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swiftshader / SwiftShader / 655fd07eaafc25f432be07c5010d94410965c6ec / . / third_party / llvm-10.0 / llvm / lib / Target / AMDGPU / SIRegisterInfo.td
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//===-- SIRegisterInfo.td - SI Register defs ---------------*- 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
//
//===----------------------------------------------------------------------===//
//===----------------------------------------------------------------------===//
// Helpers
//===----------------------------------------------------------------------===//
class getSubRegs<int size> {
list<SubRegIndex> ret2 = [sub0, sub1];
list<SubRegIndex> ret3 = [sub0, sub1, sub2];
list<SubRegIndex> ret4 = [sub0, sub1, sub2, sub3];
list<SubRegIndex> ret5 = [sub0, sub1, sub2, sub3, sub4];
list<SubRegIndex> ret8 = [sub0, sub1, sub2, sub3, sub4, sub5, sub6, sub7];
list<SubRegIndex> ret16 = [sub0, sub1, sub2, sub3,
sub4, sub5, sub6, sub7,
sub8, sub9, sub10, sub11,
sub12, sub13, sub14, sub15];
list<SubRegIndex> ret32 = [sub0, sub1, sub2, sub3,
sub4, sub5, sub6, sub7,
sub8, sub9, sub10, sub11,
sub12, sub13, sub14, sub15,
sub16, sub17, sub18, sub19,
sub20, sub21, sub22, sub23,
sub24, sub25, sub26, sub27,
sub28, sub29, sub30, sub31];
list<SubRegIndex> ret = !if(!eq(size, 2), ret2,
!if(!eq(size, 3), ret3,
!if(!eq(size, 4), ret4,
!if(!eq(size, 5), ret5,
!if(!eq(size, 8), ret8,
!if(!eq(size, 16), ret16, ret32))))));
}
// Generates list of sequential register tuple names.
// E.g. RegSeq<3,2,2,"s">.ret -> [ "s[0:1]", "s[2:3]" ]
class RegSeqNames<int last_reg, int stride, int size, string prefix,
int start = 0> {
int next = !add(start, stride);
int end_reg = !add(!add(start, size), -1);
list<string> ret =
!if(!le(end_reg, last_reg),
!listconcat([prefix # "[" # start # ":" # end_reg # "]"],
RegSeqNames<last_reg, stride, size, prefix, next>.ret),
[]);
}
// Generates list of dags for register tupless.
class RegSeqDags<RegisterClass RC, int last_reg, int stride, int size,
int start = 0> {
dag trunc_rc = (trunc RC,
!if(!and(!eq(stride, 1), !eq(start, 0)),
!add(!add(last_reg, 2), !mul(size, -1)),
!add(last_reg, 1)));
list<dag> ret =
!if(!lt(start, size),
!listconcat([(add (decimate (shl trunc_rc, start), stride))],
RegSeqDags<RC, last_reg, stride, size, !add(start, 1)>.ret),
[]);
}
class SIRegisterTuples<list<SubRegIndex> Indices, RegisterClass RC,
int last_reg, int stride, int size, string prefix> :
RegisterTuples<Indices,
RegSeqDags<RC, last_reg, stride, size>.ret,
RegSeqNames<last_reg, stride, size, prefix>.ret>;
//===----------------------------------------------------------------------===//
// Declarations that describe the SI registers
//===----------------------------------------------------------------------===//
class SIReg <string n, bits<16> regIdx = 0> :
Register<n>,
DwarfRegNum<[!cast<int>(HWEncoding)]> {
let Namespace = "AMDGPU";
// This is the not yet the complete register encoding. An additional
// bit is set for VGPRs.
let HWEncoding = regIdx;
}
// Special Registers
def VCC_LO : SIReg<"vcc_lo", 106>;
def VCC_HI : SIReg<"vcc_hi", 107>;
// Pseudo-registers: Used as placeholders during isel and immediately
// replaced, never seeing the verifier.
def PRIVATE_RSRC_REG : SIReg<"private_rsrc", 0>;
def FP_REG : SIReg<"fp", 0>;
def SP_REG : SIReg<"sp", 0>;
def SCRATCH_WAVE_OFFSET_REG : SIReg<"scratch_wave_offset", 0>;
// VCC for 64-bit instructions
def VCC : RegisterWithSubRegs<"vcc", [VCC_LO, VCC_HI]>,
DwarfRegAlias<VCC_LO> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = 106;
}
def EXEC_LO : SIReg<"exec_lo", 126>;
def EXEC_HI : SIReg<"exec_hi", 127>;
def EXEC : RegisterWithSubRegs<"exec", [EXEC_LO, EXEC_HI]>,
DwarfRegAlias<EXEC_LO> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = 126;
}
// 32-bit real registers, for MC only.
// May be used with both 32-bit and 64-bit operands.
def SRC_VCCZ : SIReg<"src_vccz", 251>;
def SRC_EXECZ : SIReg<"src_execz", 252>;
def SRC_SCC : SIReg<"src_scc", 253>;
// 1-bit pseudo register, for codegen only.
// Should never be emitted.
def SCC : SIReg<"scc">;
def M0 : SIReg <"m0", 124>;
def SGPR_NULL : SIReg<"null", 125>;
def SRC_SHARED_BASE : SIReg<"src_shared_base", 235>;
def SRC_SHARED_LIMIT : SIReg<"src_shared_limit", 236>;
def SRC_PRIVATE_BASE : SIReg<"src_private_base", 237>;
def SRC_PRIVATE_LIMIT : SIReg<"src_private_limit", 238>;
def SRC_POPS_EXITING_WAVE_ID : SIReg<"src_pops_exiting_wave_id", 239>;
def LDS_DIRECT : SIReg <"src_lds_direct", 254>;
def XNACK_MASK_LO : SIReg<"xnack_mask_lo", 104>;
def XNACK_MASK_HI : SIReg<"xnack_mask_hi", 105>;
def XNACK_MASK : RegisterWithSubRegs<"xnack_mask", [XNACK_MASK_LO, XNACK_MASK_HI]>,
DwarfRegAlias<XNACK_MASK_LO> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = 104;
}
// Trap handler registers
def TBA_LO : SIReg<"tba_lo", 108>;
def TBA_HI : SIReg<"tba_hi", 109>;
def TBA : RegisterWithSubRegs<"tba", [TBA_LO, TBA_HI]>,
DwarfRegAlias<TBA_LO> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = 108;
}
def TMA_LO : SIReg<"tma_lo", 110>;
def TMA_HI : SIReg<"tma_hi", 111>;
def TMA : RegisterWithSubRegs<"tma", [TMA_LO, TMA_HI]>,
DwarfRegAlias<TMA_LO> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = 110;
}
foreach Index = 0-15 in {
def TTMP#Index#_vi : SIReg<"ttmp"#Index, !add(112, Index)>;
def TTMP#Index#_gfx9_gfx10 : SIReg<"ttmp"#Index, !add(108, Index)>;
def TTMP#Index : SIReg<"ttmp"#Index, 0>;
}
multiclass FLAT_SCR_LOHI_m <string n, bits<16> ci_e, bits<16> vi_e> {
def _ci : SIReg<n, ci_e>;
def _vi : SIReg<n, vi_e>;
def "" : SIReg<n, 0>;
}
class FlatReg <Register lo, Register hi, bits<16> encoding> :
RegisterWithSubRegs<"flat_scratch", [lo, hi]>,
DwarfRegAlias<lo> {
let Namespace = "AMDGPU";
let SubRegIndices = [sub0, sub1];
let HWEncoding = encoding;
}
defm FLAT_SCR_LO : FLAT_SCR_LOHI_m<"flat_scratch_lo", 104, 102>; // Offset in units of 256-bytes.
defm FLAT_SCR_HI : FLAT_SCR_LOHI_m<"flat_scratch_hi", 105, 103>; // Size is the per-thread scratch size, in bytes.
def FLAT_SCR_ci : FlatReg<FLAT_SCR_LO_ci, FLAT_SCR_HI_ci, 104>;
def FLAT_SCR_vi : FlatReg<FLAT_SCR_LO_vi, FLAT_SCR_HI_vi, 102>;
def FLAT_SCR : FlatReg<FLAT_SCR_LO, FLAT_SCR_HI, 0>;
// SGPR registers
foreach Index = 0-105 in {
def SGPR#Index : SIReg <"s"#Index, Index>;
}
// VGPR registers
foreach Index = 0-255 in {
def VGPR#Index : SIReg <"v"#Index, Index> {
let HWEncoding{8} = 1;
}
}
// AccVGPR registers
foreach Index = 0-255 in {
def AGPR#Index : SIReg <"a"#Index, Index> {
let HWEncoding{8} = 1;
}
}
//===----------------------------------------------------------------------===//
// Groupings using register classes and tuples
//===----------------------------------------------------------------------===//
def SCC_CLASS : RegisterClass<"AMDGPU", [i1], 1, (add SCC)> {
let CopyCost = -1;
let isAllocatable = 0;
}
def M0_CLASS : RegisterClass<"AMDGPU", [i32], 32, (add M0)> {
let CopyCost = 1;
let isAllocatable = 0;
}
// TODO: Do we need to set DwarfRegAlias on register tuples?
// SGPR 32-bit registers
def SGPR_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add (sequence "SGPR%u", 0, 105))> {
// Give all SGPR classes higher priority than VGPR classes, because
// we want to spill SGPRs to VGPRs.
let AllocationPriority = 9;
}
// SGPR 64-bit registers
def SGPR_64Regs : SIRegisterTuples<getSubRegs<2>.ret, SGPR_32, 105, 2, 2, "s">;
// SGPR 96-bit registers. No operations use these, but for symmetry with 96-bit VGPRs.
def SGPR_96Regs : SIRegisterTuples<getSubRegs<3>.ret, SGPR_32, 105, 3, 3, "s">;
// SGPR 128-bit registers
def SGPR_128Regs : SIRegisterTuples<getSubRegs<4>.ret, SGPR_32, 105, 4, 4, "s">;
// SGPR 160-bit registers. No operations use these, but for symmetry with 160-bit VGPRs.
def SGPR_160Regs : SIRegisterTuples<getSubRegs<5>.ret, SGPR_32, 105, 4, 5, "s">;
// SGPR 256-bit registers
def SGPR_256Regs : SIRegisterTuples<getSubRegs<8>.ret, SGPR_32, 105, 4, 8, "s">;
// SGPR 512-bit registers
def SGPR_512Regs : SIRegisterTuples<getSubRegs<16>.ret, SGPR_32, 105, 4, 16, "s">;
// SGPR 1024-bit registers
def SGPR_1024Regs : SIRegisterTuples<getSubRegs<32>.ret, SGPR_32, 105, 4, 32, "s">;
// Trap handler TMP 32-bit registers
def TTMP_32 : RegisterClass<"AMDGPU", [i32, f32, v2i16, v2f16], 32,
(add (sequence "TTMP%u", 0, 15))> {
let isAllocatable = 0;
}
// Trap handler TMP 64-bit registers
def TTMP_64Regs : SIRegisterTuples<getSubRegs<2>.ret, TTMP_32, 15, 2, 2, "ttmp">;
// Trap handler TMP 128-bit registers
def TTMP_128Regs : SIRegisterTuples<getSubRegs<4>.ret, TTMP_32, 15, 4, 4, "ttmp">;
def TTMP_256Regs : SIRegisterTuples<getSubRegs<8>.ret, TTMP_32, 15, 4, 8, "ttmp">;
def TTMP_512Regs : SIRegisterTuples<getSubRegs<16>.ret, TTMP_32, 15, 4, 16, "ttmp">;
class TmpRegTuplesBase<int index, int size,
list<Register> subRegs,
list<SubRegIndex> indices = getSubRegs<size>.ret,
int index1 = !add(index, !add(size, -1)),
string name = "ttmp["#index#":"#index1#"]"> :
RegisterWithSubRegs<name, subRegs> {
let HWEncoding = subRegs[0].HWEncoding;
let SubRegIndices = indices;
}
class TmpRegTuples<string tgt,
int size,
int index0,
int index1 = !add(index0, 1),
int index2 = !add(index0, !if(!eq(size, 2), 1, 2)),
int index3 = !add(index0, !if(!eq(size, 2), 1, 3)),
int index4 = !add(index0, !if(!eq(size, 8), 4, 1)),
int index5 = !add(index0, !if(!eq(size, 8), 5, 1)),
int index6 = !add(index0, !if(!eq(size, 8), 6, 1)),
int index7 = !add(index0, !if(!eq(size, 8), 7, 1)),
Register r0 = !cast<Register>("TTMP"#index0#tgt),
Register r1 = !cast<Register>("TTMP"#index1#tgt),
Register r2 = !cast<Register>("TTMP"#index2#tgt),
Register r3 = !cast<Register>("TTMP"#index3#tgt),
Register r4 = !cast<Register>("TTMP"#index4#tgt),
Register r5 = !cast<Register>("TTMP"#index5#tgt),
Register r6 = !cast<Register>("TTMP"#index6#tgt),
Register r7 = !cast<Register>("TTMP"#index7#tgt)> :
TmpRegTuplesBase<index0, size,
!if(!eq(size, 2), [r0, r1],
!if(!eq(size, 4), [r0, r1, r2, r3],
[r0, r1, r2, r3, r4, r5, r6, r7])),
getSubRegs<size>.ret>;
foreach Index = {0, 2, 4, 6, 8, 10, 12, 14} in {
def TTMP#Index#_TTMP#!add(Index,1)#_vi : TmpRegTuples<"_vi", 2, Index>;
def TTMP#Index#_TTMP#!add(Index,1)#_gfx9_gfx10 : TmpRegTuples<"_gfx9_gfx10", 2, Index>;
}
foreach Index = {0, 4, 8, 12} in {
def TTMP#Index#_TTMP#!add(Index,1)#
_TTMP#!add(Index,2)#
_TTMP#!add(Index,3)#_vi : TmpRegTuples<"_vi", 4, Index>;
def TTMP#Index#_TTMP#!add(Index,1)#
_TTMP#!add(Index,2)#
_TTMP#!add(Index,3)#_gfx9_gfx10 : TmpRegTuples<"_gfx9_gfx10", 4, Index>;
}
foreach Index = {0, 4, 8} in {
def TTMP#Index#_TTMP#!add(Index,1)#
_TTMP#!add(Index,2)#
_TTMP#!add(Index,3)#
_TTMP#!add(Index,4)#
_TTMP#!add(Index,5)#
_TTMP#!add(Index,6)#
_TTMP#!add(Index,7)#_vi : TmpRegTuples<"_vi", 8, Index>;
def TTMP#Index#_TTMP#!add(Index,1)#
_TTMP#!add(Index,2)#
_TTMP#!add(Index,3)#
_TTMP#!add(Index,4)#
_TTMP#!add(Index,5)#
_TTMP#!add(Index,6)#
_TTMP#!add(Index,7)#_gfx9_gfx10 : TmpRegTuples<"_gfx9_gfx10", 8, Index>;
}
def TTMP0_TTMP1_TTMP2_TTMP3_TTMP4_TTMP5_TTMP6_TTMP7_TTMP8_TTMP9_TTMP10_TTMP11_TTMP12_TTMP13_TTMP14_TTMP15_vi :
TmpRegTuplesBase<0, 16,
[TTMP0_vi, TTMP1_vi, TTMP2_vi, TTMP3_vi,
TTMP4_vi, TTMP5_vi, TTMP6_vi, TTMP7_vi,
TTMP8_vi, TTMP9_vi, TTMP10_vi, TTMP11_vi,
TTMP12_vi, TTMP13_vi, TTMP14_vi, TTMP15_vi]>;
def TTMP0_TTMP1_TTMP2_TTMP3_TTMP4_TTMP5_TTMP6_TTMP7_TTMP8_TTMP9_TTMP10_TTMP11_TTMP12_TTMP13_TTMP14_TTMP15_gfx9_gfx10 :
TmpRegTuplesBase<0, 16,
[TTMP0_gfx9_gfx10, TTMP1_gfx9_gfx10, TTMP2_gfx9_gfx10, TTMP3_gfx9_gfx10,
TTMP4_gfx9_gfx10, TTMP5_gfx9_gfx10, TTMP6_gfx9_gfx10, TTMP7_gfx9_gfx10,
TTMP8_gfx9_gfx10, TTMP9_gfx9_gfx10, TTMP10_gfx9_gfx10, TTMP11_gfx9_gfx10,
TTMP12_gfx9_gfx10, TTMP13_gfx9_gfx10, TTMP14_gfx9_gfx10, TTMP15_gfx9_gfx10]>;
class RegisterTypes<list<ValueType> reg_types> {
list<ValueType> types = reg_types;
}
def Reg16Types : RegisterTypes<[i16, f16]>;
def Reg32Types : RegisterTypes<[i32, f32, v2i16, v2f16, p2, p3, p5, p6]>;
// VGPR 32-bit registers
// i16/f16 only on VI+
def VGPR_32 : RegisterClass<"AMDGPU", !listconcat(Reg32Types.types, Reg16Types.types), 32,
(add (sequence "VGPR%u", 0, 255))> {
let AllocationPriority = 1;
let Size = 32;
}
// VGPR 64-bit registers
def VGPR_64 : SIRegisterTuples<getSubRegs<2>.ret, VGPR_32, 255, 1, 2, "v">;
// VGPR 96-bit registers
def VGPR_96 : SIRegisterTuples<getSubRegs<3>.ret, VGPR_32, 255, 1, 3, "v">;
// VGPR 128-bit registers
def VGPR_128 : SIRegisterTuples<getSubRegs<4>.ret, VGPR_32, 255, 1, 4, "v">;
// VGPR 160-bit registers
def VGPR_160 : SIRegisterTuples<getSubRegs<5>.ret, VGPR_32, 255, 1, 5, "v">;
// VGPR 256-bit registers
def VGPR_256 : SIRegisterTuples<getSubRegs<8>.ret, VGPR_32, 255, 1, 8, "v">;
// VGPR 512-bit registers
def VGPR_512 : SIRegisterTuples<getSubRegs<16>.ret, VGPR_32, 255, 1, 16, "v">;
// VGPR 1024-bit registers
def VGPR_1024 : SIRegisterTuples<getSubRegs<32>.ret, VGPR_32, 255, 1, 32, "v">;
// AccVGPR 32-bit registers
def AGPR_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add (sequence "AGPR%u", 0, 255))> {
let AllocationPriority = 1;
let Size = 32;
}
// AGPR 64-bit registers
def AGPR_64 : SIRegisterTuples<getSubRegs<2>.ret, AGPR_32, 255, 1, 2, "a">;
// AGPR 128-bit registers
def AGPR_128 : SIRegisterTuples<getSubRegs<4>.ret, AGPR_32, 255, 1, 4, "a">;
// AGPR 512-bit registers
def AGPR_512 : SIRegisterTuples<getSubRegs<16>.ret, AGPR_32, 255, 1, 16, "a">;
// AGPR 1024-bit registers
def AGPR_1024 : SIRegisterTuples<getSubRegs<32>.ret, AGPR_32, 255, 1, 32, "a">;
//===----------------------------------------------------------------------===//
// Register classes used as source and destination
//===----------------------------------------------------------------------===//
def Pseudo_SReg_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add FP_REG, SP_REG, SCRATCH_WAVE_OFFSET_REG)> {
let isAllocatable = 0;
let CopyCost = -1;
}
def Pseudo_SReg_128 : RegisterClass<"AMDGPU", [v4i32, v2i64, v2f64], 32,
(add PRIVATE_RSRC_REG)> {
let isAllocatable = 0;
let CopyCost = -1;
}
def LDS_DIRECT_CLASS : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add LDS_DIRECT)> {
let isAllocatable = 0;
let CopyCost = -1;
}
// Subset of SReg_32 without M0 for SMRD instructions and alike.
// See comments in SIInstructions.td for more info.
def SReg_32_XM0_XEXEC : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16, i1], 32,
(add SGPR_32, VCC_LO, VCC_HI, FLAT_SCR_LO, FLAT_SCR_HI, XNACK_MASK_LO, XNACK_MASK_HI,
SGPR_NULL, TTMP_32, TMA_LO, TMA_HI, TBA_LO, TBA_HI, SRC_SHARED_BASE, SRC_SHARED_LIMIT,
SRC_PRIVATE_BASE, SRC_PRIVATE_LIMIT, SRC_POPS_EXITING_WAVE_ID,
SRC_VCCZ, SRC_EXECZ, SRC_SCC)> {
let AllocationPriority = 10;
}
def SReg_32_XEXEC_HI : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16, i1], 32,
(add SReg_32_XM0_XEXEC, EXEC_LO, M0_CLASS)> {
let AllocationPriority = 10;
}
def SReg_32_XM0 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16, i1], 32,
(add SReg_32_XM0_XEXEC, EXEC_LO, EXEC_HI)> {
let AllocationPriority = 10;
}
// Register class for all scalar registers (SGPRs + Special Registers)
def SReg_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16, i1], 32,
(add SReg_32_XM0, M0_CLASS, EXEC_LO, EXEC_HI, SReg_32_XEXEC_HI)> {
let AllocationPriority = 10;
}
def SRegOrLds_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16, i1], 32,
(add SReg_32_XM0, M0_CLASS, EXEC_LO, EXEC_HI, SReg_32_XEXEC_HI, LDS_DIRECT_CLASS)> {
let isAllocatable = 0;
}
def SGPR_64 : RegisterClass<"AMDGPU", [v2i32, i64, v2f32, f64, v4i16, v4f16], 32,
(add SGPR_64Regs)> {
let CopyCost = 1;
let AllocationPriority = 11;
}
// CCR (call clobbered registers) SGPR 64-bit registers
def CCR_SGPR_64 : RegisterClass<"AMDGPU", SGPR_64.RegTypes, 32,
(add (trunc SGPR_64, 16))> {
let CopyCost = SGPR_64.CopyCost;
let AllocationPriority = SGPR_64.AllocationPriority;
}
def TTMP_64 : RegisterClass<"AMDGPU", [v2i32, i64, f64, v4i16, v4f16], 32,
(add TTMP_64Regs)> {
let isAllocatable = 0;
}
def SReg_64_XEXEC : RegisterClass<"AMDGPU", [v2i32, i64, v2f32, f64, i1, v4i16, v4f16], 32,
(add SGPR_64, VCC, FLAT_SCR, XNACK_MASK, TTMP_64, TBA, TMA)> {
let CopyCost = 1;
let AllocationPriority = 13;
}
def SReg_64 : RegisterClass<"AMDGPU", [v2i32, i64, v2f32, f64, i1, v4i16, v4f16], 32,
(add SReg_64_XEXEC, EXEC)> {
let CopyCost = 1;
let AllocationPriority = 13;
}
def SReg_1_XEXEC : RegisterClass<"AMDGPU", [i1], 32,
(add SReg_64_XEXEC, SReg_32_XM0_XEXEC)> {
let CopyCost = 1;
let isAllocatable = 0;
}
def SReg_1 : RegisterClass<"AMDGPU", [i1], 32,
(add SReg_1_XEXEC, EXEC, EXEC_LO)> {
let CopyCost = 1;
let isAllocatable = 0;
}
// Requires 2 s_mov_b64 to copy
let CopyCost = 2 in {
// There are no 3-component scalar instructions, but this is needed
// for symmetry with VGPRs.
def SGPR_96 : RegisterClass<"AMDGPU", [v3i32, v3f32], 32,
(add SGPR_96Regs)> {
let AllocationPriority = 14;
}
def SReg_96 : RegisterClass<"AMDGPU", [v3i32, v3f32], 32,
(add SGPR_96)> {
let AllocationPriority = 14;
}
def SGPR_128 : RegisterClass<"AMDGPU", [v4i32, v4f32, v2i64], 32,
(add SGPR_128Regs)> {
let AllocationPriority = 15;
}
def TTMP_128 : RegisterClass<"AMDGPU", [v4i32, v4f32, v2i64], 32,
(add TTMP_128Regs)> {
let isAllocatable = 0;
}
def SReg_128 : RegisterClass<"AMDGPU", [v4i32, v4f32, v2i64, v2f64], 32,
(add SGPR_128, TTMP_128)> {
let AllocationPriority = 15;
let isAllocatable = 0;
}
} // End CopyCost = 2
// There are no 5-component scalar instructions, but this is needed
// for symmetry with VGPRs.
def SGPR_160 : RegisterClass<"AMDGPU", [v5i32, v5f32], 32,
(add SGPR_160Regs)> {
let AllocationPriority = 16;
}
def SReg_160 : RegisterClass<"AMDGPU", [v5i32, v5f32], 32,
(add SGPR_160)> {
let AllocationPriority = 16;
}
def SGPR_256 : RegisterClass<"AMDGPU", [v8i32, v8f32], 32, (add SGPR_256Regs)> {
let AllocationPriority = 17;
}
def TTMP_256 : RegisterClass<"AMDGPU", [v8i32, v8f32], 32, (add TTMP_256Regs)> {
let isAllocatable = 0;
}
def SReg_256 : RegisterClass<"AMDGPU", [v8i32, v8f32], 32,
(add SGPR_256, TTMP_256)> {
// Requires 4 s_mov_b64 to copy
let CopyCost = 4;
let AllocationPriority = 17;
}
def SGPR_512 : RegisterClass<"AMDGPU", [v16i32, v16f32], 32,
(add SGPR_512Regs)> {
let AllocationPriority = 18;
}
def TTMP_512 : RegisterClass<"AMDGPU", [v16i32, v16f32], 32,
(add TTMP_512Regs)> {
let isAllocatable = 0;
}
def SReg_512 : RegisterClass<"AMDGPU", [v16i32, v16f32], 32,
(add SGPR_512, TTMP_512)> {
// Requires 8 s_mov_b64 to copy
let CopyCost = 8;
let AllocationPriority = 18;
}
def VRegOrLds_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add VGPR_32, LDS_DIRECT_CLASS)> {
let isAllocatable = 0;
}
def SGPR_1024 : RegisterClass<"AMDGPU", [v32i32, v32f32], 32,
(add SGPR_1024Regs)> {
let AllocationPriority = 19;
}
def SReg_1024 : RegisterClass<"AMDGPU", [v32i32, v32f32], 32,
(add SGPR_1024)> {
let CopyCost = 16;
let AllocationPriority = 19;
}
// Register class for all vector registers (VGPRs + Interploation Registers)
def VReg_64 : RegisterClass<"AMDGPU", [i64, f64, v2i32, v2f32, v4f16, v4i16, p0, p1, p4], 32,
(add VGPR_64)> {
let Size = 64;
// Requires 2 v_mov_b32 to copy
let CopyCost = 2;
let AllocationPriority = 2;
}
def VReg_96 : RegisterClass<"AMDGPU", [v3i32, v3f32], 32, (add VGPR_96)> {
let Size = 96;
// Requires 3 v_mov_b32 to copy
let CopyCost = 3;
let AllocationPriority = 3;
}
def VReg_128 : RegisterClass<"AMDGPU", [v4i32, v4f32, v2i64, v2f64], 32,
(add VGPR_128)> {
let Size = 128;
// Requires 4 v_mov_b32 to copy
let CopyCost = 4;
let AllocationPriority = 4;
}
def VReg_160 : RegisterClass<"AMDGPU", [v5i32, v5f32], 32,
(add VGPR_160)> {
let Size = 160;
// Requires 5 v_mov_b32 to copy
let CopyCost = 5;
let AllocationPriority = 5;
}
def VReg_256 : RegisterClass<"AMDGPU", [v8i32, v8f32], 32,
(add VGPR_256)> {
let Size = 256;
let CopyCost = 8;
let AllocationPriority = 6;
}
def VReg_512 : RegisterClass<"AMDGPU", [v16i32, v16f32], 32,
(add VGPR_512)> {
let Size = 512;
let CopyCost = 16;
let AllocationPriority = 7;
}
def VReg_1024 : RegisterClass<"AMDGPU", [v32i32, v32f32], 32,
(add VGPR_1024)> {
let Size = 1024;
let CopyCost = 32;
let AllocationPriority = 8;
}
def AReg_64 : RegisterClass<"AMDGPU", [i64, f64, v2i32, v2f32, v4f16, v4i16], 32,
(add AGPR_64)> {
let Size = 64;
let CopyCost = 5;
let AllocationPriority = 2;
}
def AReg_128 : RegisterClass<"AMDGPU", [v4i32, v4f32, v2i64, v2f64], 32,
(add AGPR_128)> {
let Size = 128;
// Requires 4 v_accvgpr_write and 4 v_accvgpr_read to copy + burn 1 vgpr
let CopyCost = 9;
let AllocationPriority = 4;
}
def AReg_512 : RegisterClass<"AMDGPU", [v16i32, v16f32], 32,
(add AGPR_512)> {
let Size = 512;
let CopyCost = 33;
let AllocationPriority = 7;
}
def AReg_1024 : RegisterClass<"AMDGPU", [v32i32, v32f32], 32,
(add AGPR_1024)> {
let Size = 1024;
let CopyCost = 65;
let AllocationPriority = 8;
}
// This is not a real register. This is just to have a register to add
// to VReg_1 that does not alias any real register that would
// introduce inferred register classess.
def ARTIFICIAL_VGPR : SIReg <"invalid vgpr", 0> {
let isArtificial = 1;
}
// FIXME: Should specify an empty set for this. No register should
// ever be allocated using VReg_1. This is a hack for SelectionDAG
// that should always be lowered by SILowerI1Copies. TableGen crashes
// on an empty register set, but also sorts register classes based on
// the number of registerss in them. Add only one register so this is
// sorted to the end and not preferred over VGPR_32.
def VReg_1 : RegisterClass<"AMDGPU", [i1], 32, (add ARTIFICIAL_VGPR)> {
let Size = 1;
}
def VS_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add VGPR_32, SReg_32, LDS_DIRECT_CLASS)> {
let isAllocatable = 0;
}
def VS_64 : RegisterClass<"AMDGPU", [i64, f64], 32, (add VReg_64, SReg_64)> {
let isAllocatable = 0;
}
def AV_32 : RegisterClass<"AMDGPU", [i32, f32, i16, f16, v2i16, v2f16], 32,
(add AGPR_32, VGPR_32)> {
let isAllocatable = 0;
}
def AV_64 : RegisterClass<"AMDGPU", [i64, f64, v4f16], 32,
(add AReg_64, VReg_64)> {
let isAllocatable = 0;
}
//===----------------------------------------------------------------------===//
// Register operands
//===----------------------------------------------------------------------===//
class RegImmMatcher<string name> : AsmOperandClass {
let Name = name;
let RenderMethod = "addRegOrImmOperands";
}
multiclass SIRegOperand32 <string rc, string MatchName, string opType,
string rc_suffix = "_32"> {
let OperandNamespace = "AMDGPU" in {
def _b16 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_INT16";
let ParserMatchClass = RegImmMatcher<MatchName#"B16">;
let DecoderMethod = "decodeOperand_VSrc16";
}
def _f16 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_FP16";
let ParserMatchClass = RegImmMatcher<MatchName#"F16">;
let DecoderMethod = "decodeOperand_" # rc # "_16";
}
def _b32 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_INT32";
let ParserMatchClass = RegImmMatcher<MatchName#"B32">;
let DecoderMethod = "decodeOperand_" # rc # rc_suffix;
}
def _f32 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_FP32";
let ParserMatchClass = RegImmMatcher<MatchName#"F32">;
let DecoderMethod = "decodeOperand_" # rc # rc_suffix;
}
def _v2b16 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_V2INT16";
let ParserMatchClass = RegImmMatcher<MatchName#"V2B16">;
let DecoderMethod = "decodeOperand_VSrcV216";
}
def _v2f16 : RegisterOperand<!cast<RegisterClass>(rc#rc_suffix)> {
let OperandType = opType#"_V2FP16";
let ParserMatchClass = RegImmMatcher<MatchName#"V2F16">;
let DecoderMethod = "decodeOperand_VSrcV216";
}
}
}
multiclass SIRegOperand <string rc, string MatchName, string opType> :
SIRegOperand32<rc, MatchName, opType> {
let OperandNamespace = "AMDGPU" in {
def _b64 : RegisterOperand<!cast<RegisterClass>(rc#"_64")> {
let OperandType = opType#"_INT64";
let ParserMatchClass = RegImmMatcher<MatchName#"B64">;
}
def _f64 : RegisterOperand<!cast<RegisterClass>(rc#"_64")> {
let OperandType = opType#"_FP64";
let ParserMatchClass = RegImmMatcher<MatchName#"F64">;
}
}
}
// FIXME: 64-bit sources can sometimes use 32-bit constants.
multiclass RegImmOperand <string rc, string MatchName>
: SIRegOperand<rc, MatchName, "OPERAND_REG_IMM">;
multiclass RegInlineOperand <string rc, string MatchName>
: SIRegOperand<rc, MatchName, "OPERAND_REG_INLINE_C">;
multiclass RegInlineOperand32 <string rc, string MatchName,
string rc_suffix = "_32">
: SIRegOperand32<rc, MatchName, "OPERAND_REG_INLINE_C", rc_suffix>;
multiclass RegInlineOperandAC <string rc, string MatchName,
string rc_suffix = "_32">
: SIRegOperand32<rc, MatchName, "OPERAND_REG_INLINE_AC", rc_suffix>;
//===----------------------------------------------------------------------===//
// SSrc_* Operands with an SGPR or a 32-bit immediate
//===----------------------------------------------------------------------===//
defm SSrc : RegImmOperand<"SReg", "SSrc">;
def SSrcOrLds_b32 : RegisterOperand<SRegOrLds_32> {
let OperandNamespace = "AMDGPU";
let OperandType = "OPERAND_REG_IMM_INT32";
let ParserMatchClass = RegImmMatcher<"SSrcOrLdsB32">;
}
//===----------------------------------------------------------------------===//
// SCSrc_* Operands with an SGPR or a inline constant
//===----------------------------------------------------------------------===//
defm SCSrc : RegInlineOperand<"SReg", "SCSrc"> ;
//===----------------------------------------------------------------------===//
// VSrc_* Operands with an SGPR, VGPR or a 32-bit immediate
//===----------------------------------------------------------------------===//
defm VSrc : RegImmOperand<"VS", "VSrc">;
def VSrc_128 : RegisterOperand<VReg_128> {
let DecoderMethod = "DecodeVS_128RegisterClass";
}
//===----------------------------------------------------------------------===//
// VSrc_* Operands with an VGPR
//===----------------------------------------------------------------------===//
// This is for operands with the enum(9), VSrc encoding restriction,
// but only allows VGPRs.
def VRegSrc_32 : RegisterOperand<VGPR_32> {
//let ParserMatchClass = RegImmMatcher<"VRegSrc32">;
let DecoderMethod = "DecodeVS_32RegisterClass";
}
//===----------------------------------------------------------------------===//
// ASrc_* Operands with an AccVGPR
//===----------------------------------------------------------------------===//
def ARegSrc_32 : RegisterOperand<AGPR_32> {
let DecoderMethod = "DecodeAGPR_32RegisterClass";
let EncoderMethod = "getAVOperandEncoding";
}
//===----------------------------------------------------------------------===//
// VCSrc_* Operands with an SGPR, VGPR or an inline constant
//===----------------------------------------------------------------------===//
defm VCSrc : RegInlineOperand<"VS", "VCSrc">;
//===----------------------------------------------------------------------===//
// VISrc_* Operands with a VGPR or an inline constant
//===----------------------------------------------------------------------===//
defm VISrc : RegInlineOperand32<"VGPR", "VISrc">;
//===----------------------------------------------------------------------===//
// AVSrc_* Operands with an AGPR or VGPR
//===----------------------------------------------------------------------===//
def AVSrc_32 : RegisterOperand<AV_32> {
let DecoderMethod = "DecodeAV_32RegisterClass";
let EncoderMethod = "getAVOperandEncoding";
}
def AVSrc_64 : RegisterOperand<AV_64> {
let DecoderMethod = "DecodeAV_64RegisterClass";
let EncoderMethod = "getAVOperandEncoding";
}
//===----------------------------------------------------------------------===//
// ACSrc_* Operands with an AGPR or an inline constant
//===----------------------------------------------------------------------===//
defm AISrc : RegInlineOperandAC<"AGPR", "AISrc">;
defm AISrc_128 : RegInlineOperandAC<"AReg", "AISrc_128", "_128">;
defm AISrc_512 : RegInlineOperandAC<"AReg", "AISrc_512", "_512">;
defm AISrc_1024 : RegInlineOperandAC<"AReg", "AISrc_1024", "_1024">;