inst.UseNamedOperandTable;
let CodeSize = base_inst.CodeSize;
let SchedRW = base_inst.SchedRW;
}
let WaveSizePredicate = isWave64 in {
def S_MOV_B64_term : WrapTerminatorInst<S_MOV_B64>;
def S_XOR_B64_term : WrapTerminatorInst<S_XOR_B64>;
def S_OR_B64_term : WrapTerminatorInst<S_OR_B64>;
def S_ANDN2_B64_term : WrapTerminatorInst<S_ANDN2_B64>;
def S_AND_B64_term : WrapTerminatorInst<S_AND_B64>;
def S_AND_SAVEEXEC_B64_term : WrapTerminatorInst<S_AND_SAVEEXEC_B64>;
}
let WaveSizePredicate = isWave32 in {
def S_MOV_B32_term : WrapTerminatorInst<S_MOV_B32>;
def S_XOR_B32_term : WrapTerminatorInst<S_XOR_B32>;
def S_OR_B32_term : WrapTerminatorInst<S_OR_B32>;
def S_ANDN2_B32_term : WrapTerminatorInst<S_ANDN2_B32>;
def S_AND_B32_term : WrapTerminatorInst<S_AND_B32>;
def S_AND_SAVEEXEC_B32_term : WrapTerminatorInst<S_AND_SAVEEXEC_B32>;
}
def WAVE_BARRIER : SPseudoInstSI<(outs), (ins),
[(int_amdgcn_wave_barrier)]> {
let SchedRW = [];
let hasNoSchedulingInfo = 1;
let hasSideEffects = 1;
let mayLoad = 0;
let mayStore = 0;
let isConvergent = 1;
let FixedSize = 1;
let Size = 0;
let isMeta = 1;
}
def SCHED_BARRIER : SPseudoInstSI<(outs), (ins i32imm:$mask),
[(int_amdgcn_sched_barrier (i32 timm:$mask))]> {
let SchedRW = [];
let hasNoSchedulingInfo = 1;
let hasSideEffects = 1;
let mayLoad = 0;
let mayStore = 0;
let isConvergent = 1;
let FixedSize = 1;
let Size = 0;
let isMeta = 1;
}
def SCHED_GROUP_BARRIER : SPseudoInstSI<
(outs),
(ins i32imm:$mask, i32imm:$size, i32imm:$syncid),
[(int_amdgcn_sched_group_barrier (i32 timm:$mask), (i32 timm:$size), (i32 timm:$syncid))]> {
let SchedRW = [];
let hasNoSchedulingInfo = 1;
let hasSideEffects = 1;
let mayLoad = 0;
let mayStore = 0;
let isConvergent = 1;
let FixedSize = 1;
let Size = 0;
let isMeta = 1;
}
def IGLP_OPT : SPseudoInstSI<(outs), (ins i32imm:$mask),
[(int_amdgcn_iglp_opt (i32 timm:$mask))]> {
let SchedRW = [];
let hasNoSchedulingInfo = 1;
let hasSideEffects = 1;
let mayLoad = 0;
let mayStore = 0;
let isConvergent = 1;
let FixedSize = 1;
let Size = 0;
let isMeta = 1;
}
// SI pseudo instructions. These are used by the CFG structurizer pass
// and should be lowered to ISA instructions prior to codegen.
// As we have enhanced control flow intrinsics to work under unstructured CFG,
// duplicating such intrinsics can be actually treated as legal. On the contrary,
// by making them non-duplicable, we are observing better code generation result.
// So we choose to mark them non-duplicable in hope of getting better code
// generation as well as simplied CFG during Machine IR optimization stage.
let isTerminator = 1, isNotDuplicable = 1 in {
let OtherPredicates = [EnableLateCFGStructurize] in {
def SI_NON_UNIFORM_BRCOND_PSEUDO : CFPseudoInstSI <
(outs),
(ins SReg_1:$vcc, brtarget:$target),
[(brcond i1:$vcc, bb:$target)]> {
let Size = 12;
}
}
def SI_IF: CFPseudoInstSI <
(outs SReg_1:$dst), (ins SReg_1:$vcc, brtarget:$target),
[(set i1:$dst, (AMDGPUif i1:$vcc, bb:$target))], 1, 1> {
let Constraints = "";
let Size = 12;
let hasSideEffects = 1;
let IsNeverUniform = 1;
}
def SI_ELSE : CFPseudoInstSI <
(outs SReg_1:$dst),
(ins SReg_1:$src, brtarget:$target), [], 1, 1> {
let Size = 12;
let hasSideEffects = 1;
let IsNeverUniform = 1;
}
def SI_WATERFALL_LOOP : CFPseudoInstSI <
(outs),
(ins brtarget:$target), [], 1> {
let Size = 8;
let isBranch = 1;
let Defs = [];
}
def SI_LOOP : CFPseudoInstSI <
(outs), (ins SReg_1:$saved, brtarget:$target),
[(AMDGPUloop i1:$saved, bb:$target)], 1, 1> {
let Size = 8;
let isBranch = 1;
let hasSideEffects = 1;
let IsNeverUniform = 1;
}
} // End isTerminator = 1
def SI_END_CF : CFPseudoInstSI <
(outs), (ins SReg_1:$saved), [], 1, 1> {
let Size = 4;
let isAsCheapAsAMove = 1;
let isReMaterializable = 1;
let hasSideEffects = 1;
let isNotDuplicable = 1; // Not a hard requirement, see long comments above for details.
let mayLoad = 1; // FIXME: Should not need memory flags
let mayStore = 1;
}
def SI_IF_BREAK : CFPseudoInstSI <
(outs SReg_1:$dst), (ins SReg_1:$vcc, SReg_1:$src), []> {
let Size = 4;
let isNotDuplicable = 1; // Not a hard requirement, see long comments above for details.
let isAsCheapAsAMove = 1;
let isReMaterializable = 1;
}
// Branch to the early termination block of the shader if SCC is 0.
// This uses SCC from a previous SALU operation, i.e. the update of
// a mask of live lanes after a kill/demote operation.
// Only valid in pixel shaders.
def SI_EARLY_TERMINATE_SCC0 : SPseudoInstSI <(outs), (ins)> {
let Uses = [EXEC,SCC];
}
let Uses = [EXEC] in {
multiclass PseudoInstKill <dag ins> {
// Even though this pseudo can usually be expanded without an SCC def, we
// conservatively assume that it has an SCC def, both because it is sometimes
// required in degenerate cases (when V_CMPX cannot be used due to constant
// bus limitations) and because it allows us to avoid having to track SCC
// liveness across basic blocks.
let Defs = [EXEC,SCC] in
def _PSEUDO : PseudoInstSI <(outs), ins> {
let isConvergent = 1;
let usesCustomInserter = 1;
}
let Defs = [EXEC,SCC] in
def _TERMINATOR : SPseudoInstSI <(outs), ins> {
let isTerminator = 1;
}
}
defm SI_KILL_I1 : PseudoInstKill <(ins SCSrc_i1:$src, i1imm:$killvalue)>;
let Defs = [VCC] in
defm SI_KILL_F32_COND_IMM : PseudoInstKill <(ins VSrc_b32:$src0, i32imm:$src1, i32imm:$cond)>;
let Defs = [EXEC,VCC] in
def SI_ILLEGAL_COPY : SPseudoInstSI <
(outs unknown:$dst), (ins unknown:$src),
[], " ; illegal copy $src to $dst">;
} // End Uses = [EXEC], Defs = [EXEC,VCC]
// Branch on undef scc. Used to avoid intermediate copy from
// IMPLICIT_DEF to SCC.
def SI_BR_UNDEF : SPseudoInstSI <(outs), (ins sopp_brtarget:$simm16)> {
let isTerminator = 1;
let usesCustomInserter = 1;
let isBranch = 1;
}
def SI_PS_LIVE : PseudoInstSI <
(outs SReg_1:$dst), (ins),
[(set i1:$dst, (int_amdgcn_ps_live))]> {
let SALU = 1;
}
let Uses = [EXEC] in {
def SI_LIVE_MASK : PseudoInstSI <
(outs SReg_1:$dst), (ins),
[(set i1:$dst, (int_amdgcn_live_mask))]> {
let SALU = 1;
}
let Defs = [EXEC,SCC] in {
// Demote: Turn a pixel shader thread into a helper lane.
def SI_DEMOTE_I1 : SPseudoInstSI <(outs), (ins SCSrc_i1:$src, i1imm:$killvalue)>;
} // End Defs = [EXEC,SCC]
} // End Uses = [EXEC]
def SI_MASKED_UNREACHABLE : SPseudoInstSI <(outs), (ins),
[(int_amdgcn_unreachable)],
"; divergent unreachable"> {
let Size = 0;
let hasNoSchedulingInfo = 1;
let FixedSize = 1;
let isMeta = 1;
}
// Used as an isel pseudo to directly emit initialization with an
// s_mov_b32 rather than a copy of another initialized
// register. MachineCSE skips copies, and we don't want to have to
// fold operands before it runs.
def SI_INIT_M0 : SPseudoInstSI <(outs), (ins SSrc_b32:$src)> {
let Defs = [M0];
let usesCustomInserter = 1;
let isAsCheapAsAMove = 1;
let isReMaterializable = 1;
}
def SI_INIT_EXEC : SPseudoInstSI <
(outs), (ins i64imm:$src),
[(int_amdgcn_init_exec (i64 timm:$src))]> {
let Defs = [EXEC];
let isAsCheapAsAMove = 1;
}
def SI_INIT_EXEC_FROM_INPUT : SPseudoInstSI <
(outs), (ins SSrc_b32:$input, i32imm:$shift),
[(int_amdgcn_init_exec_from_input i32:$input, (i32 timm:$shift))]> {
let Defs = [EXEC];
}
// Return for returning shaders to a shader variant epilog.
def SI_RETURN_TO_EPILOG : SPseudoInstSI <
(outs), (ins variable_ops), [(AMDGPUreturn_to_epilog)]> {
let isTerminator = 1;
let isBarrier = 1;
let isReturn = 1;
let hasNoSchedulingInfo = 1;
let DisableWQM = 1;
let FixedSize = 1;
// TODO: Should this be true?
let isMeta = 0;
}
// Return for returning function calls.
def SI_RETURN : SPseudoInstSI <
(outs), (ins), [(AMDGPUret_glue)],
"; return"> {
let isTerminator = 1;
let isBarrier = 1;
let isReturn = 1;
let SchedRW = [WriteBranch];
}
// Return for returning function calls without output register.
//
// This version is only needed so we can fill in the output register
// in the custom inserter.
def SI_CALL_ISEL : SPseudoInstSI <
(outs), (ins SSrc_b64:$src0, unknown:$callee),
[(AMDGPUcall i64:$src0, tglobaladdr:$callee)]> {
let Size = 4;
let isCall = 1;
let SchedRW = [WriteBranch];
let usesCustomInserter = 1;
// TODO: Should really base this on the call target
let isConvergent = 1;
}
def : GCNPat<
(AMDGPUcall i64:$src0, (i64 0)),
(SI_CALL_ISEL $src0, (i64 0))
>;
// Wrapper around s_swappc_b64 with extra $callee parameter to track
// the called function after regalloc.
def SI_CALL : SPseudoInstSI <
(outs SReg_64:$dst), (ins SSrc_b64:$src0, unknown:$callee)> {
let Size = 4;
let FixedSize = 1;
let isCall = 1;
let UseNamedOperandTable = 1;
let SchedRW = [WriteBranch];
// TODO: Should really base this on the call target
let isConvergent = 1;
}
class SI_TCRETURN_Pseudo<RegisterClass rc, SDNode sd> : SPseudoInstSI <(outs),
(ins rc:$src0, unknown:$callee, i32imm:$fpdiff),
[(sd i64:$src0, tglobaladdr:$callee, i32:$fpdiff)]> {
let Size = 4;
let FixedSize = 1;
let isCall = 1;
let isTerminator = 1;
let isReturn = 1;
let isBarrier = 1;
let UseNamedOperandTable = 1;
let SchedRW = [WriteBranch];
// TODO: Should really base this on the call target
let isConvergent = 1;
}
// Tail call handling pseudo
def SI_TCRETURN : SI_TCRETURN_Pseudo<CCR_SGPR_64, AMDGPUtc_return>;
def SI_TCRETURN_GFX : SI_TCRETURN_Pseudo<Gfx_CCR_SGPR_64, AMDGPUtc_return_gfx>;
// Handle selecting indirect tail calls
def : GCNPat<
(AMDGPUtc_return i64:$src0, (i64 0), (i32 timm:$fpdiff)),
(SI_TCRETURN CCR_SGPR_64:$src0, (i64 0), i32imm:$fpdiff)
>;
// Handle selecting indirect tail calls for AMDGPU_gfx
def : GCNPat<
(AMDGPUtc_return_gfx i64:$src0, (i64 0), (i32 timm:$fpdiff)),
(SI_TCRETURN_GFX Gfx_CCR_SGPR_64:$src0, (i64 0), i32imm:$fpdiff)
>;
def ADJCALLSTACKUP : SPseudoInstSI<
(outs), (ins i32imm:$amt0, i32imm:$amt1),
[(callseq_start timm:$amt0, timm:$amt1)],
"; adjcallstackup $amt0 $amt1"> {
let Size = 8; // Worst case. (s_add_u32 + constant)
let FixedSize = 1;
let hasSideEffects = 1;
let usesCustomInserter = 1;
let SchedRW = [WriteSALU];
let Defs = [SCC];
}
def ADJCALLSTACKDOWN : SPseudoInstSI<
(outs), (ins i32imm:$amt1, i32imm:$amt2),
[(callseq_end timm:$amt1, timm:$amt2)],
"; adjcallstackdown $amt1"> {
let Size = 8; // Worst case. (s_add_u32 + constant)
let hasSideEffects = 1;
let usesCustomInserter = 1;
let SchedRW = [WriteSALU];
let Defs = [SCC];
}
let Defs = [M0, EXEC, SCC],
UseNamedOperandTable = 1 in {
// SI_INDIRECT_SRC/DST are only used by legacy SelectionDAG indirect
// addressing implementation.
class SI_INDIRECT_SRC<RegisterClass rc> : VPseudoInstSI <
(outs VGPR_32:$vdst),
(ins rc:$src, VS_32:$idx, i32imm:$offset)> {
let usesCustomInserter = 1;
}
class SI_INDIRECT_DST<RegisterClass rc> : VPseudoInstSI <
(outs rc:$vdst),
(ins rc:$src, VS_32:$idx, i32imm:$offset, VGPR_32:$val)> {
let Constraints = "$src = $vdst";
let usesCustomInserter = 1;
}
def SI_INDIRECT_SRC_V1 : SI_INDIRECT_SRC<VGPR_32>;
def SI_INDIRECT_SRC_V2 : SI_INDIRECT_SRC<VReg_64>;
def SI_INDIRECT_SRC_V4 : SI_INDIRECT_SRC<VReg_128>;
def SI_INDIRECT_SRC_V8 : SI_INDIRECT_SRC<VReg_256>;
def SI_INDIRECT_SRC_V9 : SI_INDIRECT_SRC<VReg_288>;
def SI_INDIRECT_SRC_V10 : SI_INDIRECT_SRC<VReg_320>;
def SI_INDIRECT_SRC_V11 : SI_INDIRECT_SRC<VReg_352>;
def SI_INDIRECT_SRC_V12 : SI_INDIRECT_SRC<VReg_384>;
def SI_INDIRECT_SRC_V16 : SI_INDIRECT_SRC<VReg_512>;
def SI_INDIRECT_SRC_V32 : SI_INDIRECT_SRC<VReg_1024>;
def SI_INDIRECT_DST_V1 : SI_INDIRECT_DST<VGPR_32>;
def SI_INDIRECT_DST_V2 : SI_INDIRECT_DST<VReg_64>;
def SI_INDIRECT_DST_V4 : SI_INDIRECT_DST<VReg_128>;
def SI_INDIRECT_DST_V8 : SI_INDIRECT_DST<VReg_256>;
def SI_INDIRECT_DST_V9 : SI_INDIRECT_DST<VReg_288>;
def SI_INDIRECT_DST_V10 : SI_INDIRECT_DST<VReg_320>;
def SI_INDIRECT_DST_V11 : SI_INDIRECT_DST<VReg_352>;
def SI_INDIRECT_DST_V12 : SI_INDIRECT_DST<VReg_384>;
def SI_INDIRECT_DST_V16 : SI_INDIRECT_DST<VReg_512>;
def SI_INDIRECT_DST_V32 : SI_INDIRECT_DST<VReg_1024>;
} // End Uses = [EXEC], Defs = [M0, EXEC]
// This is a pseudo variant of the v_movreld_b32 instruction in which the
// vector operand appears only twice, once as def and once as use. Using this
// pseudo avoids problems with the Two Address instructions pass.
class INDIRECT_REG_WRITE_MOVREL_pseudo<RegisterClass rc,
RegisterOperand val_ty> : PseudoInstSI <
(outs rc:$vdst), (ins rc:$vsrc, val_ty:$val, i32imm:$subreg)> {
let Constraints = "$vsrc = $vdst";
let Uses = [M0];
}
class V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<RegisterClass rc> :
INDIRECT_REG_WRITE_MOVREL_pseudo<rc, VSrc_b32> {
let VALU = 1;
let VOP1 = 1;
let Uses = [M0, EXEC];
}
class S_INDIRECT_REG_WRITE_MOVREL_pseudo<RegisterClass rc,
RegisterOperand val_ty> :
INDIRECT_REG_WRITE_MOVREL_pseudo<rc, val_ty> {
let SALU = 1;
let SOP1 = 1;
let Uses = [M0];
}
class S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<RegisterClass rc> :
S_INDIRECT_REG_WRITE_MOVREL_pseudo<rc, SSrc_b32>;
class S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<RegisterClass rc> :
S_INDIRECT_REG_WRITE_MOVREL_pseudo<rc, SSrc_b64>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V1 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VGPR_32>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V2 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_64>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V3 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_96>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V4 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_128>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V5 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_160>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V8 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_256>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V9 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_288>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V10 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_320>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V11 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_352>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V12 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_384>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V16 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_512>;
def V_INDIRECT_REG_WRITE_MOVREL_B32_V32 : V_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<VReg_1024>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V1 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_32>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V2 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_64>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V3 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_96>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V4 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_128>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V5 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_160>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V8 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_256>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V9 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_288>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V10 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_320>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V11 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_352>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V12 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_384>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V16 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_512>;
def S_INDIRECT_REG_WRITE_MOVREL_B32_V32 : S_INDIRECT_REG_WRITE_MOVREL_B32_pseudo<SReg_1024>;
def S_INDIRECT_REG_WRITE_MOVREL_B64_V1 : S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<SReg_64>;
def S_INDIRECT_REG_WRITE_MOVREL_B64_V2 : S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<SReg_128>;
def S_INDIRECT_REG_WRITE_MOVREL_B64_V4 : S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<SReg_256>;
def S_INDIRECT_REG_WRITE_MOVREL_B64_V8 : S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<SReg_512>;
def S_INDIRECT_REG_WRITE_MOVREL_B64_V16 : S_INDIRECT_REG_WRITE_MOVREL_B64_pseudo<SReg_1024>;
// These variants of V_INDIRECT_REG_READ/WRITE use VGPR indexing. By using these
// pseudos we avoid spills or copies being inserted within indirect sequences
// that switch the VGPR indexing mode. Spills to accvgprs could be effected by
// this mode switching.
class V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<RegisterClass rc> : PseudoInstSI <
(outs rc:$vdst), (ins rc:$vsrc, VSrc_b32:$val, SSrc_b32:$idx, i32imm:$subreg)> {
let Constraints = "$vsrc = $vdst";
let VALU = 1;
let Uses = [M0, EXEC];
let Defs = [M0];
}
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V1 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VGPR_32>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V2 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_64>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V3 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_96>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V4 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_128>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V5 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_160>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V8 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_256>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V9 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_288>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V10 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_320>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V11 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_352>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V12 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_384>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V16 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_512>;
def V_INDIRECT_REG_WRITE_GPR_IDX_B32_V32 : V_INDIRECT_REG_WRITE_GPR_IDX_pseudo<VReg_1024>;
class V_INDIRECT_REG_READ_GPR_IDX_pseudo<RegisterClass rc> : PseudoInstSI <
(outs VGPR_32:$vdst), (ins rc:$vsrc, SSrc_b32:$idx, i32imm:$subreg)> {
let VALU = 1;
let Uses = [M0, EXEC];
let Defs = [M0];
}
def V_INDIRECT_REG_READ_GPR_IDX_B32_V1 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VGPR_32>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V2 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_64>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V3 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_96>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V4 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_128>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V5 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_160>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V8 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_256>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V9 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_288>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V10 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_320>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V11 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_352>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V12 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_384>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V16 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_512>;
def V_INDIRECT_REG_READ_GPR_IDX_B32_V32 : V_INDIRECT_REG_READ_GPR_IDX_pseudo<VReg_1024>;
multiclass SI_SPILL_SGPR <RegisterClass sgpr_class> {
let UseNamedOperandTable = 1, SGPRSpill = 1, Uses = [EXEC] in {
def _SAVE : PseudoInstSI <
(outs),
(ins sgpr_class:$data, i32imm:$addr)> {
let mayStore = 1;
let mayLoad = 0;
}
def _RESTORE : PseudoInstSI <
(outs sgpr_class:$data),
(ins i32imm:$addr)> {
let mayStore = 0;
let mayLoad = 1;
}
} // End UseNamedOperandTable = 1
}
// You cannot use M0 as the output of v_readlane_b32 instructions or
// use it in the sdata operand of SMEM instructions. We still need to
// be able to spill the physical register m0, so allow it for
// SI_SPILL_32_* instructions.
defm SI_SPILL_S32 : SI_SPILL_SGPR <SReg_32>;
defm SI_SPILL_S64 : SI_SPILL_SGPR <SReg_64>;
defm SI_SPILL_S96 : SI_SPILL_SGPR <SReg_96>;
defm SI_SPILL_S128 : SI_SPILL_SGPR <SReg_128>;
defm SI_SPILL_S160 : SI_SPILL_SGPR <SReg_160>;
defm SI_SPILL_S192 : SI_SPILL_SGPR <SReg_192>;
defm SI_SPILL_S224 : SI_SPILL_SGPR <SReg_224>;
defm SI_SPILL_S256 : SI_SPILL_SGPR <SReg_256>;
defm SI_SPILL_S288 : SI_SPILL_SGPR <SReg_288>;
defm SI_SPILL_S320 : SI_SPILL_SGPR <SReg_320>;
defm SI_SPILL_S352 : SI_SPILL_SGPR <SReg_352>;
defm SI_SPILL_S384 : SI_SPILL_SGPR <SReg_384>;
defm SI_SPILL_S512 : SI_SPILL_SGPR <SReg_512>;
defm SI_SPILL_S1024 : SI_SPILL_SGPR <SReg_1024>;
// VGPR or AGPR spill instructions. In case of AGPR spilling a temp register
// needs to be used and an extra instruction to move between VGPR and AGPR.
// UsesTmp adds to the total size of an expanded spill in this case.
multiclass SI_SPILL_VGPR <RegisterClass vgpr_class, bit UsesTmp = 0> {
let UseNamedOperandTable = 1, VGPRSpill = 1,
SchedRW = [WriteVMEM] in {
def _SAVE : VPseudoInstSI <
(outs),
(ins vgpr_class:$vdata, i32imm:$vaddr,
SReg_32:$soffset, i32imm:$offset)> {
let mayStore = 1;
let mayLoad = 0;
// (2 * 4) + (8 * num_subregs) bytes maximum
int MaxSize = !add(!shl(!srl(vgpr_class.Size, 5), !add(UsesTmp, 3)), 8);
// Size field is unsigned char and cannot fit more.
let Size = !if(!le(MaxSize, 256), MaxSize, 252);
}
def _RESTORE : VPseudoInstSI <
(outs vgpr_class:$vdata),
(ins i32imm:$vaddr,
SReg_32:$soffset, i32imm:$offset)> {
let mayStore = 0;
let mayLoad = 1;
// (2 * 4) + (8 * num_subregs) bytes maximum
int MaxSize = !add(!shl(!srl(vgpr_class.Size, 5), !add(UsesTmp, 3)), 8);
// Size field is unsigned char and cannot fit more.
let Size = !if(!le(MaxSize, 256), MaxSize, 252);
}
} // End UseNamedOperandTable = 1, VGPRSpill = 1, SchedRW = [WriteVMEM]
}
defm SI_SPILL_V32 : SI_SPILL_VGPR <VGPR_32>;
defm SI_SPILL_V64 : SI_SPILL_VGPR <VReg_64>;
defm SI_SPILL_V96 : SI_SPILL_VGPR <VReg_96>;
defm SI_SPILL_V128 : SI_SPILL_VGPR <VReg_128>;
defm SI_SPILL_V160 : SI_SPILL_VGPR <VReg_160>;
defm SI_SPILL_V192 : SI_SPILL_VGPR <VReg_192>;
defm SI_SPILL_V224 : SI_SPILL_VGPR <VReg_224>;
defm SI_SPILL_V256 : SI_SPILL_VGPR <VReg_256>;
defm SI_SPILL_V288 : SI_SPILL_VGPR <VReg_288>;
defm SI_SPILL_V320 : SI_SPILL_VGPR <VReg_320>;
defm SI_SPILL_V352 : SI_SPILL_VGPR <VReg_352>;
defm SI_SPILL_V384 : SI_SPILL_VGPR <VReg_384>;
defm SI_SPILL_V512 : SI_SPILL_VGPR <VReg_512>;
defm SI_SPILL_V1024 : SI_SPILL_VGPR <VReg_1024>;
defm SI_SPILL_A32 : SI_SPILL_VGPR <AGPR_32, 1>;
defm SI_SPILL_A64 : SI_SPILL_VGPR <AReg_64, 1>;
defm SI_SPILL_A96 : SI_SPILL_VGPR <AReg_96, 1>;
defm SI_SPILL_A128 : SI_SPILL_VGPR <AReg_128, 1>;
defm SI_SPILL_A160 : SI_SPILL_VGPR <AReg_160, 1>;
defm SI_SPILL_A192 : SI_SPILL_VGPR <AReg_192, 1>;
defm SI_SPILL_A224 : SI_SPILL_VGPR <AReg_224, 1>;
defm SI_SPILL_A256 : SI_SPILL_VGPR <AReg_256, 1>;
defm SI_SPILL_A288 : SI_SPILL_VGPR <AReg_288, 1>;
defm SI_SPILL_A320 : SI_SPILL_VGPR <AReg_320, 1>;
defm SI_SPILL_A352 : SI_SPILL_VGPR <AReg_352, 1>;
defm SI_SPILL_A384 : SI_SPILL_VGPR <AReg_384, 1>;
defm SI_SPILL_A512 : SI_SPILL_VGPR <AReg_512, 1>;
defm SI_SPILL_A1024 : SI_SPILL_VGPR <AReg_1024, 1>;
defm SI_SPILL_AV32 : SI_SPILL_VGPR <AV_32, 1>;
defm SI_SPILL_AV64 : SI_SPILL_VGPR <AV_64, 1>;
defm SI_SPILL_AV96 : SI_SPILL_VGPR <AV_96, 1>;
defm SI_SPILL_AV128 : SI_SPILL_VGPR <AV_128, 1>;
defm SI_SPILL_AV160 : SI_SPILL_VGPR <AV_160, 1>;
defm SI_SPILL_AV192 : SI_SPILL_VGPR <AV_192, 1>;
defm SI_SPILL_AV224 : SI_SPILL_VGPR <AV_224, 1>;
defm SI_SPILL_AV256 : SI_SPILL_VGPR <AV_256, 1>;
defm SI_SPILL_AV288 : SI_SPILL_VGPR <AV_288, 1>;
defm SI_SPILL_AV320 : SI_SPILL_VGPR <AV_320, 1>;
defm SI_SPILL_AV352 : SI_SPILL_VGPR <AV_352, 1>;
defm SI_SPILL_AV384 : SI_SPILL_VGPR <AV_384, 1>;
defm SI_SPILL_AV512 : SI_SPILL_VGPR <AV_512, 1>;
defm SI_SPILL_AV1024 : SI_SPILL_VGPR <AV_1024, 1>;
def SI_PC_ADD_REL_OFFSET : SPseudoInstSI <
(outs SReg_64:$dst),
(ins si_ga:$ptr_lo, si_ga:$ptr_hi),
[(set SReg_64:$dst,
(i64 (SIpc_add_rel_offset tglobaladdr:$ptr_lo, tglobaladdr:$ptr_hi)))]> {
let Defs = [SCC];
}
def : GCNPat <
(SIpc_add_rel_offset tglobaladdr:$ptr_lo, 0),
(SI_PC_ADD_REL_OFFSET $ptr_lo, (i32 0))
>;
def : GCNPat<
(AMDGPUtrap timm:$trapid),
(S_TRAP $trapid)
>;
def : GCNPat<
(AMDGPUelse i1:$src, bb:$target),
(SI_ELSE $src, $target)
>;
def : Pat <
(int_amdgcn_kill i1:$src),
(SI_KILL_I1_PSEUDO SCSrc_i1:$src, 0)
>;
def : Pat <
(int_amdgcn_kill (i1 (not i1:$src))),
(SI_KILL_I1_PSEUDO SCSrc_i1:$src, -1)
>;
def : Pat <
(int_amdgcn_kill (i1 (setcc f32:$src, InlineImmFP32:$imm, cond:$cond))),
(SI_KILL_F32_COND_IMM_PSEUDO VSrc_b32:$src, (bitcast_fpimm_to_i32 $imm), (cond_as_i32imm $cond))
>;
def : Pat <
(int_amdgcn_wqm_demote i1:$src),
(SI_DEMOTE_I1 SCSrc_i1:$src, 0)
>;
def : Pat <
(int_amdgcn_wqm_demote (i1 (not i1:$src))),
(SI_DEMOTE_I1 SCSrc_i1:$src, -1)
>;
// TODO: we could add more variants for other types of conditionals
def : Pat <
(i64 (int_amdgcn_icmp i1:$src, (i1 0), (i32 33))),
(COPY $src) // Return the SGPRs representing i1 src
>;
def : Pat <
(i32 (int_amdgcn_icmp i1:$src, (i1 0), (i32 33))),
(COPY $src) // Return the SGPRs representing i1 src
>;
//===----------------------------------------------------------------------===//
// VOP1 Patterns
//===----------------------------------------------------------------------===//
multiclass f16_fp_Pats<Instruction cvt_f16_f32_inst_e64, Instruction cvt_f32_f16_inst_e64> {
// f16_to_fp patterns
def : GCNPat <
(f32 (f16_to_fp i32:$src0)),
(cvt_f32_f16_inst_e64 SRCMODS.NONE, $src0)
>;
def : GCNPat <
(f32 (f16_to_fp (and_oneuse i32:$src0, 0x7fff))),
(cvt_f32_f16_inst_e64 SRCMODS.ABS, $src0)
>;