blob: 12d2aac5d4c3061eaa06791a2d0b07a361676259 [file] [log] [blame]
/*
* Copyright(c) 2019-2021 Qualcomm Innovation Center, Inc. All Rights Reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, see <http://www.gnu.org/licenses/>.
*/
/*
* ALU Instructions
*/
/**********************************************/
/* Add/Sub instructions */
/**********************************************/
Q6INSN(A2_add,"Rd32=add(Rs32,Rt32)",ATTRIBS(),
"Add 32-bit registers",
{ RdV=RsV+RtV;})
Q6INSN(A2_sub,"Rd32=sub(Rt32,Rs32)",ATTRIBS(),
"Subtract 32-bit registers",
{ RdV=RtV-RsV;})
#define COND_ALU(TAG,OPER,DESCR,SEMANTICS)\
Q6INSN(TAG##t,"if (Pu4) "OPER,ATTRIBS(A_ARCHV2),DESCR,{if(fLSBOLD(PuV)){SEMANTICS;} else {CANCEL;}})\
Q6INSN(TAG##f,"if (!Pu4) "OPER,ATTRIBS(A_ARCHV2),DESCR,{if(fLSBOLDNOT(PuV)){SEMANTICS;} else {CANCEL;}})\
Q6INSN(TAG##tnew,"if (Pu4.new) " OPER,ATTRIBS(A_ARCHV2),DESCR,{if(fLSBNEW(PuN)){SEMANTICS;} else {CANCEL;}})\
Q6INSN(TAG##fnew,"if (!Pu4.new) "OPER,ATTRIBS(A_ARCHV2),DESCR,{if(fLSBNEWNOT(PuN)){SEMANTICS;} else {CANCEL;}})
COND_ALU(A2_padd,"Rd32=add(Rs32,Rt32)","Conditionally Add 32-bit registers",RdV=RsV+RtV)
COND_ALU(A2_psub,"Rd32=sub(Rt32,Rs32)","Conditionally Subtract 32-bit registers",RdV=RtV-RsV)
COND_ALU(A2_paddi,"Rd32=add(Rs32,#s8)","Conditionally Add Register and immediate",fIMMEXT(siV); RdV=RsV+siV)
COND_ALU(A2_pxor,"Rd32=xor(Rs32,Rt32)","Conditionally XOR registers",RdV=RsV^RtV)
COND_ALU(A2_pand,"Rd32=and(Rs32,Rt32)","Conditionally AND registers",RdV=RsV&RtV)
COND_ALU(A2_por,"Rd32=or(Rs32,Rt32)","Conditionally OR registers",RdV=RsV|RtV)
COND_ALU(A4_psxtb,"Rd32=sxtb(Rs32)","Conditionally sign-extend byte", RdV=fSXTN(8,32,RsV))
COND_ALU(A4_pzxtb,"Rd32=zxtb(Rs32)","Conditionally zero-extend byte", RdV=fZXTN(8,32,RsV))
COND_ALU(A4_psxth,"Rd32=sxth(Rs32)","Conditionally sign-extend halfword", RdV=fSXTN(16,32,RsV))
COND_ALU(A4_pzxth,"Rd32=zxth(Rs32)","Conditionally zero-extend halfword", RdV=fZXTN(16,32,RsV))
COND_ALU(A4_paslh,"Rd32=aslh(Rs32)","Conditionally zero-extend halfword", RdV=RsV<<16)
COND_ALU(A4_pasrh,"Rd32=asrh(Rs32)","Conditionally zero-extend halfword", RdV=RsV>>16)
Q6INSN(A2_addsat,"Rd32=add(Rs32,Rt32):sat",ATTRIBS(),
"Add 32-bit registers with saturation",
{ RdV=fSAT(fSE32_64(RsV)+fSE32_64(RtV)); })
Q6INSN(A2_subsat,"Rd32=sub(Rt32,Rs32):sat",ATTRIBS(),
"Subtract 32-bit registers with saturation",
{ RdV=fSAT(fSE32_64(RtV) - fSE32_64(RsV)); })
Q6INSN(A2_addi,"Rd32=add(Rs32,#s16)",ATTRIBS(),
"Add a signed immediate to a register",
{ fIMMEXT(siV); RdV=RsV+siV;})
Q6INSN(C4_addipc,"Rd32=add(pc,#u6)",ATTRIBS(),
"Add immediate to PC",
{ RdV=fREAD_PC()+fIMMEXT(uiV);})
/**********************************************/
/* Single-precision HL forms */
/* These insns and the SP mpy are the ones */
/* that can do .HL stuff */
/**********************************************/
#define STD_HL_INSN(TAG,OPER,AOPER,ATR,SEM)\
Q6INSN(A2_##TAG##_ll, OPER"(Rt.L32,Rs.L32)"AOPER, ATR,"",{SEM(fGETHALF(0,RtV),fGETHALF(0,RsV));})\
Q6INSN(A2_##TAG##_lh, OPER"(Rt.L32,Rs.H32)"AOPER, ATR,"",{SEM(fGETHALF(0,RtV),fGETHALF(1,RsV));})\
Q6INSN(A2_##TAG##_hl, OPER"(Rt.H32,Rs.L32)"AOPER, ATR,"",{SEM(fGETHALF(1,RtV),fGETHALF(0,RsV));})\
Q6INSN(A2_##TAG##_hh, OPER"(Rt.H32,Rs.H32)"AOPER, ATR,"",{SEM(fGETHALF(1,RtV),fGETHALF(1,RsV));})
#define SUBSTD_HL_INSN(TAG,OPER,AOPER,ATR,SEM)\
Q6INSN(A2_##TAG##_ll, OPER"(Rt.L32,Rs.L32)"AOPER, ATR,"",{SEM(fGETHALF(0,RtV),fGETHALF(0,RsV));})\
Q6INSN(A2_##TAG##_hl, OPER"(Rt.L32,Rs.H32)"AOPER, ATR,"",{SEM(fGETHALF(0,RtV),fGETHALF(1,RsV));})
#undef HLSEM
#define HLSEM(A,B) RdV=fSXTN(16,32,(A+B))
SUBSTD_HL_INSN(addh_l16,"Rd32=add","",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=fSATH(A+B)
SUBSTD_HL_INSN(addh_l16_sat,"Rd32=add",":sat",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=fSXTN(16,32,(A-B))
SUBSTD_HL_INSN(subh_l16,"Rd32=sub","",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=fSATH(A-B)
SUBSTD_HL_INSN(subh_l16_sat,"Rd32=sub",":sat",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=(A+B)<<16
STD_HL_INSN(addh_h16,"Rd32=add",":<<16",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=(fSATH(A+B))<<16
STD_HL_INSN(addh_h16_sat,"Rd32=add",":sat:<<16",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=(A-B)<<16
STD_HL_INSN(subh_h16,"Rd32=sub",":<<16",ATTRIBS(),HLSEM)
#undef HLSEM
#define HLSEM(A,B) RdV=(fSATH(A-B))<<16
STD_HL_INSN(subh_h16_sat,"Rd32=sub",":sat:<<16",ATTRIBS(),HLSEM)
Q6INSN(A2_aslh,"Rd32=aslh(Rs32)",ATTRIBS(),
"Arithmetic Shift Left by Halfword",{ RdV=RsV<<16; })
Q6INSN(A2_asrh,"Rd32=asrh(Rs32)",ATTRIBS(),
"Arithmetic Shift Right by Halfword",{ RdV=RsV>>16; })
/* 64-bit versions */
Q6INSN(A2_addp,"Rdd32=add(Rss32,Rtt32)",ATTRIBS(),
"Add",
{ RddV=RssV+RttV;})
Q6INSN(A2_addpsat,"Rdd32=add(Rss32,Rtt32):sat",ATTRIBS(A_ARCHV3),
"Add",
{ fADDSAT64(RddV,RssV,RttV);})
Q6INSN(A2_addspl,"Rdd32=add(Rss32,Rtt32):raw:lo",ATTRIBS(A_ARCHV3),
"Add",
{ RddV=RttV+fSXTN(32,64,fGETWORD(0,RssV));})
Q6INSN(A2_addsph,"Rdd32=add(Rss32,Rtt32):raw:hi",ATTRIBS(A_ARCHV3),
"Add",
{ RddV=RttV+fSXTN(32,64,fGETWORD(1,RssV));})
Q6INSN(A2_subp,"Rdd32=sub(Rtt32,Rss32)",ATTRIBS(),
"Sub",
{ RddV=RttV-RssV;})
/* 64-bit with carry */
Q6INSN(A4_addp_c,"Rdd32=add(Rss32,Rtt32,Px4):carry",ATTRIBS(),"Add with Carry",
{
RddV = RssV + RttV + fLSBOLD(PxV);
PxV = f8BITSOF(fCARRY_FROM_ADD(RssV,RttV,fLSBOLD(PxV)));
})
Q6INSN(A4_subp_c,"Rdd32=sub(Rss32,Rtt32,Px4):carry",ATTRIBS(),"Sub with Carry",
{
RddV = RssV + ~RttV + fLSBOLD(PxV);
PxV = f8BITSOF(fCARRY_FROM_ADD(RssV,~RttV,fLSBOLD(PxV)));
})
/* NEG and ABS */
Q6INSN(A2_negsat,"Rd32=neg(Rs32):sat",ATTRIBS(),
"Arithmetic negate register", { RdV = fSAT(-fCAST8s(RsV)); })
Q6INSN(A2_abs,"Rd32=abs(Rs32)",ATTRIBS(),
"Absolute Value register", { RdV = fABS(RsV); })
Q6INSN(A2_abssat,"Rd32=abs(Rs32):sat",ATTRIBS(),
"Arithmetic negate register", { RdV = fSAT(fABS(fCAST4_8s(RsV))); })
Q6INSN(A2_vconj,"Rdd32=vconj(Rss32):sat",ATTRIBS(A_ARCHV2),
"Vector Complex conjugate of Rss",
{ fSETHALF(1,RddV,fSATN(16,-fGETHALF(1,RssV)));
fSETHALF(0,RddV,fGETHALF(0,RssV));
fSETHALF(3,RddV,fSATN(16,-fGETHALF(3,RssV)));
fSETHALF(2,RddV,fGETHALF(2,RssV));
})
/* 64-bit versions */
Q6INSN(A2_negp,"Rdd32=neg(Rss32)",ATTRIBS(),
"Arithmetic negate register", { RddV = -RssV; })
Q6INSN(A2_absp,"Rdd32=abs(Rss32)",ATTRIBS(),
"Absolute Value register", { RddV = fABS(RssV); })
/* MIN and MAX R */
Q6INSN(A2_max,"Rd32=max(Rs32,Rt32)",ATTRIBS(),
"Maximum of two registers",
{ RdV = fMAX(RsV,RtV); })
Q6INSN(A2_maxu,"Rd32=maxu(Rs32,Rt32)",ATTRIBS(),
"Maximum of two registers (unsigned)",
{ RdV = fMAX(fCAST4u(RsV),fCAST4u(RtV)); })
Q6INSN(A2_min,"Rd32=min(Rt32,Rs32)",ATTRIBS(),
"Minimum of two registers",
{ RdV = fMIN(RtV,RsV); })
Q6INSN(A2_minu,"Rd32=minu(Rt32,Rs32)",ATTRIBS(),
"Minimum of two registers (unsigned)",
{ RdV = fMIN(fCAST4u(RtV),fCAST4u(RsV)); })
/* MIN and MAX Pairs */
#if 1
Q6INSN(A2_maxp,"Rdd32=max(Rss32,Rtt32)",ATTRIBS(A_ARCHV3),
"Maximum of two register pairs",
{ RddV = fMAX(RssV,RttV); })
Q6INSN(A2_maxup,"Rdd32=maxu(Rss32,Rtt32)",ATTRIBS(A_ARCHV3),
"Maximum of two register pairs (unsigned)",
{ RddV = fMAX(fCAST8u(RssV),fCAST8u(RttV)); })
Q6INSN(A2_minp,"Rdd32=min(Rtt32,Rss32)",ATTRIBS(A_ARCHV3),
"Minimum of two register pairs",
{ RddV = fMIN(RttV,RssV); })
Q6INSN(A2_minup,"Rdd32=minu(Rtt32,Rss32)",ATTRIBS(A_ARCHV3),
"Minimum of two register pairs (unsigned)",
{ RddV = fMIN(fCAST8u(RttV),fCAST8u(RssV)); })
#endif
/**********************************************/
/* Register and Immediate Transfers */
/**********************************************/
Q6INSN(A2_nop,"nop",ATTRIBS(A_IT_NOP),
"Nop (32-bit encoding)",
fHIDE( { } ))
Q6INSN(A4_ext,"immext(#u26:6)",ATTRIBS(A_IT_EXTENDER),
"This instruction carries the 26 most-significant immediate bits for the next instruction",
{ fHIDE(); })
Q6INSN(A2_tfr,"Rd32=Rs32",ATTRIBS(),
"tfr register",{ RdV=RsV;})
Q6INSN(A2_tfrsi,"Rd32=#s16",ATTRIBS(),
"transfer signed immediate to register",{ fIMMEXT(siV); RdV=siV;})
Q6INSN(A2_sxtb,"Rd32=sxtb(Rs32)",ATTRIBS(),
"Sign extend byte", {RdV = fSXTN(8,32,RsV);})
Q6INSN(A2_zxth,"Rd32=zxth(Rs32)",ATTRIBS(),
"Zero extend half", {RdV = fZXTN(16,32,RsV);})
Q6INSN(A2_sxth,"Rd32=sxth(Rs32)",ATTRIBS(),
"Sign extend half", {RdV = fSXTN(16,32,RsV);})
Q6INSN(A2_combinew,"Rdd32=combine(Rs32,Rt32)",ATTRIBS(),
"Combine two words into a register pair",
{ fSETWORD(0,RddV,RtV);
fSETWORD(1,RddV,RsV);
})
Q6INSN(A4_combineri,"Rdd32=combine(Rs32,#s8)",ATTRIBS(),
"Combine a word and an immediate into a register pair",
{ fIMMEXT(siV); fSETWORD(0,RddV,siV);
fSETWORD(1,RddV,RsV);
})
Q6INSN(A4_combineir,"Rdd32=combine(#s8,Rs32)",ATTRIBS(),
"Combine a word and an immediate into a register pair",
{ fIMMEXT(siV); fSETWORD(0,RddV,RsV);
fSETWORD(1,RddV,siV);
})
Q6INSN(A2_combineii,"Rdd32=combine(#s8,#S8)",ATTRIBS(A_ARCHV2),
"Set two small immediates",
{ fIMMEXT(siV); fSETWORD(0,RddV,SiV); fSETWORD(1,RddV,siV); })
Q6INSN(A4_combineii,"Rdd32=combine(#s8,#U6)",ATTRIBS(),"Set two small immediates",
{ fIMMEXT(UiV); fSETWORD(0,RddV,UiV); fSETWORD(1,RddV,siV); })
Q6INSN(A2_combine_hh,"Rd32=combine(Rt.H32,Rs.H32)",ATTRIBS(),
"Combine two halves into a register", {RdV = (fGETUHALF(1,RtV)<<16) | fGETUHALF(1,RsV);})
Q6INSN(A2_combine_hl,"Rd32=combine(Rt.H32,Rs.L32)",ATTRIBS(),
"Combine two halves into a register", {RdV = (fGETUHALF(1,RtV)<<16) | fGETUHALF(0,RsV);})
Q6INSN(A2_combine_lh,"Rd32=combine(Rt.L32,Rs.H32)",ATTRIBS(),
"Combine two halves into a register", {RdV = (fGETUHALF(0,RtV)<<16) | fGETUHALF(1,RsV);})
Q6INSN(A2_combine_ll,"Rd32=combine(Rt.L32,Rs.L32)",ATTRIBS(),
"Combine two halves into a register", {RdV = (fGETUHALF(0,RtV)<<16) | fGETUHALF(0,RsV);})
Q6INSN(A2_tfril,"Rx.L32=#u16",ATTRIBS(),
"Set low 16-bits, leave upper 16 unchanged",{ fSETHALF(0,RxV,uiV);})
Q6INSN(A2_tfrih,"Rx.H32=#u16",ATTRIBS(),
"Set high 16-bits, leave low 16 unchanged",{ fSETHALF(1,RxV,uiV);})
Q6INSN(A2_tfrcrr,"Rd32=Cs32",ATTRIBS(),
"transfer control register to general register",{ RdV=CsV;})
Q6INSN(A2_tfrrcr,"Cd32=Rs32",ATTRIBS(),
"transfer general register to control register",{ CdV=RsV;})
Q6INSN(A4_tfrcpp,"Rdd32=Css32",ATTRIBS(),
"transfer control register to general register",{ RddV=CssV;})
Q6INSN(A4_tfrpcp,"Cdd32=Rss32",ATTRIBS(),
"transfer general register to control register",{ CddV=RssV;})
/**********************************************/
/* Logicals */
/**********************************************/
Q6INSN(A2_and,"Rd32=and(Rs32,Rt32)",ATTRIBS(),
"logical AND",{ RdV=RsV&RtV;})
Q6INSN(A2_or,"Rd32=or(Rs32,Rt32)",ATTRIBS(),
"logical OR",{ RdV=RsV|RtV;})
Q6INSN(A2_xor,"Rd32=xor(Rs32,Rt32)",ATTRIBS(),
"logical XOR",{ RdV=RsV^RtV;})
Q6INSN(M2_xor_xacc,"Rx32^=xor(Rs32,Rt32)",ATTRIBS(A_ARCHV2),
"logical XOR with XOR accumulation",{ RxV^=RsV^RtV;})
Q6INSN(M4_xor_xacc,"Rxx32^=xor(Rss32,Rtt32)",,
"logical XOR with XOR accumulation",{ RxxV^=RssV^RttV;})
Q6INSN(A4_andn,"Rd32=and(Rt32,~Rs32)",,
"And-Not", { RdV = (RtV & ~RsV); })
Q6INSN(A4_orn,"Rd32=or(Rt32,~Rs32)",,
"Or-Not", { RdV = (RtV | ~RsV); })
Q6INSN(A4_andnp,"Rdd32=and(Rtt32,~Rss32)",,
"And-Not", { RddV = (RttV & ~RssV); })
Q6INSN(A4_ornp,"Rdd32=or(Rtt32,~Rss32)",,
"Or-Not", { RddV = (RttV | ~RssV); })
/********************/
/* Compound add-add */
/********************/
Q6INSN(S4_addaddi,"Rd32=add(Rs32,add(Ru32,#s6))",ATTRIBS(),
"3-input add",
{ RdV = RsV + RuV + fIMMEXT(siV); })
Q6INSN(S4_subaddi,"Rd32=add(Rs32,sub(#s6,Ru32))",ATTRIBS(),
"3-input sub",
{ RdV = RsV - RuV + fIMMEXT(siV); })
/****************************/
/* Compound logical-logical */
/****************************/
Q6INSN(M4_and_and,"Rx32&=and(Rs32,Rt32)",ATTRIBS(),
"Compound And-And", { RxV &= (RsV & RtV); })
Q6INSN(M4_and_andn,"Rx32&=and(Rs32,~Rt32)",ATTRIBS(),
"Compound And-Andn", { RxV &= (RsV & ~RtV); })
Q6INSN(M4_and_or,"Rx32&=or(Rs32,Rt32)",ATTRIBS(),
"Compound And-Or", { RxV &= (RsV | RtV); })
Q6INSN(M4_and_xor,"Rx32&=xor(Rs32,Rt32)",ATTRIBS(),
"Compound And-xor", { RxV &= (RsV ^ RtV); })
Q6INSN(M4_or_and,"Rx32|=and(Rs32,Rt32)",ATTRIBS(),
"Compound Or-And", { RxV |= (RsV & RtV); })
Q6INSN(M4_or_andn,"Rx32|=and(Rs32,~Rt32)",ATTRIBS(),
"Compound Or-AndN", { RxV |= (RsV & ~RtV); })
Q6INSN(M4_or_or,"Rx32|=or(Rs32,Rt32)",ATTRIBS(),
"Compound Or-Or", { RxV |= (RsV | RtV); })
Q6INSN(M4_or_xor,"Rx32|=xor(Rs32,Rt32)",ATTRIBS(),
"Compound Or-xor", { RxV |= (RsV ^ RtV); })
Q6INSN(S4_or_andix,"Rx32=or(Ru32,and(Rx32,#s10))",ATTRIBS(),
"Compound Or-And", { RxV = RuV | (RxV & fIMMEXT(siV)); })
Q6INSN(S4_or_andi,"Rx32|=and(Rs32,#s10)",ATTRIBS(),
"Compound Or-And", { RxV = RxV | (RsV & fIMMEXT(siV)); })
Q6INSN(S4_or_ori,"Rx32|=or(Rs32,#s10)",ATTRIBS(),
"Compound Or-And", { RxV = RxV | (RsV | fIMMEXT(siV)); })
Q6INSN(M4_xor_and,"Rx32^=and(Rs32,Rt32)",ATTRIBS(),
"Compound Xor-And", { RxV ^= (RsV & RtV); })
Q6INSN(M4_xor_or,"Rx32^=or(Rs32,Rt32)",ATTRIBS(),
"Compound Xor-Or", { RxV ^= (RsV | RtV); })
Q6INSN(M4_xor_andn,"Rx32^=and(Rs32,~Rt32)",ATTRIBS(),
"Compound Xor-And", { RxV ^= (RsV & ~RtV); })
Q6INSN(A2_subri,"Rd32=sub(#s10,Rs32)",ATTRIBS(A_ARCHV2),
"Subtract register from immediate",{ fIMMEXT(siV); RdV=siV-RsV;})
Q6INSN(A2_andir,"Rd32=and(Rs32,#s10)",ATTRIBS(A_ARCHV2),
"logical AND with immediate",{ fIMMEXT(siV); RdV=RsV&siV;})
Q6INSN(A2_orir,"Rd32=or(Rs32,#s10)",ATTRIBS(A_ARCHV2),
"logical OR with immediate",{ fIMMEXT(siV); RdV=RsV|siV;})
Q6INSN(A2_andp,"Rdd32=and(Rss32,Rtt32)",ATTRIBS(),
"logical AND pair",{ RddV=RssV&RttV;})
Q6INSN(A2_orp,"Rdd32=or(Rss32,Rtt32)",ATTRIBS(),
"logical OR pair",{ RddV=RssV|RttV;})
Q6INSN(A2_xorp,"Rdd32=xor(Rss32,Rtt32)",ATTRIBS(),
"logical eXclusive OR pair",{ RddV=RssV^RttV;})
Q6INSN(A2_notp,"Rdd32=not(Rss32)",ATTRIBS(),
"logical NOT pair",{ RddV=~RssV;})
Q6INSN(A2_sxtw,"Rdd32=sxtw(Rs32)",ATTRIBS(),
"Sign extend 32-bit word to 64-bit pair",
{ RddV = fCAST4_8s(RsV); })
Q6INSN(A2_sat,"Rd32=sat(Rss32)",ATTRIBS(),
"Saturate to 32-bit Signed",
{ RdV = fSAT(RssV); })
Q6INSN(A2_roundsat,"Rd32=round(Rss32):sat",ATTRIBS(),
"Round & Saturate to 32-bit Signed",
{ fHIDE(size8s_t tmp;) fADDSAT64(tmp,RssV,0x080000000ULL); RdV = fGETWORD(1,tmp); })
Q6INSN(A2_sath,"Rd32=sath(Rs32)",ATTRIBS(),
"Saturate to 16-bit Signed",
{ RdV = fSATH(RsV); })
Q6INSN(A2_satuh,"Rd32=satuh(Rs32)",ATTRIBS(),
"Saturate to 16-bit Unsigned",
{ RdV = fSATUH(RsV); })
Q6INSN(A2_satub,"Rd32=satub(Rs32)",ATTRIBS(),
"Saturate to 8-bit Unsigned",
{ RdV = fSATUB(RsV); })
Q6INSN(A2_satb,"Rd32=satb(Rs32)",ATTRIBS(A_ARCHV2),
"Saturate to 8-bit Signed",
{ RdV = fSATB(RsV); })
/**********************************************/
/* Vector Add */
/**********************************************/
Q6INSN(A2_vaddub,"Rdd32=vaddub(Rss32,Rtt32)",ATTRIBS(),
"Add vector of bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,(fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV)));
}
})
Q6INSN(A2_vaddubs,"Rdd32=vaddub(Rss32,Rtt32):sat",ATTRIBS(),
"Add vector of bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,fSATUN(8,fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV)));
}
})
Q6INSN(A2_vaddh,"Rdd32=vaddh(Rss32,Rtt32)",ATTRIBS(),
"Add vector of half integers",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fGETHALF(i,RssV)+fGETHALF(i,RttV));
}
})
Q6INSN(A2_vaddhs,"Rdd32=vaddh(Rss32,Rtt32):sat",ATTRIBS(),
"Add vector of half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATN(16,fGETHALF(i,RssV)+fGETHALF(i,RttV)));
}
})
Q6INSN(A2_vadduhs,"Rdd32=vadduh(Rss32,Rtt32):sat",ATTRIBS(),
"Add vector of unsigned half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATUN(16,fGETUHALF(i,RssV)+fGETUHALF(i,RttV)));
}
})
Q6INSN(A5_vaddhubs,"Rd32=vaddhub(Rss32,Rtt32):sat",ATTRIBS(),
"Add vector of half integers with saturation and pack to unsigned bytes",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETBYTE(i,RdV,fSATUB(fGETHALF(i,RssV)+fGETHALF(i,RttV)));
}
})
Q6INSN(A2_vaddw,"Rdd32=vaddw(Rss32,Rtt32)",ATTRIBS(),
"Add vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fGETWORD(i,RssV)+fGETWORD(i,RttV));
}
})
Q6INSN(A2_vaddws,"Rdd32=vaddw(Rss32,Rtt32):sat",ATTRIBS(),
"Add vector of words with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fSATN(32,fGETWORD(i,RssV)+fGETWORD(i,RttV)));
}
})
Q6INSN(S4_vxaddsubw,"Rdd32=vxaddsubw(Rss32,Rtt32):sat",ATTRIBS(),
"Cross vector add-sub words with saturation",
{
fSETWORD(0,RddV,fSAT(fGETWORD(0,RssV)+fGETWORD(1,RttV)));
fSETWORD(1,RddV,fSAT(fGETWORD(1,RssV)-fGETWORD(0,RttV)));
})
Q6INSN(S4_vxsubaddw,"Rdd32=vxsubaddw(Rss32,Rtt32):sat",ATTRIBS(),
"Cross vector sub-add words with saturation",
{
fSETWORD(0,RddV,fSAT(fGETWORD(0,RssV)-fGETWORD(1,RttV)));
fSETWORD(1,RddV,fSAT(fGETWORD(1,RssV)+fGETWORD(0,RttV)));
})
Q6INSN(S4_vxaddsubh,"Rdd32=vxaddsubh(Rss32,Rtt32):sat",ATTRIBS(),
"Cross vector add-sub halfwords with saturation",
{
fSETHALF(0,RddV,fSATH(fGETHALF(0,RssV)+fGETHALF(1,RttV)));
fSETHALF(1,RddV,fSATH(fGETHALF(1,RssV)-fGETHALF(0,RttV)));
fSETHALF(2,RddV,fSATH(fGETHALF(2,RssV)+fGETHALF(3,RttV)));
fSETHALF(3,RddV,fSATH(fGETHALF(3,RssV)-fGETHALF(2,RttV)));
})
Q6INSN(S4_vxsubaddh,"Rdd32=vxsubaddh(Rss32,Rtt32):sat",ATTRIBS(),
"Cross vector sub-add halfwords with saturation",
{
fSETHALF(0,RddV,fSATH(fGETHALF(0,RssV)-fGETHALF(1,RttV)));
fSETHALF(1,RddV,fSATH(fGETHALF(1,RssV)+fGETHALF(0,RttV)));
fSETHALF(2,RddV,fSATH(fGETHALF(2,RssV)-fGETHALF(3,RttV)));
fSETHALF(3,RddV,fSATH(fGETHALF(3,RssV)+fGETHALF(2,RttV)));
})
Q6INSN(S4_vxaddsubhr,"Rdd32=vxaddsubh(Rss32,Rtt32):rnd:>>1:sat",ATTRIBS(),
"Cross vector add-sub halfwords with shift, round, and saturation",
{
fSETHALF(0,RddV,fSATH((fGETHALF(0,RssV)+fGETHALF(1,RttV)+1)>>1));
fSETHALF(1,RddV,fSATH((fGETHALF(1,RssV)-fGETHALF(0,RttV)+1)>>1));
fSETHALF(2,RddV,fSATH((fGETHALF(2,RssV)+fGETHALF(3,RttV)+1)>>1));
fSETHALF(3,RddV,fSATH((fGETHALF(3,RssV)-fGETHALF(2,RttV)+1)>>1));
})
Q6INSN(S4_vxsubaddhr,"Rdd32=vxsubaddh(Rss32,Rtt32):rnd:>>1:sat",ATTRIBS(),
"Cross vector sub-add halfwords with shift, round, and saturation",
{
fSETHALF(0,RddV,fSATH((fGETHALF(0,RssV)-fGETHALF(1,RttV)+1)>>1));
fSETHALF(1,RddV,fSATH((fGETHALF(1,RssV)+fGETHALF(0,RttV)+1)>>1));
fSETHALF(2,RddV,fSATH((fGETHALF(2,RssV)-fGETHALF(3,RttV)+1)>>1));
fSETHALF(3,RddV,fSATH((fGETHALF(3,RssV)+fGETHALF(2,RttV)+1)>>1));
})
/**********************************************/
/* 1/2 Vector operations */
/**********************************************/
Q6INSN(A2_svavgh,"Rd32=vavgh(Rs32,Rt32)",ATTRIBS(A_ARCHV2),
"Avg vector of half integers",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,((fGETHALF(i,RsV)+fGETHALF(i,RtV))>>1));
}
})
Q6INSN(A2_svavghs,"Rd32=vavgh(Rs32,Rt32):rnd",ATTRIBS(A_ARCHV2),
"Avg vector of half integers with rounding",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,((fGETHALF(i,RsV)+fGETHALF(i,RtV)+1)>>1));
}
})
Q6INSN(A2_svnavgh,"Rd32=vnavgh(Rt32,Rs32)",ATTRIBS(A_ARCHV2),
"Avg vector of half integers",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,((fGETHALF(i,RtV)-fGETHALF(i,RsV))>>1));
}
})
Q6INSN(A2_svaddh,"Rd32=vaddh(Rs32,Rt32)",ATTRIBS(),
"Add vector of half integers",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fGETHALF(i,RsV)+fGETHALF(i,RtV));
}
})
Q6INSN(A2_svaddhs,"Rd32=vaddh(Rs32,Rt32):sat",ATTRIBS(),
"Add vector of half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fSATN(16,fGETHALF(i,RsV)+fGETHALF(i,RtV)));
}
})
Q6INSN(A2_svadduhs,"Rd32=vadduh(Rs32,Rt32):sat",ATTRIBS(),
"Add vector of unsigned half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fSATUN(16,fGETUHALF(i,RsV)+fGETUHALF(i,RtV)));
}
})
Q6INSN(A2_svsubh,"Rd32=vsubh(Rt32,Rs32)",ATTRIBS(),
"Sub vector of half integers",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fGETHALF(i,RtV)-fGETHALF(i,RsV));
}
})
Q6INSN(A2_svsubhs,"Rd32=vsubh(Rt32,Rs32):sat",ATTRIBS(),
"Sub vector of half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fSATN(16,fGETHALF(i,RtV)-fGETHALF(i,RsV)));
}
})
Q6INSN(A2_svsubuhs,"Rd32=vsubuh(Rt32,Rs32):sat",ATTRIBS(),
"Sub vector of unsigned half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETHALF(i,RdV,fSATUN(16,fGETUHALF(i,RtV)-fGETUHALF(i,RsV)));
}
})
/**********************************************/
/* Vector Reduce Add */
/**********************************************/
Q6INSN(A2_vraddub,"Rdd32=vraddub(Rss32,Rtt32)",ATTRIBS(),
"Sum: two vectors of unsigned bytes",
{
fHIDE(int i;)
RddV = 0;
for (i=0;i<4;i++) {
fSETWORD(0,RddV,(fGETWORD(0,RddV) + (fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV))));
}
for (i=4;i<8;i++) {
fSETWORD(1,RddV,(fGETWORD(1,RddV) + (fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV))));
}
})
Q6INSN(A2_vraddub_acc,"Rxx32+=vraddub(Rss32,Rtt32)",ATTRIBS(),
"Sum: two vectors of unsigned bytes",
{
fHIDE(int i;)
for (i = 0; i < 4; i++) {
fSETWORD(0,RxxV,(fGETWORD(0,RxxV) + (fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV))));
}
for (i = 4; i < 8; i++) {
fSETWORD(1,RxxV,(fGETWORD(1,RxxV) + (fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV))));
}
})
Q6INSN(M2_vraddh,"Rd32=vraddh(Rss32,Rtt32)",ATTRIBS(A_ARCHV3),
"Sum: two vectors of halves",
{
fHIDE(int i;)
RdV = 0;
for (i=0;i<4;i++) {
RdV += (fGETHALF(i,RssV)+fGETHALF(i,RttV));
}
})
Q6INSN(M2_vradduh,"Rd32=vradduh(Rss32,Rtt32)",ATTRIBS(A_ARCHV3),
"Sum: two vectors of unsigned halves",
{
fHIDE(int i;)
RdV = 0;
for (i=0;i<4;i++) {
RdV += (fGETUHALF(i,RssV)+fGETUHALF(i,RttV));
}
})
/**********************************************/
/* Vector Sub */
/**********************************************/
Q6INSN(A2_vsubub,"Rdd32=vsubub(Rtt32,Rss32)",ATTRIBS(),
"Sub vector of bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,(fGETUBYTE(i,RttV)-fGETUBYTE(i,RssV)));
}
})
Q6INSN(A2_vsububs,"Rdd32=vsubub(Rtt32,Rss32):sat",ATTRIBS(),
"Sub vector of bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,fSATUN(8,fGETUBYTE(i,RttV)-fGETUBYTE(i,RssV)));
}
})
Q6INSN(A2_vsubh,"Rdd32=vsubh(Rtt32,Rss32)",ATTRIBS(),
"Sub vector of half integers",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fGETHALF(i,RttV)-fGETHALF(i,RssV));
}
})
Q6INSN(A2_vsubhs,"Rdd32=vsubh(Rtt32,Rss32):sat",ATTRIBS(),
"Sub vector of half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATN(16,fGETHALF(i,RttV)-fGETHALF(i,RssV)));
}
})
Q6INSN(A2_vsubuhs,"Rdd32=vsubuh(Rtt32,Rss32):sat",ATTRIBS(),
"Sub vector of unsigned half integers with saturation",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATUN(16,fGETUHALF(i,RttV)-fGETUHALF(i,RssV)));
}
})
Q6INSN(A2_vsubw,"Rdd32=vsubw(Rtt32,Rss32)",ATTRIBS(),
"Sub vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fGETWORD(i,RttV)-fGETWORD(i,RssV));
}
})
Q6INSN(A2_vsubws,"Rdd32=vsubw(Rtt32,Rss32):sat",ATTRIBS(),
"Sub vector of words with saturation",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fSATN(32,fGETWORD(i,RttV)-fGETWORD(i,RssV)));
}
})
/**********************************************/
/* Vector Abs */
/**********************************************/
Q6INSN(A2_vabsh,"Rdd32=vabsh(Rss32)",ATTRIBS(),
"Negate vector of half integers",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fABS(fGETHALF(i,RssV)));
}
})
Q6INSN(A2_vabshsat,"Rdd32=vabsh(Rss32):sat",ATTRIBS(),
"Negate vector of half integers",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATH(fABS(fGETHALF(i,RssV))));
}
})
Q6INSN(A2_vabsw,"Rdd32=vabsw(Rss32)",ATTRIBS(),
"Absolute Value vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fABS(fGETWORD(i,RssV)));
}
})
Q6INSN(A2_vabswsat,"Rdd32=vabsw(Rss32):sat",ATTRIBS(),
"Absolute Value vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fSAT(fABS(fGETWORD(i,RssV))));
}
})
/**********************************************/
/* Vector SAD */
/**********************************************/
Q6INSN(M2_vabsdiffw,"Rdd32=vabsdiffw(Rtt32,Rss32)",ATTRIBS(A_ARCHV2),
"Absolute Differences: vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fABS(fGETWORD(i,RttV) - fGETWORD(i,RssV)));
}
})
Q6INSN(M2_vabsdiffh,"Rdd32=vabsdiffh(Rtt32,Rss32)",ATTRIBS(A_ARCHV2),
"Absolute Differences: vector of halfwords",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fABS(fGETHALF(i,RttV) - fGETHALF(i,RssV)));
}
})
Q6INSN(M6_vabsdiffb,"Rdd32=vabsdiffb(Rtt32,Rss32)",ATTRIBS(),
"Absolute Differences: vector of halfwords",
{
fHIDE(int i;)
for (i=0;i<8;i++) {
fSETBYTE(i,RddV,fABS(fGETBYTE(i,RttV) - fGETBYTE(i,RssV)));
}
})
Q6INSN(M6_vabsdiffub,"Rdd32=vabsdiffub(Rtt32,Rss32)",ATTRIBS(),
"Absolute Differences: vector of halfwords",
{
fHIDE(int i;)
for (i=0;i<8;i++) {
fSETBYTE(i,RddV,fABS(fGETUBYTE(i,RttV) - fGETUBYTE(i,RssV)));
}
})
Q6INSN(A2_vrsadub,"Rdd32=vrsadub(Rss32,Rtt32)",ATTRIBS(),
"Sum of Absolute Differences: vector of unsigned bytes",
{
fHIDE(int i;)
RddV = 0;
for (i = 0; i < 4; i++) {
fSETWORD(0,RddV,(fGETWORD(0,RddV) + fABS((fGETUBYTE(i,RssV) - fGETUBYTE(i,RttV)))));
}
for (i = 4; i < 8; i++) {
fSETWORD(1,RddV,(fGETWORD(1,RddV) + fABS((fGETUBYTE(i,RssV) - fGETUBYTE(i,RttV)))));
}
})
Q6INSN(A2_vrsadub_acc,"Rxx32+=vrsadub(Rss32,Rtt32)",ATTRIBS(),
"Sum of Absolute Differences: vector of unsigned bytes",
{
fHIDE(int i;)
for (i = 0; i < 4; i++) {
fSETWORD(0,RxxV,(fGETWORD(0,RxxV) + fABS((fGETUBYTE(i,RssV) - fGETUBYTE(i,RttV)))));
}
for (i = 4; i < 8; i++) {
fSETWORD(1,RxxV,(fGETWORD(1,RxxV) + fABS((fGETUBYTE(i,RssV) - fGETUBYTE(i,RttV)))));
}
})
/**********************************************/
/* Vector Average */
/**********************************************/
Q6INSN(A2_vavgub,"Rdd32=vavgub(Rss32,Rtt32)",ATTRIBS(),
"Average vector of unsigned bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,((fGETUBYTE(i,RssV) + fGETUBYTE(i,RttV))>>1));
}
})
Q6INSN(A2_vavguh,"Rdd32=vavguh(Rss32,Rtt32)",ATTRIBS(),
"Average vector of unsigned halfwords",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,(fGETUHALF(i,RssV)+fGETUHALF(i,RttV))>>1);
}
})
Q6INSN(A2_vavgh,"Rdd32=vavgh(Rss32,Rtt32)",ATTRIBS(),
"Average vector of halfwords",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,(fGETHALF(i,RssV)+fGETHALF(i,RttV))>>1);
}
})
Q6INSN(A2_vnavgh,"Rdd32=vnavgh(Rtt32,Rss32)",ATTRIBS(),
"Negative Average vector of halfwords",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,(fGETHALF(i,RttV)-fGETHALF(i,RssV))>>1);
}
})
Q6INSN(A2_vavgw,"Rdd32=vavgw(Rss32,Rtt32)",ATTRIBS(),
"Average vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fSXTN(32,33,fGETWORD(i,RssV))+fSXTN(32,33,fGETWORD(i,RttV)))>>1);
}
})
Q6INSN(A2_vnavgw,"Rdd32=vnavgw(Rtt32,Rss32)",ATTRIBS(A_ARCHV2),
"Average vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fSXTN(32,33,fGETWORD(i,RttV))-fSXTN(32,33,fGETWORD(i,RssV)))>>1);
}
})
Q6INSN(A2_vavgwr,"Rdd32=vavgw(Rss32,Rtt32):rnd",ATTRIBS(),
"Average vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fSXTN(32,33,fGETWORD(i,RssV))+fSXTN(32,33,fGETWORD(i,RttV))+1)>>1);
}
})
Q6INSN(A2_vnavgwr,"Rdd32=vnavgw(Rtt32,Rss32):rnd:sat",ATTRIBS(A_ARCHV2),
"Average vector of words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fSAT((fSXTN(32,33,fGETWORD(i,RttV))-fSXTN(32,33,fGETWORD(i,RssV))+1)>>1));
}
})
Q6INSN(A2_vavgwcr,"Rdd32=vavgw(Rss32,Rtt32):crnd",ATTRIBS(A_ARCHV2),
"Average vector of words with convergent rounding",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fCRND(fSXTN(32,33,fGETWORD(i,RssV))+fSXTN(32,33,fGETWORD(i,RttV)))>>1));
}
})
Q6INSN(A2_vnavgwcr,"Rdd32=vnavgw(Rtt32,Rss32):crnd:sat",ATTRIBS(A_ARCHV2),
"Average negative vector of words with convergent rounding",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,fSAT(fCRND(fSXTN(32,33,fGETWORD(i,RttV))-fSXTN(32,33,fGETWORD(i,RssV)))>>1));
}
})
Q6INSN(A2_vavghcr,"Rdd32=vavgh(Rss32,Rtt32):crnd",ATTRIBS(A_ARCHV2),
"Average vector of halfwords with conv rounding",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fCRND(fGETHALF(i,RssV)+fGETHALF(i,RttV))>>1);
}
})
Q6INSN(A2_vnavghcr,"Rdd32=vnavgh(Rtt32,Rss32):crnd:sat",ATTRIBS(A_ARCHV2),
"Average negative vector of halfwords with conv rounding",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATH(fCRND(fGETHALF(i,RttV)-fGETHALF(i,RssV))>>1));
}
})
Q6INSN(A2_vavguw,"Rdd32=vavguw(Rss32,Rtt32)",ATTRIBS(),
"Average vector of unsigned words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fZXTN(32,33,fGETUWORD(i,RssV))+fZXTN(32,33,fGETUWORD(i,RttV)))>>1);
}
})
Q6INSN(A2_vavguwr,"Rdd32=vavguw(Rss32,Rtt32):rnd",ATTRIBS(),
"Average vector of unsigned words",
{
fHIDE(int i;)
for (i=0;i<2;i++) {
fSETWORD(i,RddV,(fZXTN(32,33,fGETUWORD(i,RssV))+fZXTN(32,33,fGETUWORD(i,RttV))+1)>>1);
}
})
Q6INSN(A2_vavgubr,"Rdd32=vavgub(Rss32,Rtt32):rnd",ATTRIBS(),
"Average vector of unsigned bytes",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBYTE(i,RddV,((fGETUBYTE(i,RssV)+fGETUBYTE(i,RttV)+1)>>1));
}
})
Q6INSN(A2_vavguhr,"Rdd32=vavguh(Rss32,Rtt32):rnd",ATTRIBS(),
"Average vector of unsigned halfwords with rounding",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,(fGETUHALF(i,RssV)+fGETUHALF(i,RttV)+1)>>1);
}
})
Q6INSN(A2_vavghr,"Rdd32=vavgh(Rss32,Rtt32):rnd",ATTRIBS(),
"Average vector of halfwords with rounding",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,(fGETHALF(i,RssV)+fGETHALF(i,RttV)+1)>>1);
}
})
Q6INSN(A2_vnavghr,"Rdd32=vnavgh(Rtt32,Rss32):rnd:sat",ATTRIBS(A_ARCHV2),
"Negative Average vector of halfwords with rounding",
{
fHIDE(int i;)
for (i=0;i<4;i++) {
fSETHALF(i,RddV,fSATH((fGETHALF(i,RttV)-fGETHALF(i,RssV)+1)>>1));
}
})
/* Rounding Instruction */
Q6INSN(A4_round_ri,"Rd32=round(Rs32,#u5)",ATTRIBS(),"Round", {RdV = fRNDN(RsV,uiV)>>uiV; })
Q6INSN(A4_round_rr,"Rd32=round(Rs32,Rt32)",ATTRIBS(),"Round", {RdV = fRNDN(RsV,fZXTN(5,32,RtV))>>fZXTN(5,32,RtV); })
Q6INSN(A4_round_ri_sat,"Rd32=round(Rs32,#u5):sat",ATTRIBS(),"Round", {RdV = (fSAT(fRNDN(RsV,uiV)))>>uiV; })
Q6INSN(A4_round_rr_sat,"Rd32=round(Rs32,Rt32):sat",ATTRIBS(),"Round", {RdV = (fSAT(fRNDN(RsV,fZXTN(5,32,RtV))))>>fZXTN(5,32,RtV); })
Q6INSN(A4_cround_ri,"Rd32=cround(Rs32,#u5)",ATTRIBS(),"Convergent Round", {RdV = fCRNDN(RsV,uiV); })
Q6INSN(A4_cround_rr,"Rd32=cround(Rs32,Rt32)",ATTRIBS(),"Convergent Round", {RdV = fCRNDN(RsV,fZXTN(5,32,RtV)); })
#define CROUND(DST,SRC,SHIFT) \
fHIDE(size16s_t rndbit_128;)\
fHIDE(size16s_t tmp128;)\
fHIDE(size16s_t src_128;)\
if (SHIFT == 0) { \
DST = SRC;\
} else if ((SRC & (size8s_t)((1LL << (SHIFT - 1)) - 1LL)) == 0) { \
src_128 = fCAST8S_16S(SRC);\
rndbit_128 = fCAST8S_16S(1LL);\
rndbit_128 = fSHIFTL128(rndbit_128, SHIFT);\
rndbit_128 = fAND128(rndbit_128, src_128);\
rndbit_128 = fSHIFTR128(rndbit_128, 1);\
tmp128 = fADD128(src_128, rndbit_128);\
tmp128 = fSHIFTR128(tmp128, SHIFT);\
DST = fCAST16S_8S(tmp128);\
} else {\
size16s_t rndbit_128 = fCAST8S_16S((1LL << (SHIFT - 1))); \
size16s_t src_128 = fCAST8S_16S(SRC); \
size16s_t tmp128 = fADD128(src_128, rndbit_128);\
tmp128 = fSHIFTR128(tmp128, SHIFT);\
DST = fCAST16S_8S(tmp128);\
}
Q6INSN(A7_croundd_ri,"Rdd32=cround(Rss32,#u6)",ATTRIBS(),"Convergent Round",
{
CROUND(RddV,RssV,uiV);
})
Q6INSN(A7_croundd_rr,"Rdd32=cround(Rss32,Rt32)",ATTRIBS(),"Convergent Round",
{
CROUND(RddV,RssV,fZXTN(6,32,RtV));
})
Q6INSN(A7_clip,"Rd32=clip(Rs32,#u5)",ATTRIBS(),"Clip to #s5", { fCLIP(RdV,RsV,uiV);})
Q6INSN(A7_vclip,"Rdd32=vclip(Rss32,#u5)",ATTRIBS(),"Clip to #s5",
{
fHIDE(size4s_t tmp;)
fCLIP(tmp, fGETWORD(0, RssV), uiV);
fSETWORD(0, RddV, tmp);
fCLIP(tmp,fGETWORD(1, RssV), uiV);
fSETWORD(1, RddV, tmp);
}
)
/**********************************************/
/* V4: Cross Vector Min/Max */
/**********************************************/
#define VRMINORMAX(TAG,STR,OP,SHORTTYPE,SETTYPE,GETTYPE,NEL,SHIFT) \
Q6INSN(A4_vr##TAG##SHORTTYPE,"Rxx32=vr"#TAG#SHORTTYPE"(Rss32,Ru32)",ATTRIBS(), \
"Choose " STR " elements of a vector", \
{ \
fHIDE(int i; size8s_t TAG; size4s_t addr;) \
TAG = fGET##GETTYPE(0,RxxV); \
addr = fGETWORD(1,RxxV); \
for (i = 0; i < NEL; i++) { \
if (TAG OP fGET##GETTYPE(i,RssV)) { \
TAG = fGET##GETTYPE(i,RssV); \
addr = RuV | i<<SHIFT; \
} \
} \
fSETWORD(0,RxxV,TAG); \
fSETWORD(1,RxxV,addr); \
})
#define RMINMAX(SHORTTYPE,SETTYPE,GETTYPE,NEL,SHIFT) \
VRMINORMAX(min,"minimum",>,SHORTTYPE,SETTYPE,GETTYPE,NEL,SHIFT) \
VRMINORMAX(max,"maximum",<,SHORTTYPE,SETTYPE,GETTYPE,NEL,SHIFT)
RMINMAX(h,HALF,HALF,4,1)
RMINMAX(uh,HALF,UHALF,4,1)
RMINMAX(w,WORD,WORD,2,2)
RMINMAX(uw,WORD,UWORD,2,2)
#undef RMINMAX
#undef VRMINORMAX
/**********************************************/
/* Vector Min/Max */
/**********************************************/
#define VMINORMAX(TAG,STR,FUNC,SHORTTYPE,SETTYPE,GETTYPE,NEL) \
Q6INSN(A2_v##TAG##SHORTTYPE,"Rdd32=v"#TAG#SHORTTYPE"(Rtt32,Rss32)",ATTRIBS(), \
"Choose " STR " elements of two vectors", \
{ \
fHIDE(int i;) \
for (i = 0; i < NEL; i++) { \
fSET##SETTYPE(i,RddV,FUNC(fGET##GETTYPE(i,RttV),fGET##GETTYPE(i,RssV))); \
} \
})
#define VMINORMAX3(TAG,STR,FUNC,SHORTTYPE,SETTYPE,GETTYPE,NEL) \
Q6INSN(A6_v##TAG##SHORTTYPE##3,"Rxx32=v"#TAG#SHORTTYPE"3(Rtt32,Rss32)",ATTRIBS(), \
"Choose " STR " elements of two vectors", \
{ \
fHIDE(int i;) \
for (i = 0; i < NEL; i++) { \
fSET##SETTYPE(i,RxxV,FUNC(fGET##GETTYPE(i,RxxV),FUNC(fGET##GETTYPE(i,RttV),fGET##GETTYPE(i,RssV)))); \
} \
})
#define MINMAX(SHORTTYPE,SETTYPE,GETTYPE,NEL) \
VMINORMAX(min,"minimum",fMIN,SHORTTYPE,SETTYPE,GETTYPE,NEL) \
VMINORMAX(max,"maximum",fMAX,SHORTTYPE,SETTYPE,GETTYPE,NEL)
MINMAX(b,BYTE,BYTE,8)
MINMAX(ub,BYTE,UBYTE,8)
MINMAX(h,HALF,HALF,4)
MINMAX(uh,HALF,UHALF,4)
MINMAX(w,WORD,WORD,2)
MINMAX(uw,WORD,UWORD,2)
#undef MINMAX
#undef VMINORMAX
#undef VMINORMAX3
Q6INSN(A5_ACS,"Rxx32,Pe4=vacsh(Rss32,Rtt32)",ATTRIBS(),
"Add Compare and Select elements of two vectors, record the maximums and the decisions ",
{
fHIDE(int i;)
fHIDE(int xv;)
fHIDE(int sv;)
fHIDE(int tv;)
for (i = 0; i < 4; i++) {
xv = (int) fGETHALF(i,RxxV);
sv = (int) fGETHALF(i,RssV);
tv = (int) fGETHALF(i,RttV);
xv = xv + tv; //assumes 17bit datapath
sv = sv - tv; //assumes 17bit datapath
fSETBIT(i*2, PeV, (xv > sv));
fSETBIT(i*2+1,PeV, (xv > sv));
fSETHALF(i, RxxV, fSATH(fMAX(xv,sv)));
}
})
Q6INSN(A6_vminub_RdP,"Rdd32,Pe4=vminub(Rtt32,Rss32)",ATTRIBS(),
"Vector minimum of bytes, records minimum and decision vector",
{
fHIDE(int i;)
for (i = 0; i < 8; i++) {
fSETBIT(i, PeV, (fGETUBYTE(i,RttV) > fGETUBYTE(i,RssV)));
fSETBYTE(i,RddV,fMIN(fGETUBYTE(i,RttV),fGETUBYTE(i,RssV)));
}
})
/**********************************************/
/* Vector Min/Max */
/**********************************************/
Q6INSN(A4_modwrapu,"Rd32=modwrap(Rs32,Rt32)",ATTRIBS(),
"Wrap to an unsigned modulo buffer",
{
if (RsV < 0) {
RdV = RsV + fCAST4u(RtV);
} else if (fCAST4u(RsV) >= fCAST4u(RtV)) {
RdV = RsV - fCAST4u(RtV);
} else {
RdV = RsV;
}
})