llvm-project/llvm/lib/Target/Hexagon/HexagonIntrinsicsV4.td

300 lines
12 KiB
TableGen

//===- HexagonIntrinsicsV4.td - V4 Instruction intrinsics --*- tablegen -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
// This is populated based on the following specs:
// Hexagon V4 Architecture Extensions
// Application-Level Specification
// 80-V9418-12 Rev. A
// June 15, 2010
// Vector reduce multiply word by signed half (32x16)
//Rdd=vrmpyweh(Rss,Rtt)[:<<1]
def : T_PP_pat <M4_vrmpyeh_s0, int_hexagon_M4_vrmpyeh_s0>;
def : T_PP_pat <M4_vrmpyeh_s1, int_hexagon_M4_vrmpyeh_s1>;
//Rdd=vrmpywoh(Rss,Rtt)[:<<1]
def : T_PP_pat <M4_vrmpyoh_s0, int_hexagon_M4_vrmpyoh_s0>;
def : T_PP_pat <M4_vrmpyoh_s1, int_hexagon_M4_vrmpyoh_s1>;
//Rdd+=vrmpyweh(Rss,Rtt)[:<<1]
def : T_PPP_pat <M4_vrmpyeh_acc_s0, int_hexagon_M4_vrmpyeh_acc_s0>;
def : T_PPP_pat <M4_vrmpyeh_acc_s1, int_hexagon_M4_vrmpyeh_acc_s1>;
//Rdd=vrmpywoh(Rss,Rtt)[:<<1]
def : T_PPP_pat <M4_vrmpyoh_acc_s0, int_hexagon_M4_vrmpyoh_acc_s0>;
def : T_PPP_pat <M4_vrmpyoh_acc_s1, int_hexagon_M4_vrmpyoh_acc_s1>;
// Vector multiply halfwords, signed by unsigned
// Rdd=vmpyhsu(Rs,Rt)[:<<1]:sat
def : T_RR_pat <M2_vmpy2su_s0, int_hexagon_M2_vmpy2su_s0>;
def : T_RR_pat <M2_vmpy2su_s1, int_hexagon_M2_vmpy2su_s1>;
// Rxx+=vmpyhsu(Rs,Rt)[:<<1]:sat
def : T_PRR_pat <M2_vmac2su_s0, int_hexagon_M2_vmac2su_s0>;
def : T_PRR_pat <M2_vmac2su_s1, int_hexagon_M2_vmac2su_s1>;
// Vector polynomial multiply halfwords
// Rdd=vpmpyh(Rs,Rt)
def : T_RR_pat <M4_vpmpyh, int_hexagon_M4_vpmpyh>;
// Rxx[^]=vpmpyh(Rs,Rt)
def : T_PRR_pat <M4_vpmpyh_acc, int_hexagon_M4_vpmpyh_acc>;
// Polynomial multiply words
// Rdd=pmpyw(Rs,Rt)
def : T_RR_pat <M4_pmpyw, int_hexagon_M4_pmpyw>;
// Rxx^=pmpyw(Rs,Rt)
def : T_PRR_pat <M4_pmpyw_acc, int_hexagon_M4_pmpyw_acc>;
//Rxx^=asr(Rss,Rt)
def : T_PPR_pat <S2_asr_r_p_xor, int_hexagon_S2_asr_r_p_xor>;
//Rxx^=asl(Rss,Rt)
def : T_PPR_pat <S2_asl_r_p_xor, int_hexagon_S2_asl_r_p_xor>;
//Rxx^=lsr(Rss,Rt)
def : T_PPR_pat <S2_lsr_r_p_xor, int_hexagon_S2_lsr_r_p_xor>;
//Rxx^=lsl(Rss,Rt)
def : T_PPR_pat <S2_lsl_r_p_xor, int_hexagon_S2_lsl_r_p_xor>;
// Multiply and use upper result
def : MType_R32_pat <int_hexagon_M2_mpysu_up, M2_mpysu_up>;
def : MType_R32_pat <int_hexagon_M2_mpy_up_s1, M2_mpy_up_s1>;
def : MType_R32_pat <int_hexagon_M2_hmmpyh_s1, M2_hmmpyh_s1>;
def : MType_R32_pat <int_hexagon_M2_hmmpyl_s1, M2_hmmpyl_s1>;
def : MType_R32_pat <int_hexagon_M2_mpy_up_s1_sat, M2_mpy_up_s1_sat>;
// Vector reduce add unsigned halfwords
def : Pat <(int_hexagon_M2_vraddh DoubleRegs:$src1, DoubleRegs:$src2),
(M2_vraddh DoubleRegs:$src1, DoubleRegs:$src2)>;
def : T_P_pat <S2_brevp, int_hexagon_S2_brevp>;
def: T_P_pat <S2_ct0p, int_hexagon_S2_ct0p>;
def: T_P_pat <S2_ct1p, int_hexagon_S2_ct1p>;
def: T_RR_pat<C4_nbitsset, int_hexagon_C4_nbitsset>;
def: T_RR_pat<C4_nbitsclr, int_hexagon_C4_nbitsclr>;
def: T_RI_pat<C4_nbitsclri, int_hexagon_C4_nbitsclri>;
def : T_RR_pat<A4_cmpbeq, int_hexagon_A4_cmpbeq>;
def : T_RR_pat<A4_cmpbgt, int_hexagon_A4_cmpbgt>;
def : T_RR_pat<A4_cmpbgtu, int_hexagon_A4_cmpbgtu>;
def : T_RR_pat<A4_cmpheq, int_hexagon_A4_cmpheq>;
def : T_RR_pat<A4_cmphgt, int_hexagon_A4_cmphgt>;
def : T_RR_pat<A4_cmphgtu, int_hexagon_A4_cmphgtu>;
def : T_RI_pat<A4_cmpbeqi, int_hexagon_A4_cmpbeqi>;
def : T_RI_pat<A4_cmpbgti, int_hexagon_A4_cmpbgti>;
def : T_RI_pat<A4_cmpbgtui, int_hexagon_A4_cmpbgtui>;
def : T_RI_pat<A4_cmpheqi, int_hexagon_A4_cmpheqi>;
def : T_RI_pat<A4_cmphgti, int_hexagon_A4_cmphgti>;
def : T_RI_pat<A4_cmphgtui, int_hexagon_A4_cmphgtui>;
def : T_RP_pat <A4_boundscheck, int_hexagon_A4_boundscheck>;
def : T_PR_pat<A4_tlbmatch, int_hexagon_A4_tlbmatch>;
def : Pat <(int_hexagon_M4_mpyrr_addr IntRegs:$src1, IntRegs:$src2,
IntRegs:$src3),
(M4_mpyrr_addr IntRegs:$src1, IntRegs:$src2, IntRegs:$src3)>;
def : T_IRR_pat <M4_mpyrr_addi, int_hexagon_M4_mpyrr_addi>;
def : T_IRI_pat <M4_mpyri_addi, int_hexagon_M4_mpyri_addi>;
def : T_RIR_pat <M4_mpyri_addr_u2, int_hexagon_M4_mpyri_addr_u2>;
def : T_RRI_pat <M4_mpyri_addr, int_hexagon_M4_mpyri_addr>;
// Multiply 32x32 and use upper result
def : T_RRR_pat <M4_mac_up_s1_sat, int_hexagon_M4_mac_up_s1_sat>;
def : T_RRR_pat <M4_nac_up_s1_sat, int_hexagon_M4_nac_up_s1_sat>;
// Complex multiply 32x16
def : T_PR_pat <M4_cmpyi_wh, int_hexagon_M4_cmpyi_wh>;
def : T_PR_pat <M4_cmpyr_wh, int_hexagon_M4_cmpyr_wh>;
def : T_PR_pat <M4_cmpyi_whc, int_hexagon_M4_cmpyi_whc>;
def : T_PR_pat <M4_cmpyr_whc, int_hexagon_M4_cmpyr_whc>;
def : T_PP_pat<A4_andnp, int_hexagon_A4_andnp>;
def : T_PP_pat<A4_ornp, int_hexagon_A4_ornp>;
// Complex add/sub halfwords/words
def : T_PP_pat <S4_vxaddsubw, int_hexagon_S4_vxaddsubw>;
def : T_PP_pat <S4_vxsubaddw, int_hexagon_S4_vxsubaddw>;
def : T_PP_pat <S4_vxaddsubh, int_hexagon_S4_vxaddsubh>;
def : T_PP_pat <S4_vxsubaddh, int_hexagon_S4_vxsubaddh>;
def : T_PP_pat <S4_vxaddsubhr, int_hexagon_S4_vxaddsubhr>;
def : T_PP_pat <S4_vxsubaddhr, int_hexagon_S4_vxsubaddhr>;
// Extract bitfield
def : T_PP_pat <S4_extractp_rp, int_hexagon_S4_extractp_rp>;
def : T_RP_pat <S4_extract_rp, int_hexagon_S4_extract_rp>;
def : T_PII_pat <S4_extractp, int_hexagon_S4_extractp>;
def : T_RII_pat <S4_extract, int_hexagon_S4_extract>;
// Vector conditional negate
// Rdd=vcnegh(Rss,Rt)
def : T_PR_pat <S2_vcnegh, int_hexagon_S2_vcnegh>;
// Shift an immediate left by register amount
def : T_IR_pat<S4_lsli, int_hexagon_S4_lsli>;
// Vector reduce maximum halfwords
def : T_PPR_pat <A4_vrmaxh, int_hexagon_A4_vrmaxh>;
def : T_PPR_pat <A4_vrmaxuh, int_hexagon_A4_vrmaxuh>;
// Vector reduce maximum words
def : T_PPR_pat <A4_vrmaxw, int_hexagon_A4_vrmaxw>;
def : T_PPR_pat <A4_vrmaxuw, int_hexagon_A4_vrmaxuw>;
// Vector reduce minimum halfwords
def : T_PPR_pat <A4_vrminh, int_hexagon_A4_vrminh>;
def : T_PPR_pat <A4_vrminuh, int_hexagon_A4_vrminuh>;
// Vector reduce minimum words
def : T_PPR_pat <A4_vrminw, int_hexagon_A4_vrminw>;
def : T_PPR_pat <A4_vrminuw, int_hexagon_A4_vrminuw>;
// Rotate and reduce bytes
def : Pat <(int_hexagon_S4_vrcrotate DoubleRegs:$src1, IntRegs:$src2,
u2ImmPred:$src3),
(S4_vrcrotate DoubleRegs:$src1, IntRegs:$src2, u2ImmPred:$src3)>;
// Rotate and reduce bytes with accumulation
// Rxx+=vrcrotate(Rss,Rt,#u2)
def : Pat <(int_hexagon_S4_vrcrotate_acc DoubleRegs:$src1, DoubleRegs:$src2,
IntRegs:$src3, u2ImmPred:$src4),
(S4_vrcrotate_acc DoubleRegs:$src1, DoubleRegs:$src2,
IntRegs:$src3, u2ImmPred:$src4)>;
// Vector conditional negate
def : T_PPR_pat<S2_vrcnegh, int_hexagon_S2_vrcnegh>;
// Logical xor with xor accumulation
def : T_PPP_pat<M4_xor_xacc, int_hexagon_M4_xor_xacc>;
// ALU64 - Vector min/max byte
def : T_PP_pat <A2_vminb, int_hexagon_A2_vminb>;
def : T_PP_pat <A2_vmaxb, int_hexagon_A2_vmaxb>;
// Shift and add/sub/and/or
def : T_IRI_pat <S4_andi_asl_ri, int_hexagon_S4_andi_asl_ri>;
def : T_IRI_pat <S4_ori_asl_ri, int_hexagon_S4_ori_asl_ri>;
def : T_IRI_pat <S4_addi_asl_ri, int_hexagon_S4_addi_asl_ri>;
def : T_IRI_pat <S4_subi_asl_ri, int_hexagon_S4_subi_asl_ri>;
def : T_IRI_pat <S4_andi_lsr_ri, int_hexagon_S4_andi_lsr_ri>;
def : T_IRI_pat <S4_ori_lsr_ri, int_hexagon_S4_ori_lsr_ri>;
def : T_IRI_pat <S4_addi_lsr_ri, int_hexagon_S4_addi_lsr_ri>;
def : T_IRI_pat <S4_subi_lsr_ri, int_hexagon_S4_subi_lsr_ri>;
// Split bitfield
def : T_RI_pat <A4_bitspliti, int_hexagon_A4_bitspliti>;
def : T_RR_pat <A4_bitsplit, int_hexagon_A4_bitsplit>;
def: T_RR_pat<S4_parity, int_hexagon_S4_parity>;
def: T_RI_pat<S4_ntstbit_i, int_hexagon_S4_ntstbit_i>;
def: T_RR_pat<S4_ntstbit_r, int_hexagon_S4_ntstbit_r>;
def: T_RI_pat<S4_clbaddi, int_hexagon_S4_clbaddi>;
def: T_PI_pat<S4_clbpaddi, int_hexagon_S4_clbpaddi>;
def: T_P_pat <S4_clbpnorm, int_hexagon_S4_clbpnorm>;
/********************************************************************
* ALU32/ALU *
*********************************************************************/
// ALU32 / ALU / Logical Operations.
def: T_RR_pat<A4_andn, int_hexagon_A4_andn>;
def: T_RR_pat<A4_orn, int_hexagon_A4_orn>;
/********************************************************************
* ALU32/PERM *
*********************************************************************/
// Combine Words Into Doublewords.
def: T_RI_pat<A4_combineri, int_hexagon_A4_combineri, s8ExtPred>;
def: T_IR_pat<A4_combineir, int_hexagon_A4_combineir, s8ExtPred>;
/********************************************************************
* ALU32/PRED *
*********************************************************************/
// Compare
def : T_RI_pat<C4_cmpneqi, int_hexagon_C4_cmpneqi, s10ExtPred>;
def : T_RI_pat<C4_cmpltei, int_hexagon_C4_cmpltei, s10ExtPred>;
def : T_RI_pat<C4_cmplteui, int_hexagon_C4_cmplteui, u9ExtPred>;
def: T_RR_pat<A4_rcmpeq, int_hexagon_A4_rcmpeq>;
def: T_RR_pat<A4_rcmpneq, int_hexagon_A4_rcmpneq>;
def: T_RI_pat<A4_rcmpeqi, int_hexagon_A4_rcmpeqi>;
def: T_RI_pat<A4_rcmpneqi, int_hexagon_A4_rcmpneqi>;
/********************************************************************
* CR *
*********************************************************************/
// CR / Logical Operations On Predicates.
class qi_CRInst_qiqiqi_pat<Intrinsic IntID, InstHexagon Inst> :
Pat<(i32 (IntID IntRegs:$Rs, IntRegs:$Rt, IntRegs:$Ru)),
(i32 (C2_tfrpr (Inst (C2_tfrrp IntRegs:$Rs),
(C2_tfrrp IntRegs:$Rt),
(C2_tfrrp IntRegs:$Ru))))>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_and_and, C4_and_and>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_and_andn, C4_and_andn>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_and_or, C4_and_or>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_and_orn, C4_and_orn>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_or_and, C4_or_and>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_or_andn, C4_or_andn>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_or_or, C4_or_or>;
def: qi_CRInst_qiqiqi_pat<int_hexagon_C4_or_orn, C4_or_orn>;
/********************************************************************
* XTYPE/ALU *
*********************************************************************/
// Add And Accumulate.
def : T_RRI_pat <S4_addaddi, int_hexagon_S4_addaddi>;
def : T_RIR_pat <S4_subaddi, int_hexagon_S4_subaddi>;
// XTYPE / ALU / Logical-logical Words.
def : T_RRR_pat <M4_or_xor, int_hexagon_M4_or_xor>;
def : T_RRR_pat <M4_and_xor, int_hexagon_M4_and_xor>;
def : T_RRR_pat <M4_or_and, int_hexagon_M4_or_and>;
def : T_RRR_pat <M4_and_and, int_hexagon_M4_and_and>;
def : T_RRR_pat <M4_xor_and, int_hexagon_M4_xor_and>;
def : T_RRR_pat <M4_or_or, int_hexagon_M4_or_or>;
def : T_RRR_pat <M4_and_or, int_hexagon_M4_and_or>;
def : T_RRR_pat <M4_xor_or, int_hexagon_M4_xor_or>;
def : T_RRR_pat <M4_or_andn, int_hexagon_M4_or_andn>;
def : T_RRR_pat <M4_and_andn, int_hexagon_M4_and_andn>;
def : T_RRR_pat <M4_xor_andn, int_hexagon_M4_xor_andn>;
def : T_RRI_pat <S4_or_andi, int_hexagon_S4_or_andi>;
def : T_RRI_pat <S4_or_andix, int_hexagon_S4_or_andix>;
def : T_RRI_pat <S4_or_ori, int_hexagon_S4_or_ori>;
// Modulo wrap.
def : T_RR_pat <A4_modwrapu, int_hexagon_A4_modwrapu>;
// Arithmetic/Convergent round
// Rd=[cround|round](Rs,Rt)[:sat]
// Rd=[cround|round](Rs,#u5)[:sat]
def : T_RI_pat <A4_cround_ri, int_hexagon_A4_cround_ri>;
def : T_RR_pat <A4_cround_rr, int_hexagon_A4_cround_rr>;
def : T_RI_pat <A4_round_ri, int_hexagon_A4_round_ri>;
def : T_RR_pat <A4_round_rr, int_hexagon_A4_round_rr>;
def : T_RI_pat <A4_round_ri_sat, int_hexagon_A4_round_ri_sat>;
def : T_RR_pat <A4_round_rr_sat, int_hexagon_A4_round_rr_sat>;
def : T_P_pat <A2_roundsat, int_hexagon_A2_roundsat>;