//
// The LLVM Compiler Infrastructure
//
-// This file was developed by the LLVM research group and is distributed under
-// the University of Illinois Open Source License. See LICENSE.TXT for details.
+// This file is distributed under the University of Illinois Open Source
+// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
def Alpha_cvttq : SDNode<"AlphaISD::CVTTQ_" , SDTFPUnaryOp, []>;
def Alpha_gprello : SDNode<"AlphaISD::GPRelLo", SDTIntBinOp, []>;
def Alpha_gprelhi : SDNode<"AlphaISD::GPRelHi", SDTIntBinOp, []>;
-def Alpha_rellit : SDNode<"AlphaISD::RelLit", SDTIntBinOp, []>;
+def Alpha_rellit : SDNode<"AlphaISD::RelLit", SDTIntBinOp, [SDNPMayLoad]>;
-def retflag : SDNode<"AlphaISD::RET_FLAG", SDTRet,
- [SDNPHasChain, SDNPOptInFlag]>;
+def retflag : SDNode<"AlphaISD::RET_FLAG", SDTNone,
+ [SDNPHasChain, SDNPOptInFlag]>;
// These are target-independent nodes, but have target-specific formats.
-def SDT_AlphaCallSeq : SDTypeProfile<0, 1, [ SDTCisVT<0, i64> ]>;
-def callseq_start : SDNode<"ISD::CALLSEQ_START", SDT_AlphaCallSeq,
- [SDNPHasChain, SDNPOutFlag]>;
-def callseq_end : SDNode<"ISD::CALLSEQ_END", SDT_AlphaCallSeq,
+def SDT_AlphaCallSeqStart : SDCallSeqStart<[ SDTCisVT<0, i64> ]>;
+def SDT_AlphaCallSeqEnd : SDCallSeqEnd<[ SDTCisVT<0, i64>,
+ SDTCisVT<1, i64> ]>;
+
+def callseq_start : SDNode<"ISD::CALLSEQ_START", SDT_AlphaCallSeqStart,
[SDNPHasChain, SDNPOutFlag]>;
+def callseq_end : SDNode<"ISD::CALLSEQ_END", SDT_AlphaCallSeqEnd,
+ [SDNPHasChain, SDNPOptInFlag, SDNPOutFlag]>;
//********************
//Paterns for matching
//********************
def invX : SDNodeXForm<imm, [{ //invert
- return getI64Imm(~N->getValue());
+ return getI64Imm(~N->getZExtValue());
}]>;
def negX : SDNodeXForm<imm, [{ //negate
- return getI64Imm(~N->getValue() + 1);
+ return getI64Imm(~N->getZExtValue() + 1);
}]>;
def SExt32 : SDNodeXForm<imm, [{ //signed extend int to long
- return getI64Imm(((int64_t)N->getValue() << 32) >> 32);
+ return getI64Imm(((int64_t)N->getZExtValue() << 32) >> 32);
}]>;
def SExt16 : SDNodeXForm<imm, [{ //signed extend int to long
- return getI64Imm(((int64_t)N->getValue() << 48) >> 48);
+ return getI64Imm(((int64_t)N->getZExtValue() << 48) >> 48);
}]>;
def LL16 : SDNodeXForm<imm, [{ //lda part of constant
- return getI64Imm(get_lda16(N->getValue()));
+ return getI64Imm(get_lda16(N->getZExtValue()));
}]>;
def LH16 : SDNodeXForm<imm, [{ //ldah part of constant (or more if too big)
- return getI64Imm(get_ldah16(N->getValue()));
+ return getI64Imm(get_ldah16(N->getZExtValue()));
}]>;
def iZAPX : SDNodeXForm<and, [{ // get imm to ZAPi
ConstantSDNode *RHS = cast<ConstantSDNode>(N->getOperand(1));
- return getI64Imm(get_zapImm(SDOperand(), RHS->getValue()));
+ return getI64Imm(get_zapImm(SDValue(), RHS->getZExtValue()));
}]>;
def nearP2X : SDNodeXForm<imm, [{
- return getI64Imm(Log2_64(getNearPower2((uint64_t)N->getValue())));
+ return getI64Imm(Log2_64(getNearPower2((uint64_t)N->getZExtValue())));
}]>;
def nearP2RemX : SDNodeXForm<imm, [{
- uint64_t x = abs(N->getValue() - getNearPower2((uint64_t)N->getValue()));
+ uint64_t x =
+ abs64(N->getZExtValue() - getNearPower2((uint64_t)N->getZExtValue()));
return getI64Imm(Log2_64(x));
}]>;
def immUExt8 : PatLeaf<(imm), [{ //imm fits in 8 bit zero extended field
- return (uint64_t)N->getValue() == (uint8_t)N->getValue();
+ return (uint64_t)N->getZExtValue() == (uint8_t)N->getZExtValue();
}]>;
def immUExt8inv : PatLeaf<(imm), [{ //inverted imm fits in 8 bit zero extended field
- return (uint64_t)~N->getValue() == (uint8_t)~N->getValue();
+ return (uint64_t)~N->getZExtValue() == (uint8_t)~N->getZExtValue();
}], invX>;
def immUExt8neg : PatLeaf<(imm), [{ //negated imm fits in 8 bit zero extended field
- return ((uint64_t)~N->getValue() + 1) == (uint8_t)((uint64_t)~N->getValue() + 1);
+ return ((uint64_t)~N->getZExtValue() + 1) ==
+ (uint8_t)((uint64_t)~N->getZExtValue() + 1);
}], negX>;
def immSExt16 : PatLeaf<(imm), [{ //imm fits in 16 bit sign extended field
- return ((int64_t)N->getValue() << 48) >> 48 == (int64_t)N->getValue();
+ return ((int64_t)N->getZExtValue() << 48) >> 48 ==
+ (int64_t)N->getZExtValue();
}]>;
def immSExt16int : PatLeaf<(imm), [{ //(int)imm fits in a 16 bit sign extended field
- return ((int64_t)N->getValue() << 48) >> 48 == ((int64_t)N->getValue() << 32) >> 32;
+ return ((int64_t)N->getZExtValue() << 48) >> 48 ==
+ ((int64_t)N->getZExtValue() << 32) >> 32;
}], SExt16>;
-def zappat : PatFrag<(ops node:$LHS), (and node:$LHS, imm:$L), [{
- if (ConstantSDNode *RHS = dyn_cast<ConstantSDNode>(N->getOperand(1))) {
- uint64_t build = get_zapImm(N->getOperand(0), (uint64_t)RHS->getValue());
- return build != 0;
- }
- return false;
+def zappat : PatFrag<(ops node:$LHS), (and node:$LHS, imm), [{
+ ConstantSDNode *RHS = dyn_cast<ConstantSDNode>(N->getOperand(1));
+ if (!RHS) return 0;
+ uint64_t build = get_zapImm(N->getOperand(0), (uint64_t)RHS->getZExtValue());
+ return build != 0;
}]>;
def immFPZ : PatLeaf<(fpimm), [{ //the only fpconstant nodes are +/- 0.0
return true;
}]>;
-def immRem1 : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),1, 0);}]>;
-def immRem2 : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),2, 0);}]>;
-def immRem3 : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),3, 0);}]>;
-def immRem4 : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),4, 0);}]>;
-def immRem5 : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),5, 0);}]>;
-def immRem1n : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),1, 1);}]>;
-def immRem2n : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),2, 1);}]>;
-def immRem3n : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),3, 1);}]>;
-def immRem4n : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),4, 1);}]>;
-def immRem5n : PatLeaf<(imm), [{return chkRemNearPower2(N->getValue(),5, 1);}]>;
+def immRem1 :PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),1,0);}]>;
+def immRem2 :PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),2,0);}]>;
+def immRem3 :PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),3,0);}]>;
+def immRem4 :PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),4,0);}]>;
+def immRem5 :PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),5,0);}]>;
+def immRem1n:PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),1,1);}]>;
+def immRem2n:PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),2,1);}]>;
+def immRem3n:PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),3,1);}]>;
+def immRem4n:PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),4,1);}]>;
+def immRem5n:PatLeaf<(imm),[{return chkRemNearPower2(N->getZExtValue(),5,1);}]>;
def immRemP2n : PatLeaf<(imm), [{
- return isPowerOf2_64(getNearPower2((uint64_t)N->getValue()) - N->getValue());
+ return isPowerOf2_64(getNearPower2((uint64_t)N->getZExtValue()) -
+ N->getZExtValue());
}]>;
def immRemP2 : PatLeaf<(imm), [{
- return isPowerOf2_64(N->getValue() - getNearPower2((uint64_t)N->getValue()));
+ return isPowerOf2_64(N->getZExtValue() -
+ getNearPower2((uint64_t)N->getZExtValue()));
}]>;
def immUExt8ME : PatLeaf<(imm), [{ //use this imm for mulqi
- int64_t d = abs((int64_t)N->getValue() - (int64_t)getNearPower2((uint64_t)N->getValue()));
+ int64_t d = abs64((int64_t)N->getZExtValue() -
+ (int64_t)getNearPower2((uint64_t)N->getZExtValue()));
if (isPowerOf2_64(d)) return false;
switch (d) {
case 1: case 3: case 5: return false;
- default: return (uint64_t)N->getValue() == (uint8_t)N->getValue();
+ default: return (uint64_t)N->getZExtValue() == (uint8_t)N->getZExtValue();
};
}]>;
//Pseudo ops for selection
-def IDEF_I : PseudoInstAlpha<(outs GPRC:$RA), (ins), ";#idef $RA",
- [(set GPRC:$RA, (undef))], s_pseudo>;
-def IDEF_F32 : PseudoInstAlpha<(outs F4RC:$RA), (ins), ";#idef $RA",
- [(set F4RC:$RA, (undef))], s_pseudo>;
-def IDEF_F64 : PseudoInstAlpha<(outs F8RC:$RA), (ins), ";#idef $RA",
- [(set F8RC:$RA, (undef))], s_pseudo>;
-
def WTF : PseudoInstAlpha<(outs), (ins variable_ops), "#wtf", [], s_pseudo>;
-let isLoad = 1, hasCtrlDep = 1 in {
-def ADJUSTSTACKUP : PseudoInstAlpha<(outs), (ins s64imm:$amt), "; ADJUP $amt",
- [(callseq_start imm:$amt)], s_pseudo>, Imp<[R30],[R30]>;
-def ADJUSTSTACKDOWN : PseudoInstAlpha<(outs), (ins s64imm:$amt), "; ADJDOWN $amt",
- [(callseq_end imm:$amt)], s_pseudo>, Imp<[R30],[R30]>;
+let hasCtrlDep = 1, Defs = [R30], Uses = [R30] in {
+def ADJUSTSTACKUP : PseudoInstAlpha<(outs), (ins s64imm:$amt),
+ "; ADJUP $amt",
+ [(callseq_start timm:$amt)], s_pseudo>;
+def ADJUSTSTACKDOWN : PseudoInstAlpha<(outs), (ins s64imm:$amt1, s64imm:$amt2),
+ "; ADJDOWN $amt1",
+ [(callseq_end timm:$amt1, timm:$amt2)], s_pseudo>;
}
+
def ALTENT : PseudoInstAlpha<(outs), (ins s64imm:$TARGET), "$$$TARGET..ng:\n", [], s_pseudo>;
def PCLABEL : PseudoInstAlpha<(outs), (ins s64imm:$num), "PCMARKER_$num:\n",[], s_pseudo>;
def MEMLABEL : PseudoInstAlpha<(outs), (ins s64imm:$i, s64imm:$j, s64imm:$k, s64imm:$m),
"LSMARKER$$$i$$$j$$$k$$$m:", [], s_pseudo>;
+let usesCustomInserter = 1 in { // Expanded after instruction selection.
+def CAS32 : PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$cmp, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_cmp_swap_32 GPRC:$ptr, GPRC:$cmp, GPRC:$swp))], s_pseudo>;
+def CAS64 : PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$cmp, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_cmp_swap_64 GPRC:$ptr, GPRC:$cmp, GPRC:$swp))], s_pseudo>;
+
+def LAS32 : PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_load_add_32 GPRC:$ptr, GPRC:$swp))], s_pseudo>;
+def LAS64 :PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_load_add_64 GPRC:$ptr, GPRC:$swp))], s_pseudo>;
+
+def SWAP32 : PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_swap_32 GPRC:$ptr, GPRC:$swp))], s_pseudo>;
+def SWAP64 :PseudoInstAlpha<(outs GPRC:$dst), (ins GPRC:$ptr, GPRC:$swp), "",
+ [(set GPRC:$dst, (atomic_swap_64 GPRC:$ptr, GPRC:$swp))], s_pseudo>;
+}
+
//***********************
//Real instructions
//***********************
def ZAPNOTi : OFormL<0x12, 0x31, "zapnot $RA,$L,$RC", [], s_ishf>;
// Define the pattern that produces ZAPNOTi.
-def : Pat<(i64 (zappat GPRC:$RA):$imm),
+def : Pat<(zappat:$imm GPRC:$RA),
(ZAPNOTi GPRC:$RA, (iZAPX GPRC:$imm))>;
def : Pat<(setune GPRC:$X, immUExt8:$Y), (CMPEQi (CMPEQ GPRC:$X, immUExt8:$Y), 0)>;
-let isReturn = 1, isTerminator = 1, noResults = 1, Ra = 31, Rb = 26, disp = 1, Uses = [R26] in {
+let isReturn = 1, isTerminator = 1, isBarrier = 1, Ra = 31, Rb = 26, disp = 1, Uses = [R26] in {
def RETDAG : MbrForm< 0x1A, 0x02, (ops), "ret $$31,($$26),1", s_jsr>; //Return from subroutine
def RETDAGp : MbrpForm< 0x1A, 0x02, (ops), "ret $$31,($$26),1", [(retflag)], s_jsr>; //Return from subroutine
}
-let isBranch = 1, isTerminator = 1, noResults = 1, isBarrier = 1,
-Ra = 31, disp = 0 in
+let isBranch = 1, isTerminator = 1, isBarrier = 1, isIndirectBranch = 1, Ra = 31, disp = 0 in
def JMP : MbrpForm< 0x1A, 0x00, (ops GPRC:$RS), "jmp $$31,($RS),0",
[(brind GPRC:$RS)], s_jsr>; //Jump
-let isCall = 1, noResults = 1, Ra = 26,
+let isCall = 1, Ra = 26,
Defs = [R0, R1, R2, R3, R4, R5, R6, R7, R8, R16, R17, R18, R19,
R20, R21, R22, R23, R24, R25, R26, R27, R28, R29,
F0, F1,
F20, F21, F22, F23, F24, F25, F26, F27, F28, F29, F30], Uses = [R29] in {
def BSR : BFormD<0x34, "bsr $$26,$$$DISP..ng", [], s_jsr>; //Branch to subroutine
}
-let isCall = 1, noResults = 1, Ra = 26, Rb = 27, disp = 0,
+let isCall = 1, Ra = 26, Rb = 27, disp = 0,
Defs = [R0, R1, R2, R3, R4, R5, R6, R7, R8, R16, R17, R18, R19,
R20, R21, R22, R23, R24, R25, R26, R27, R28, R29,
F0, F1,
def JSR : MbrForm< 0x1A, 0x01, (ops ), "jsr $$26,($$27),0", s_jsr>; //Jump to subroutine
}
-let isCall = 1, noResults = 1, Ra = 23, Rb = 27, disp = 0,
+let isCall = 1, Ra = 23, Rb = 27, disp = 0,
Defs = [R23, R24, R25, R27, R28], Uses = [R24, R25, R27] in
def JSRs : MbrForm< 0x1A, 0x01, (ops ), "jsr $$23,($$27),0", s_jsr>; //Jump to div or rem
let OutOperandList = (ops GPRC:$RA), InOperandList = (ops s64imm:$DISP, GPRC:$RB) in {
-def LDQ : MForm<0x29, 0, 1, "ldq $RA,$DISP($RB)",
+def LDQ : MForm<0x29, 1, "ldq $RA,$DISP($RB)",
[(set GPRC:$RA, (load (add GPRC:$RB, immSExt16:$DISP)))], s_ild>;
-def LDQr : MForm<0x29, 0, 1, "ldq $RA,$DISP($RB)\t\t!gprellow",
+def LDQr : MForm<0x29, 1, "ldq $RA,$DISP($RB)\t\t!gprellow",
[(set GPRC:$RA, (load (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_ild>;
-def LDL : MForm<0x28, 0, 1, "ldl $RA,$DISP($RB)",
+def LDL : MForm<0x28, 1, "ldl $RA,$DISP($RB)",
[(set GPRC:$RA, (sextloadi32 (add GPRC:$RB, immSExt16:$DISP)))], s_ild>;
-def LDLr : MForm<0x28, 0, 1, "ldl $RA,$DISP($RB)\t\t!gprellow",
+def LDLr : MForm<0x28, 1, "ldl $RA,$DISP($RB)\t\t!gprellow",
[(set GPRC:$RA, (sextloadi32 (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_ild>;
-def LDBU : MForm<0x0A, 0, 1, "ldbu $RA,$DISP($RB)",
+def LDBU : MForm<0x0A, 1, "ldbu $RA,$DISP($RB)",
[(set GPRC:$RA, (zextloadi8 (add GPRC:$RB, immSExt16:$DISP)))], s_ild>;
-def LDBUr : MForm<0x0A, 0, 1, "ldbu $RA,$DISP($RB)\t\t!gprellow",
+def LDBUr : MForm<0x0A, 1, "ldbu $RA,$DISP($RB)\t\t!gprellow",
[(set GPRC:$RA, (zextloadi8 (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_ild>;
-def LDWU : MForm<0x0C, 0, 1, "ldwu $RA,$DISP($RB)",
+def LDWU : MForm<0x0C, 1, "ldwu $RA,$DISP($RB)",
[(set GPRC:$RA, (zextloadi16 (add GPRC:$RB, immSExt16:$DISP)))], s_ild>;
-def LDWUr : MForm<0x0C, 0, 1, "ldwu $RA,$DISP($RB)\t\t!gprellow",
+def LDWUr : MForm<0x0C, 1, "ldwu $RA,$DISP($RB)\t\t!gprellow",
[(set GPRC:$RA, (zextloadi16 (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_ild>;
}
let OutOperandList = (ops), InOperandList = (ops GPRC:$RA, s64imm:$DISP, GPRC:$RB) in {
-def STB : MForm<0x0E, 1, 0, "stb $RA,$DISP($RB)",
- [(truncstorei8 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
-def STBr : MForm<0x0E, 1, 0, "stb $RA,$DISP($RB)\t\t!gprellow",
- [(truncstorei8 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
-def STW : MForm<0x0D, 1, 0, "stw $RA,$DISP($RB)",
- [(truncstorei16 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
-def STWr : MForm<0x0D, 1, 0, "stw $RA,$DISP($RB)\t\t!gprellow",
- [(truncstorei16 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
-def STL : MForm<0x2C, 1, 0, "stl $RA,$DISP($RB)",
- [(truncstorei32 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
-def STLr : MForm<0x2C, 1, 0, "stl $RA,$DISP($RB)\t\t!gprellow",
- [(truncstorei32 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
-def STQ : MForm<0x2D, 1, 0, "stq $RA,$DISP($RB)",
- [(store GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
-def STQr : MForm<0x2D, 1, 0, "stq $RA,$DISP($RB)\t\t!gprellow",
- [(store GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
+def STB : MForm<0x0E, 0, "stb $RA,$DISP($RB)",
+ [(truncstorei8 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
+def STBr : MForm<0x0E, 0, "stb $RA,$DISP($RB)\t\t!gprellow",
+ [(truncstorei8 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
+def STW : MForm<0x0D, 0, "stw $RA,$DISP($RB)",
+ [(truncstorei16 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
+def STWr : MForm<0x0D, 0, "stw $RA,$DISP($RB)\t\t!gprellow",
+ [(truncstorei16 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
+def STL : MForm<0x2C, 0, "stl $RA,$DISP($RB)",
+ [(truncstorei32 GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
+def STLr : MForm<0x2C, 0, "stl $RA,$DISP($RB)\t\t!gprellow",
+ [(truncstorei32 GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
+def STQ : MForm<0x2D, 0, "stq $RA,$DISP($RB)",
+ [(store GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_ist>;
+def STQr : MForm<0x2D, 0, "stq $RA,$DISP($RB)\t\t!gprellow",
+ [(store GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_ist>;
}
//Load address
let OutOperandList = (ops GPRC:$RA), InOperandList = (ops s64imm:$DISP, GPRC:$RB) in {
-def LDA : MForm<0x08, 0, 0, "lda $RA,$DISP($RB)",
+def LDA : MForm<0x08, 0, "lda $RA,$DISP($RB)",
[(set GPRC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_lda>;
-def LDAr : MForm<0x08, 0, 0, "lda $RA,$DISP($RB)\t\t!gprellow",
+def LDAr : MForm<0x08, 0, "lda $RA,$DISP($RB)\t\t!gprellow",
[(set GPRC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_lda>; //Load address
-def LDAH : MForm<0x09, 0, 0, "ldah $RA,$DISP($RB)",
+def LDAH : MForm<0x09, 0, "ldah $RA,$DISP($RB)",
[], s_lda>; //Load address high
-def LDAHr : MForm<0x09, 0, 0, "ldah $RA,$DISP($RB)\t\t!gprelhigh",
+def LDAHr : MForm<0x09, 0, "ldah $RA,$DISP($RB)\t\t!gprelhigh",
[(set GPRC:$RA, (Alpha_gprelhi tglobaladdr:$DISP, GPRC:$RB))], s_lda>; //Load address high
}
let OutOperandList = (ops), InOperandList = (ops F4RC:$RA, s64imm:$DISP, GPRC:$RB) in {
-def STS : MForm<0x26, 1, 0, "sts $RA,$DISP($RB)",
- [(store F4RC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_fst>;
-def STSr : MForm<0x26, 1, 0, "sts $RA,$DISP($RB)\t\t!gprellow",
- [(store F4RC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_fst>;
+def STS : MForm<0x26, 0, "sts $RA,$DISP($RB)",
+ [(store F4RC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_fst>;
+def STSr : MForm<0x26, 0, "sts $RA,$DISP($RB)\t\t!gprellow",
+ [(store F4RC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_fst>;
}
let OutOperandList = (ops F4RC:$RA), InOperandList = (ops s64imm:$DISP, GPRC:$RB) in {
-def LDS : MForm<0x22, 0, 1, "lds $RA,$DISP($RB)",
- [(set F4RC:$RA, (load (add GPRC:$RB, immSExt16:$DISP)))], s_fld>;
-def LDSr : MForm<0x22, 0, 1, "lds $RA,$DISP($RB)\t\t!gprellow",
- [(set F4RC:$RA, (load (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_fld>;
+def LDS : MForm<0x22, 1, "lds $RA,$DISP($RB)",
+ [(set F4RC:$RA, (load (add GPRC:$RB, immSExt16:$DISP)))], s_fld>;
+def LDSr : MForm<0x22, 1, "lds $RA,$DISP($RB)\t\t!gprellow",
+ [(set F4RC:$RA, (load (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_fld>;
}
let OutOperandList = (ops), InOperandList = (ops F8RC:$RA, s64imm:$DISP, GPRC:$RB) in {
-def STT : MForm<0x27, 1, 0, "stt $RA,$DISP($RB)",
- [(store F8RC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_fst>;
-def STTr : MForm<0x27, 1, 0, "stt $RA,$DISP($RB)\t\t!gprellow",
- [(store F8RC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_fst>;
+def STT : MForm<0x27, 0, "stt $RA,$DISP($RB)",
+ [(store F8RC:$RA, (add GPRC:$RB, immSExt16:$DISP))], s_fst>;
+def STTr : MForm<0x27, 0, "stt $RA,$DISP($RB)\t\t!gprellow",
+ [(store F8RC:$RA, (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB))], s_fst>;
}
let OutOperandList = (ops F8RC:$RA), InOperandList = (ops s64imm:$DISP, GPRC:$RB) in {
-def LDT : MForm<0x23, 0, 1, "ldt $RA,$DISP($RB)",
- [(set F8RC:$RA, (load (add GPRC:$RB, immSExt16:$DISP)))], s_fld>;
-def LDTr : MForm<0x23, 0, 1, "ldt $RA,$DISP($RB)\t\t!gprellow",
- [(set F8RC:$RA, (load (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_fld>;
+def LDT : MForm<0x23, 1, "ldt $RA,$DISP($RB)",
+ [(set F8RC:$RA, (load (add GPRC:$RB, immSExt16:$DISP)))], s_fld>;
+def LDTr : MForm<0x23, 1, "ldt $RA,$DISP($RB)\t\t!gprellow",
+ [(set F8RC:$RA, (load (Alpha_gprello tglobaladdr:$DISP, GPRC:$RB)))], s_fld>;
}
//load address, rellocated gpdist form
-let OutOperandList = (ops GPRC:$RA), InOperandList = (ops s16imm:$DISP, GPRC:$RB, s16imm:$NUM) in {
-def LDAg : MForm<0x08, 0, 1, "lda $RA,0($RB)\t\t!gpdisp!$NUM", [], s_lda>; //Load address
-def LDAHg : MForm<0x09, 0, 1, "ldah $RA,0($RB)\t\t!gpdisp!$NUM", [], s_lda>; //Load address
+let OutOperandList = (ops GPRC:$RA),
+ InOperandList = (ops s16imm:$DISP, GPRC:$RB, s16imm:$NUM),
+ mayLoad = 1 in {
+def LDAg : MForm<0x08, 1, "lda $RA,0($RB)\t\t!gpdisp!$NUM", [], s_lda>; //Load address
+def LDAHg : MForm<0x09, 1, "ldah $RA,0($RB)\t\t!gpdisp!$NUM", [], s_lda>; //Load address
}
//Load quad, rellocated literal form
let OutOperandList = (ops GPRC:$RA), InOperandList = (ops s64imm:$DISP, GPRC:$RB) in
-def LDQl : MForm<0x29, 0, 1, "ldq $RA,$DISP($RB)\t\t!literal",
+def LDQl : MForm<0x29, 1, "ldq $RA,$DISP($RB)\t\t!literal",
[(set GPRC:$RA, (Alpha_rellit tglobaladdr:$DISP, GPRC:$RB))], s_ild>;
def : Pat<(Alpha_rellit texternalsym:$ext, GPRC:$RB),
(LDQl texternalsym:$ext, GPRC:$RB)>;
+let OutOperandList = (outs GPRC:$RR),
+ InOperandList = (ins GPRC:$RA, s64imm:$DISP, GPRC:$RB),
+ Constraints = "$RA = $RR",
+ DisableEncoding = "$RR" in {
+def STQ_C : MForm<0x2F, 0, "stq_l $RA,$DISP($RB)", [], s_ist>;
+def STL_C : MForm<0x2E, 0, "stl_l $RA,$DISP($RB)", [], s_ist>;
+}
+let OutOperandList = (ops GPRC:$RA),
+ InOperandList = (ops s64imm:$DISP, GPRC:$RB),
+ mayLoad = 1 in {
+def LDQ_L : MForm<0x2B, 1, "ldq_l $RA,$DISP($RB)", [], s_ild>;
+def LDL_L : MForm<0x2A, 1, "ldl_l $RA,$DISP($RB)", [], s_ild>;
+}
def RPCC : MfcForm<0x18, 0xC000, "rpcc $RA", s_rpcc>; //Read process cycle counter
+def MB : MfcPForm<0x18, 0x4000, "mb", s_imisc>; //memory barrier
+def WMB : MfcPForm<0x18, 0x4400, "wmb", s_imisc>; //write memory barrier
+
+def : Pat<(membarrier (i64 imm), (i64 imm), (i64 imm), (i64 1), (i64 imm)),
+ (WMB)>;
+def : Pat<(membarrier (i64 imm), (i64 imm), (i64 imm), (i64 imm), (i64 imm)),
+ (MB)>;
//Basic Floating point ops
//misc FP selects
//Select double
-
+
def : Pat<(select (seteq F8RC:$RA, F8RC:$RB), F8RC:$st, F8RC:$sf),
(FCMOVNET F8RC:$sf, F8RC:$st, (CMPTEQ F8RC:$RA, F8RC:$RB))>;
def : Pat<(select (setoeq F8RC:$RA, F8RC:$RB), F8RC:$st, F8RC:$sf),
let OutOperandList = (ops GPRC:$RC), InOperandList = (ops F4RC:$RA), Fb = 31 in
-def FTOIS : FPForm<0x1C, 0x078, "ftois $RA,$RC",[], s_ftoi>; //Floating to integer move, S_floating
+def FTOIS : FPForm<0x1C, 0x078, "ftois $RA,$RC",
+ [(set GPRC:$RC, (bitconvert F4RC:$RA))], s_ftoi>; //Floating to integer move, S_floating
let OutOperandList = (ops GPRC:$RC), InOperandList = (ops F8RC:$RA), Fb = 31 in
def FTOIT : FPForm<0x1C, 0x070, "ftoit $RA,$RC",
[(set GPRC:$RC, (bitconvert F8RC:$RA))], s_ftoi>; //Floating to integer move
let OutOperandList = (ops F4RC:$RC), InOperandList = (ops GPRC:$RA), Fb = 31 in
-def ITOFS : FPForm<0x14, 0x004, "itofs $RA,$RC",[], s_itof>; //Integer to floating move, S_floating
+def ITOFS : FPForm<0x14, 0x004, "itofs $RA,$RC",
+ [(set F4RC:$RC, (bitconvert GPRC:$RA))], s_itof>; //Integer to floating move, S_floating
let OutOperandList = (ops F8RC:$RC), InOperandList = (ops GPRC:$RA), Fb = 31 in
def ITOFT : FPForm<0x14, 0x024, "itoft $RA,$RC",
[(set F8RC:$RC, (bitconvert GPRC:$RA))], s_itof>; //Integer to floating move
def CVTTS : FPForm<0x16, 0x7AC, "cvtts/sui $RB,$RC",
[(set F4RC:$RC, (fround F8RC:$RB))], s_fadd>;
+def : Pat<(select GPRC:$RC, F8RC:$st, F8RC:$sf),
+ (f64 (FCMOVEQT F8RC:$st, F8RC:$sf, (ITOFT GPRC:$RC)))>;
+def : Pat<(select GPRC:$RC, F4RC:$st, F4RC:$sf),
+ (f32 (FCMOVEQS F4RC:$st, F4RC:$sf, (ITOFT GPRC:$RC)))>;
/////////////////////////////////////////////////////////
//Branching
: BFormN<opc, (ops u64imm:$opc, F8RC:$R, target:$dst),
!strconcat(asmstr, " $R,$dst"), s_fbr>;
-let isBranch = 1, isTerminator = 1, hasCtrlDep = 1, noResults = 1 in {
+let isBranch = 1, isTerminator = 1, hasCtrlDep = 1 in {
let Ra = 31 in
def BR : BFormD<0x30, "br $$31,$DISP", [(br bb:$DISP)], s_ubr>;
//An ugly trick to get the opcode as an imm I can use
def immBRCond : SDNodeXForm<imm, [{
- switch((uint64_t)N->getValue()) {
+ switch((uint64_t)N->getZExtValue()) {
+ default: assert(0 && "Unknown branch type");
case 0: return getI64Imm(Alpha::BEQ);
case 1: return getI64Imm(Alpha::BNE);
case 2: return getI64Imm(Alpha::BGE);
case 23: return getI64Imm(Alpha::FBGT);
case 24: return getI64Imm(Alpha::FBLE);
case 25: return getI64Imm(Alpha::FBLT);
- default: assert(0 && "Unknown branch type");
}
}]>;
//EXCB Mfc 18.0400 Exception barrier
//FETCH Mfc 18.8000 Prefetch data
//FETCH_M Mfc 18.A000 Prefetch data, modify intent
-//LDL_L Mem 2A Load sign-extended longword locked
-//LDQ_L Mem 2B Load quadword locked
//LDQ_U Mem 0B Load unaligned quadword
//MB Mfc 18.4000 Memory barrier
-//STL_C Mem 2E Store longword conditional
-//STQ_C Mem 2F Store quadword conditional
//STQ_U Mem 0F Store unaligned quadword
//TRAPB Mfc 18.0000 Trap barrier
//WH64 Mfc 18.F800 Write hint \14 64 bytes
def immConst2Part : PatLeaf<(imm), [{
//true if imm fits in a LDAH LDA pair
- int64_t val = (int64_t)N->getValue();
+ int64_t val = (int64_t)N->getZExtValue();
return (val <= IMM_FULLHIGH && val >= IMM_FULLLOW);
}]>;
def immConst2PartInt : PatLeaf<(imm), [{
//true if imm fits in a LDAH LDA pair with zeroext
- uint64_t uval = N->getValue();
+ uint64_t uval = N->getZExtValue();
int32_t val32 = (int32_t)uval;
return ((uval >> 32) == 0 && //empty upper bits
val32 <= IMM_FULLHIGH);
(ADDQr (SLr GPRC:$RA, (nearP2X immRemP2:$imm)), (SLi GPRC:$RA, (nearP2RemX immRemP2:$imm)))>;
//n is below a power of 2
-def : Pat<(mul GPRC:$RA, immRem1n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRem1n:$imm)), GPRC:$RA)>;
-def : Pat<(mul GPRC:$RA, immRem2n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRem2n:$imm)), (ADDQr GPRC:$RA, GPRC:$RA))>;
-def : Pat<(mul GPRC:$RA, immRem3n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRem3n:$imm)), (S4SUBQr GPRC:$RA, GPRC:$RA))>;
-def : Pat<(mul GPRC:$RA, immRem4n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRem4n:$imm)), (SLi GPRC:$RA, 2))>;
-def : Pat<(mul GPRC:$RA, immRem5n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRem5n:$imm)), (S4ADDQr GPRC:$RA, GPRC:$RA))>;
-def : Pat<(mul GPRC:$RA, immRemP2n:$imm),
- (SUBQr (SLr GPRC:$RA, (nearP2X immRemP2n:$imm)), (SLi GPRC:$RA, (nearP2RemX immRemP2n:$imm)))>;
+//FIXME: figure out why something is truncating the imm to 32bits
+// this will fix 2007-11-27-mulneg3
+//def : Pat<(mul GPRC:$RA, immRem1n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRem1n:$imm)), GPRC:$RA)>;
+//def : Pat<(mul GPRC:$RA, immRem2n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRem2n:$imm)), (ADDQr GPRC:$RA, GPRC:$RA))>;
+//def : Pat<(mul GPRC:$RA, immRem3n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRem3n:$imm)), (S4SUBQr GPRC:$RA, GPRC:$RA))>;
+//def : Pat<(mul GPRC:$RA, immRem4n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRem4n:$imm)), (SLi GPRC:$RA, 2))>;
+//def : Pat<(mul GPRC:$RA, immRem5n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRem5n:$imm)), (S4ADDQr GPRC:$RA, GPRC:$RA))>;
+//def : Pat<(mul GPRC:$RA, immRemP2n:$imm),
+// (SUBQr (SLr GPRC:$RA, (nearP2X immRemP2n:$imm)), (SLi GPRC:$RA, (nearP2RemX immRemP2n:$imm)))>;
} //Added complexity