--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Base class for sparc instructions, and some support functions
+//
+
+output header {{
+ /**
+ * Base class for all SPARC static instructions.
+ */
+ class SparcStaticInst : public StaticInst<SPARCISA>
+ {
+ protected:
+
+ // Constructor.
+ SparcStaticInst(const char *mnem, MachInst _machInst, OpClass __opClass)
+ : StaticInst<SPARCISA>(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+
+ bool passesCondition(struct {uint8_t c:1; uint8_t v:1; uint8_t z:1; uint8_t n:1} codes, uint8_t condition);
+}};
+
+output decoder {{
+
+ std::string SparcStaticInst::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ std::stringstream ss;
+
+ ccprintf(ss, "%-10s ", mnemonic);
+
+ // just print the first two source regs... if there's
+ // a third one, it's a read-modify-write dest (Rc),
+ // e.g. for CMOVxx
+ if(_numSrcRegs > 0)
+ {
+ printReg(ss, _srcRegIdx[0]);
+ }
+ if(_numSrcRegs > 1)
+ {
+ ss << ",";
+ printReg(ss, _srcRegIdx[1]);
+ }
+
+ // just print the first dest... if there's a second one,
+ // it's generally implicit
+ if(_numDestRegs > 0)
+ {
+ if(_numSrcRegs > 0)
+ ss << ",";
+ printReg(ss, _destRegIdx[0]);
+ }
+
+ return ss.str();
+ }
+
+ bool passesCondition(struct {uint8_t c:1; uint8_t v:1; uint8_t z:1; uint8_t n:1} codes, uint8_t condition)
+ {
+ switch(condition)
+ {
+ case 0b1000: return true;
+ case 0b0000: return false;
+ case 0b1001: return !codes.z;
+ case 0b0001: return codes.z;
+ case 0b1010: return !(codes.z | (codes.n ^ codes.v));
+ case 0b0010: return codes.z | (codes.n ^ codes.v);
+ case 0b1011: return !(codes.n ^ codes.v);
+ case 0b0011: return (codes.n ^ codes.v);
+ case 0b1100: return !(codes.c | codes.z);
+ case 0b0100: return (codes.c | codes.z);
+ case 0b1101: return !codes.c;
+ case 0b0101: return codes.c;
+ case 0b1110: return !codes.n;
+ case 0b0110: return codes.n;
+ case 0b1111: return !codes.v;
+ case 0b0111: return codes.v;
+ }
+ }
+}};
+
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Bitfield definitions.
+//
+
+// Bitfields are shared liberally between instruction formats, so they are
+// simply defined alphabetically
+
+def bitfield A <29>;
+def bitfield CC02 <20>;
+def bitfield CC03 <25>;
+def bitfield CC04 <11>;
+def bitfield CC12 <21>;
+def bitfield CC13 <26>;
+def bitfield CC14 <12>;
+def bitfield CC2 <18>;
+def bitfield CMASK <6:4>;
+def bitfield COND2 <28:25>;
+def bitfield COND4 <17:14>;
+def bitfield D16HI <21:20>;
+def bitfield D16LO <13:0>;
+def bitfield DISP19 <18:0>;
+def bitfield DISP22 <21:0>;
+def bitfield DISP30 <29:0>;
+def bitfield FCN <29:26>;
+def bitfield I <13>;
+def bitfield IMM_ASI <12:5>;
+def bitfield IMM22 <21:0>;
+def bitfield MMASK <3:0>;
+def bitfield OP <31:30>;
+def bitfield OP2 <24:22>;
+def bitfield OP3 <24:19>;
+def bitfield OPF <13:5>;
+def bitfield OPF_CC <13:11>;
+def bitfield OPF_LOW5 <9:5>;
+def bitfield OPF_LOW6 <10:5>;
+def bitfield P <19>;
+def bitfield RCOND2 <27:25>;
+def bitfield RCOND3 <12:10>;
+def bitfield RCOND4 <12:10>;
+def bitfield RD <29:25>;
+def bitfield RS1 <18:14>;
+def bitfield RS2 <4:0>;
+def bitfield SHCNT32 <4:0>;
+def bitfield SHCNT64 <5:0>;
+def bitfield SIMM10 <9:0>;
+def bitfield SIMM11 <10:0>;
+def bitfield SIMM13 <12:0>;
+def bitfield SW_TRAP <6:0>;
+def bitfield X <12>;
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// The actual decoder specification
+//
+
+decode OP default Trap::unknown({{illegal_instruction}}) {
+
+ 0x0: decode OP2 {
+ 0x0: Trap::illtrap({{illegal_instruction}}); //ILLTRAP
+ 0x1: Branch::bpcc({{
+ switch((CC12 << 1) | CC02)
+ {
+ case 1: case 3:
+ throw illegal_instruction;
+ case 0:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.icc, COND2))
+ ;//branchHere
+ break;
+ case 2:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.xcc, COND2))
+ ;//branchHere
+ break;
+ }
+ }});//BPcc
+ 0x2: Branch::bicc({{
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.icc, COND2))
+ ;//branchHere
+ }});//Bicc
+ 0x3: Branch::bpr({{
+ switch(RCOND)
+ {
+ case 0: case 4:
+ throw illegal_instruction;
+ case 1:
+ if(Rs1 == 0) ;//branchHere
+ break;
+ case 2:
+ if(Rs1 <= 0) ;//branchHere
+ break;
+ case 3:
+ if(Rs1 < 0) ;//branchHere
+ break;
+ case 5:
+ if(Rs1 != 0) ;//branchHere
+ break;
+ case 6:
+ if(Rs1 > 0) ;//branchHere
+ break;
+ case 7:
+ if(Rs1 >= 0) ;//branchHere
+ break;
+ }
+ }}); //BPr
+ 0x4: IntegerOp::sethi({{Rd = (IMM22 << 10) & 0xFFFFFC00;}}); //SETHI (or NOP if rd == 0 and imm == 0)
+ 0x5: Trap::fbpfcc({{throw fp_disabled;}}); //FBPfcc
+ 0x6: Trap::fbfcc({{throw fp_disabled;}}); //FBfcc
+ }
+ 0x1: Branch::call({{
+ //branch here
+ Rd = xc->pc;
+ }});
+ 0x2: decode OP3 {
+ format IntegerOp {
+ 0x00: add({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ Rd = Rs1.sdw + val2;
+ }});//ADD
+ 0x01: and({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = Rs1.udw & val2;
+ }});//AND
+ 0x02: or({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = Rs1.udw | val2;
+ }});//OR
+ 0x03: xor({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = Rs1.udw ^ val2;
+ }});//XOR
+ 0x04: sub({{
+ INT64 val2 = ~((UINT64)(I ? SIMM13.sdw : Rs2.udw))+1;
+ Rd = Rs1.sdw + val2;
+ }});//SUB
+ 0x05: andn({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = Rs1.udw & ~val2;
+ }});//ANDN
+ 0x06: orn({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = Rs1.udw | ~val2;
+ }});//ORN
+ 0x07: xnor({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = ~(Rs1.udw ^ val2);
+ }});//XNOR
+ 0x08: addc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ INT64 carryin = xc->regs.MiscRegs.ccrfields.iccfields.c;
+ Rd = Rs1.sdw + val2 + carryin;
+ }});//ADDC
+ 0x09: mulx({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 * val2;
+ }});//MULX
+ 0x0A: umul({{
+ UINT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2.udw);
+ Rd = resTemp = Rs1.udw<31:0> * val2<31:0>;
+ xc->regs.MiscRegs.yFields.value = resTemp<63:32>;
+ }});//UMUL
+ 0x0B: smul({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ rd.sdw = resTemp = Rs1.sdw<31:0> * val2<31:0>;
+ xc->regs.MiscRegs.yFields.value = resTemp<63:32>;
+ }});//SMUL
+ 0x0C: subc({{
+ INT64 val2 = ~((INT64)(I ? SIMM13.sdw : Rs2.sdw))+1;
+ INT64 carryin = xc->regs.MiscRegs.ccrfields.iccfields.c;
+ Rd.sdw = Rs1.sdw + val2 + carryin;
+ }});//SUBC
+ 0x0D: udivx({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ if(val2 == 0) throw division_by_zero;
+ Rd.udw = Rs1.udw / val2;
+ }});//UDIVX
+ 0x0E: udiv({{
+ UINT32 resTemp, val2 = (I ? SIMM13.sw : Rs2.udw<31:0>);
+ if(val2 == 0) throw division_by_zero;
+ resTemp = (UINT64)((xc->regs.MiscRegs.yFields.value << 32) | Rs1.udw<31:0>) / val2;
+ INT32 overflow = (resTemp<63:32> != 0);
+ if(overflow) rd.udw = resTemp = 0xFFFFFFFF;
+ else rd.udw = resTemp;
+ }}); //UDIV
+ 0x0F: sdiv({{
+ INT32 resTemp, val2 = (I ? SIMM13.sw : Rs2.sdw<31:0>);
+ if(val2 == 0) throw division_by_zero;
+ Rd.sdw = resTemp = (INT64)((xc->regs.MiscRegs.yFields.value << 32) | Rs1.sdw<31:0>) / val2;
+ INT32 overflow = (resTemp<63:31> != 0);
+ INT32 underflow = (resTemp<63:> && resTemp<62:31> != 0xFFFFFFFF);
+ if(overflow) rd.udw = resTemp = 0x7FFFFFFF;
+ else if(underflow) rd.udw = resTemp = 0xFFFFFFFF80000000;
+ else rd.udw = resTemp;
+ }});//SDIV
+ }
+ format IntegerOpCc {
+ 0x10: addcc({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 + val2;}},
+ {{((Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31)}},
+ {{Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>}},
+ {{((Rs1 >> 1) + (val2 >> 1) + (Rs1 & val2 & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//ADDcc
+ 0x11: andcc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 & val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//ANDcc
+ 0x12: orcc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 | val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//ORcc
+ 0x13: xorcc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 ^ val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//XORcc
+ 0x14: subcc({{
+ INT64 resTemp, val2 = (INT64)(I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 - val2;}},
+ {{((Rs1 & 0xFFFFFFFF + (~val2) & 0xFFFFFFFF + 1) >> 31)}},
+ {{Rs1<31:> != val2<31:> && Rs1<31:> != resTemp<31:>}},
+ {{((Rs1 >> 1) + (~val2) >> 1) + ((Rs1 | ~val2) & 0x1))<63:>}},
+ {{Rs1<63:> != val2<63:> && Rs1<63:> != resTemp<63:>}}
+ );//SUBcc
+ 0x15: andncc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 & ~val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//ANDNcc
+ 0x16: orncc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = Rs1 | ~val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//ORNcc
+ 0x17: xnorcc({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = ~(Rs1 ^ val2);}}
+ ,{{0}},{{0}},{{0}},{{0}});//XNORcc
+ 0x18: addccc({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ INT64 carryin = xc->regs.MiscRegs.ccrfields.iccfields.c;
+ Rd = resTemp = Rs1 + val2 + carryin;}},
+ {{((Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31 + carryin)}},
+ {{Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>}},
+ {{((Rs1 >> 1) + (val2 >> 1) + ((Rs1 & val2) | (carryin & (Rs1 | val2)) & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//ADDCcc
+ 0x1A: umulcc({{
+ UINT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1.udw<31:0> * val2<31:0>;
+ xc->regs.MiscRegs.yFields.value = resTemp<63:32>;}}
+ ,{{0}},{{0}},{{0}},{{0}});//UMULcc
+ 0x1B: smulcc({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1.sdw<31:0> * val2<31:0>;
+ xc->regs.MiscRegs.yFields.value = resTemp<63:32>;}}
+ ,{{0}},{{0}},{{0}},{{0}});//SMULcc
+ 0x1C: subccc({{
+ INT64 resTemp, val2 = (INT64)(I ? SIMM13.sdw : Rs2);
+ INT64 carryin = xc->regs.MiscRegs.ccrfields.iccfields.c;
+ Rd = resTemp = Rs1 + ~(val2 + carryin) + 1;}},
+ {{((Rs1 & 0xFFFFFFFF + (~(val2 + carryin)) & 0xFFFFFFFF + 1) >> 31)}},
+ {{Rs1<31:> != val2<31:> && Rs1<31:> != resTemp<31:>}},
+ {{((Rs1 >> 1) + (~(val2 + carryin)) >> 1) + ((Rs1 | ~(val2+carryin)) & 0x1))<63:>}},
+ {{Rs1<63:> != val2<63:> && Rs1<63:> != resTemp<63:>}}
+ );//SUBCcc
+ 0x1D: udivxcc({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.udw);
+ if(val2 == 0) throw division_by_zero;
+ Rd.udw = Rs1.udw / val2;}}
+ ,{{0}},{{0}},{{0}},{{0}});//UDIVXcc
+ 0x1E: udivcc({{
+ UINT32 resTemp, val2 = (I ? SIMM13.sw : Rs2.udw<31:0>);
+ if(val2 == 0) throw division_by_zero;
+ resTemp = (UINT64)((xc->regs.MiscRegs.yFields.value << 32) | Rs1.udw<31:0>) / val2;
+ INT32 overflow = (resTemp<63:32> != 0);
+ if(overflow) rd.udw = resTemp = 0xFFFFFFFF;
+ else rd.udw = resTemp;}},
+ {{0}},
+ {{overflow}},
+ {{0}},
+ {{0}}
+ );//UDIVcc
+ 0x1F: sdivcc({{
+ INT32 resTemp, val2 = (I ? SIMM13.sw : Rs2.sdw<31:0>);
+ if(val2 == 0) throw division_by_zero;
+ Rd.sdw = resTemp = (INT64)((xc->regs.MiscRegs.yFields.value << 32) | Rs1.sdw<31:0>) / val2;
+ INT32 overflow = (resTemp<63:31> != 0);
+ INT32 underflow = (resTemp<63:> && resTemp<62:31> != 0xFFFFFFFF);
+ if(overflow) rd.udw = resTemp = 0x7FFFFFFF;
+ else if(underflow) rd.udw = resTemp = 0xFFFFFFFF80000000;
+ else rd.udw = resTemp;}},
+ {{0}},
+ {{overflow || underflow}},
+ {{0}},
+ {{0}}
+ );//SDIVcc
+ 0x20: taddcc({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 + val2;
+ INT32 overflow = Rs1<1:0> || val2<1:0> || (Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>);}},
+ {{((Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31)}},
+ {{overflow}},
+ {{((Rs1 >> 1) + (val2 >> 1) + (Rs1 & val2 & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//TADDcc
+ 0x21: tsubcc({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 + val2;
+ INT32 overflow = Rs1<1:0> || val2<1:0> || (Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>);}},
+ {{(Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31)}},
+ {{overflow}},
+ {{((Rs1 >> 1) + (val2 >> 1) + (Rs1 & val2 & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//TSUBcc
+ 0x22: taddcctv({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 + val2;
+ INT32 overflow = Rs1<1:0> || val2<1:0> || (Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>);
+ if(overflow) throw tag_overflow;}},
+ {{((Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31)}},
+ {{overflow}},
+ {{((Rs1 >> 1) + (val2 >> 1) + (Rs1 & val2 & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//TADDccTV
+ 0x23: tsubcctv({{
+ INT64 resTemp, val2 = (I ? SIMM13.sdw : Rs2);
+ Rd = resTemp = Rs1 + val2;
+ INT32 overflow = Rs1<1:0> || val2<1:0> || (Rs1<31:> == val2<31:> && val2<31:> != resTemp<31:>);
+ if(overflow) throw tag_overflow;}},
+ {{((Rs1 & 0xFFFFFFFF + val2 & 0xFFFFFFFF) >> 31)}},
+ {{overflow}},
+ {{((Rs1 >> 1) + (val2 >> 1) + (Rs1 & val2 & 0x1))<63:>}},
+ {{Rs1<63:> == val2<63:> && val2<63:> != resTemp<63:>}}
+ );//TSUBccTV
+ 0x24: mulscc({{
+ INT64 resTemp, multiplicand = (I ? SIMM13.sdw : Rs2);
+ INT32 multiplier = Rs1<31:0>;
+ INT32 savedLSB = Rs1<0:>;
+ multiplier = multipler<31:1> |
+ ((xc->regs.MiscRegs.ccrFields.iccFields.n
+ ^ xc->regs.MiscRegs.ccrFields.iccFields.v) << 32);
+ if(!xc->regs.MiscRegs.yFields.value<0:>)
+ multiplicand = 0;
+ Rd = resTemp = multiplicand + multiplier;
+ xc->regs.MiscRegs.yFields.value = xc->regs.MiscRegs.yFields.value<31:1> | (savedLSB << 31);}},
+ {{((multiplicand & 0xFFFFFFFF + multiplier & 0xFFFFFFFF) >> 31)}},
+ {{multiplicand<31:> == multiplier<31:> && multiplier<31:> != resTemp<31:>}},
+ {{((multiplicand >> 1) + (multiplier >> 1) + (multiplicand & multiplier & 0x1))<63:>}},
+ {{multiplicand<63:> == multiplier<63:> && multiplier<63:> != resTemp<63:>}}
+ );//MULScc
+ }
+ format IntegerOp
+ {
+ 0x25: decode X {
+ 0x0: sll({{Rd = Rs1 << (I ? SHCNT32 : Rs2<4:0>);}}); //SLL
+ 0x1: sllx({{Rd = Rs1 << (I ? SHCNT64 : Rs2<5:0>);}}); //SLLX
+ }
+ 0x26: decode X {
+ 0x0: srl({{Rd = Rs1.udw<31:0> >> (I ? SHCNT32 : Rs2<4:0>);}}); //SRL
+ 0x1: srlx({{Rd = Rs1.udw >> (I ? SHCNT64 : Rs2<5:0>);}});//SRLX
+ }
+ 0x27: decode X {
+ 0x0: sra({{Rd = Rs1.sdw<31:0> >> (I ? SHCNT32 : Rs2<4:0>);}}); //SRA
+ 0x1: srax({{Rd = Rs1.sdw >> (I ? SHCNT64 : Rs2<5:0>);}});//SRAX
+ }
+ 0x28: decode RS1 {
+ 0x0: rdy({{Rd = xc->regs.MiscRegs.yFields.value;}}); //RDY
+ 0x2: rdccr({{Rd = xc->regs.MiscRegs.ccr;}}); //RDCCR
+ 0x3: rdasi({{Rd = xc->regs.MiscRegs.asi;}}); //RDASI
+ 0x4: rdtick({{
+ if(xc->regs.MiscRegs.pstateFields.priv == 0 &&
+ xc->regs.MiscRegs.tickFields.npt == 1)
+ throw privileged_action;
+ Rd = xc->regs.MiscRegs.tick;
+ }});//RDTICK
+ 0x5: rdpc({{Rd = xc->regs.pc;}}); //RDPC
+ 0x6: rdfprs({{Rd = xc->regs.MiscRegs.fprs;}}); //RDFPRS
+ 0xF: decode I {
+ 0x0: Noop::membar({{//Membar isn't needed yet}}); //MEMBAR
+ 0x1: Noop::stbar({{//Stbar isn/'t needed yet}}); //STBAR
+ }
+ }
+
+ 0x2A: decode RS1 {
+ 0x0: rdprtpc({{checkPriv Rd = xc->regs.MiscRegs.tpc[xc->regs.MiscRegs.tl];}});
+ 0x1: rdprtnpc({{checkPriv Rd = xc->regs.MiscRegs.tnpc[xc->regs.MiscRegs.tl];}});
+ 0x2: rdprtstate({{checkPriv Rd = xc->regs.MiscRegs.tstate[xc->regs.MiscRegs.tl];}});
+ 0x3: rdprtt({{checkPriv Rd = xc->regs.MiscRegs.tt[xc->regs.MiscRegs.tl];}});
+ 0x4: rdprtick({{checkPriv Rd = xc->regs.MiscRegs.tick;}});
+ 0x5: rdprtba({{checkPriv Rd = xc->regs.MiscRegs.tba;}});
+ 0x6: rdprpstate({{checkPriv Rd = xc->regs.MiscRegs.pstate;}});
+ 0x7: rdprtl({{checkPriv Rd = xc->regs.MiscRegs.tl;}});
+ 0x8: rdprpil({{checkPriv Rd = xc->regs.MiscRegs.pil;}});
+ 0x9: rdprcwp({{checkPriv Rd = xc->regs.MiscRegs.cwp;}});
+ 0xA: rdprcansave({{checkPriv Rd = xc->regs.MiscRegs.cansave;}});
+ 0xB: rdprcanrestore({{checkPriv Rd = xc->regs.MiscRegs.canrestore;}});
+ 0xC: rdprcleanwin({{checkPriv Rd = xc->regs.MiscRegs.cleanwin;}});
+ 0xD: rdprotherwin({{checkPriv Rd = xc->regs.MiscRegs.otherwin;}});
+ 0xE: rdprwstate({{checkPriv Rd = xc->regs.MiscRegs.wstate;}});
+ 0xF: rdprfq({{throw illegal_instruction;}}); //The floating point queue isn't implemented right now.
+ }
+ 0x2B: BasicOperate::flushw({{\\window toilet}}); //FLUSHW
+ 0x2C: movcc({{
+ ccBank = (CC24 << 2) | (CC14 << 1) | (CC04 << 0);
+ switch(ccBank)
+ {
+ case 0: case 1: case 2: case 3:
+ throw fp_disabled;
+ break;
+ case 5: case 7:
+ throw illegal_instruction;
+ break;
+ case 4:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.icc, COND4))
+ Rd = (I ? SIMM11.sdw : RS2);
+ break;
+ case 6:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.xcc, COND4))
+ Rd = (I ? SIMM11.sdw : RS2);
+ break;
+ }
+ }});//MOVcc
+ 0x2D: sdivx({{
+ INT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ if(val2 == 0) throw division_by_zero;
+ Rd.sdw = Rs1.sdw / val2;
+ }});//SDIVX
+ 0x2E: decode RS1 {
+ 0x0: IntegerOp::popc({{
+ INT64 count = 0, val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ UINT8 oneBits[] = {0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4}
+ for(unsigned int x = 0; x < 16; x++)
+ {
+ count += oneBits[val2 & 0xF];
+ val2 >> 4;
+ }
+ }});//POPC
+ }
+ 0x2F: movr({{
+ UINT64 val2 = (I ? SIMM10.sdw : Rs2.sdw);
+ switch(RCOND)
+ {
+ case 0: case 4:
+ throw illegal_instruction;
+ break;
+ case 1:
+ if(Rs1 == 0) Rd = val2;
+ break;
+ case 2:
+ if(Rs1 <= 0) Rd = val2;
+ break;
+ case 3:
+ if(Rs1 = 0) Rd = val2;
+ break;
+ case 5:
+ if(Rs1 != 0) Rd = val2;
+ break;
+ case 6:
+ if(Rs1 > 0) Rd = val2;
+ break;
+ case 7:
+ if(Rs1 >= 0) Rd = val2;
+ break;
+ }
+ }});//MOVR
+ 0x30: decode RD {
+ 0x0: wry({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.y = Rs1 ^ val2;
+ }});//WRY
+ 0x2: wrccr({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.ccr = Rs1 ^ val2;
+ }});//WRCCR
+ 0x3: wrasi({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.asi = Rs1 ^ val2;
+ }});//WRASI
+ 0x6: wrfprs({{
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.asi = Rs1 ^ val2;
+ }});//WRFPRS
+ 0xF: Trap::sir({{software_initiated_reset}}); //SIR
+ }
+ 0x31: decode FCN {
+ 0x0: BasicOperate::saved({{\\Boogy Boogy}}); //SAVED
+ 0x1: BasicOperate::restored({{\\Boogy Boogy}}); //RESTORED
+ }
+ 0x32: decode RD {
+ 0x0: wrprtpc({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tpc[xc->regs.MiscRegs.tl] = Rs1 ^ val2;
+ }});
+ 0x1: wrprtnpc({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tnpc[xc->regs.MiscRegs.tl] = Rs1 ^ val2;
+ }});
+ 0x2: wrprtstate({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tstate[xc->regs.MiscRegs.tl] = Rs1 ^ val2;
+ }});
+ 0x3: wrprtt({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tt[xc->regs.MiscRegs.tl] = Rs1 ^ val2;
+ }});
+ 0x4: wrprtick({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tick = Rs1 ^ val2;
+ }});
+ 0x5: wrprtba({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tba = Rs1 ^ val2;
+ }});
+ 0x6: wrprpstate({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.pstate = Rs1 ^ val2;
+ }});
+ 0x7: wrprtl({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.tl = Rs1 ^ val2;
+ }});
+ 0x8: wrprpil({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.pil = Rs1 ^ val2;
+ }});
+ 0x9: wrprcwp({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.cwp = Rs1 ^ val2;
+ }});
+ 0xA: wrprcansave({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.cansave = Rs1 ^ val2;
+ }});
+ 0xB: wrprcanrestore({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.canrestore = Rs1 ^ val2;
+ }});
+ 0xC: wrprcleanwin({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.cleanwin = Rs1 ^ val2;
+ }});
+ 0xD: wrprotherwin({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.otherwin = Rs1 ^ val2;
+ }});
+ 0xE: wrprwstate({{checkPriv
+ UINT64 val2 = (I ? SIMM13.sdw : Rs2.sdw);
+ xc->regs.MiscRegs.wstate = Rs1 ^ val2;
+ }});
+ }
+
+ 0x34: Trap::fpop1({{Throw fp_disabled;}}); //FPOP1
+ 0x35: Trap::fpop2({{Throw fp_disabled;}}); //FPOP2
+
+
+ 0x38: Branch::jmpl({{//Stuff}}); //JMPL
+ 0x39: Branch::return({{//Other Stuff}}); //RETURN
+ 0x3A: Trap::tcc({{
+ switch((CC14 << 1) | (CC04 << 0))
+ {
+ case 1: case 3:
+ throw illegal_instruction;
+ case 0:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.icc, machInst<25:28>))
+ throw trap_instruction;
+ break;
+ case 2:
+ if(passesCondition(xc->regs.MiscRegs.ccrFields.xcc, machInst<25:28>))
+ throw trap_instruction;
+ break;
+ }
+ }}); //Tcc
+ 0x3B: BasicOperate::flush({{//Lala}}); //FLUSH
+ 0x3C: BasicOperate::save({{//leprechauns); //SAVE
+ 0x3D: BasicOperate::restore({{//Eat my short int}}); //RESTORE
+ 0x3E: decode FCN {
+ 0x1: BasicOperate::done({{//Done thing}}); //DONE
+ 0x2: BasicOperate::retry({{//Retry thing}}); //RETRY
+ }
+ }
+ }
+ 0x3: decode OP3 {
+ format Mem {
+ 0x00: lduw({{Rd.uw = Mem.uw;}}); //LDUW
+ 0x01: ldub({{Rd.ub = Mem.ub;}}); //LDUB
+ 0x02: lduh({{Rd.uhw = Mem.uhw;}}); //LDUH
+ 0x03: ldd({{
+ UINT64 val = Mem.udw;
+ setIntReg(RD & (~1), val<31:0>);
+ setIntReg(RD | 1, val<63:32>);
+ }});//LDD
+ 0x04: stw({{Mem.sw = Rd.sw;}}); //STW
+ 0x05: stb({{Mem.sb = Rd.sb;}}); //STB
+ 0x06: sth({{Mem.shw = Rd.shw;}}); //STH
+ 0x07: std({{
+ Mem.udw = readIntReg(RD & (~1))<31:0> | (readIntReg(RD | 1)<31:0> << 32);
+ }});//STD
+ 0x08: ldsw({{Rd.sw = Mem.sw;}}); //LDSW
+ 0x09: ldsb({{Rd.sb = Mem.sb;}}); //LDSB
+ 0x0A: ldsh({{Rd.shw = Mem.shw;}}); //LDSH
+ 0x0B: ldx({{Rd.udw = Mem.udw;}}); //LDX
+
+ 0x0D: ldstub({{
+ Rd.ub = Mem.ub;
+ Mem.ub = 0xFF;
+ }}); //LDSTUB
+ 0x0E: stx({{Rd.udw = Mem.udw;}}); //STX
+ 0x0F: swap({{
+ UINT32 temp = Rd.uw;
+ Rd.uw = Mem.uw;
+ Mem.uw = temp;
+ }}); //SWAP
+ 0x10: lduwa({{Rd.uw = Mem.uw;}}); //LDUWA
+ 0x11: lduba({{Rd.ub = Mem.ub;}}); //LDUBA
+ 0x12: lduha({{Rd.uhw = Mem.uhw;}}); //LDUHA
+ 0x13: ldda({{
+ UINT64 val = Mem.udw;
+ setIntReg(RD & (~1), val<31:0>);
+ setIntReg(RD | 1, val<63:32>);
+ }}); //LDDA
+ 0x14: stwa({{Mem.uw = Rd.uw;}}); //STWA
+ 0x15: stba({{Mem.ub = Rd.ub;}}); //STBA
+ 0x16: stha({{Mem.uhw = Rd.uhw;}}); //STHA
+ 0x17: stda({{
+ Mem.udw = readIntReg(RD & (~1))<31:0> | (readIntReg(RD | 1)<31:0> << 32);
+ }}); //STDA
+ 0x18: ldswa({{Rd.sw = Mem.sw;}}); //LDSWA
+ 0x19: ldsba({{Rd.sb = Mem.sb;}}); //LDSBA
+ 0x1A: ldsha({{Rd.shw = Mem.shw;}}); //LDSHA
+ 0x1B: ldxa({{Rd.sdw = Mem.sdw;}}); //LDXA
+
+ 0x1D: ldstuba({{
+ Rd.ub = Mem.ub;
+ Mem.ub = 0xFF;
+ }}); //LDSTUBA
+ 0x1E: stxa({{Mem.sdw = Rd.sdw}}); //STXA
+ 0x1F: swapa({{
+ UINT32 temp = Rd.uw;
+ Rd.uw = Mem.uw;
+ Mem.uw = temp;
+ }}); //SWAPA
+ 0x20: Trap::ldf({{throw fp_disabled;}}); //LDF
+ 0x21: decode X {
+ 0x0: Trap::ldfsr({{throw fp_disabled;}}); //LDFSR
+ 0x1: Trap::ldxfsr({{throw fp_disabled;}}); //LDXFSR
+ }
+ 0x22: Trap::ldqf({{throw fp_disabled;}}); //LDQF
+ 0x23: Trap::lddf({{throw fp_disabled;}}); //LDDF
+ 0x24: Trap::stf({{throw fp_disabled;}}); //STF
+ 0x25: decode X {
+ 0x0: Trap::stfsr({{throw fp_disabled;}}); //STFSR
+ 0x1: Trap::stxfsr({{throw fp_disabled;}}); //STXFSR
+ }
+ 0x26: Trap::stqf({{throw fp_disabled;}}); //STQF
+ 0x27: Trap::stdf({{throw fp_disabled;}}); //STDF
+
+
+
+
+
+ 0x2D: Noop::prefetch({{ }}); //PREFETCH
+
+
+ 0x30: Trap::ldfa({{throw fp_disabled;}}); //LDFA
+
+ 0x32: Trap::ldqfa({{throw fp_disabled;}}); //LDQFA
+ 0x33: Trap::lddfa({{throw fp_disabled;}}); //LDDFA
+ 0x34: Trap::stfa({{throw fp_disabled;}}); //STFA
+ 0x35: Trap::stqfa({{throw fp_disabled;}}); //STQFA
+ 0x36: Trap::stdfa({{throw fp_disabled;}}); //STDFA
+
+
+
+
+
+ 0x3C: Cas::casa(
+ {{UINT64 val = Mem.uw;
+ if(Rs2.uw == val)
+ Mem.uw = Rd.uw;
+ Rd.uw = val;
+ }}); //CASA
+ 0x3D: Noop::prefetcha({{ }}); //PREFETCHA
+ 0x3E: Cas::casxa(
+ {{UINT64 val = Mem.udw;
+ if(Rs2 == val)
+ Mem.udw = Rd;
+ Rd = val;
+ }}); //CASXA
+ }
+ }
+}
--- /dev/null
+//Include the basic format
+//Templates from this format are used later
+##include "m5/arch/sparc/isa_desc/formats/basic.format"
+
+//Include the integerOp and integerOpCc format
+##include "m5/arch/sparc/isa_desc/formats/integerop.format"
+
+//Include the mem format
+##include "m5/arch/sparc/isa_desc/formats/mem.format"
+
+//Include the trap format
+##include "m5/arch/sparc/isa_desc/formats/trap.format"
+
+//Include the branch format
+##include "m5/arch/sparc/isa_desc/formats/branch.format"
+
+//Include the noop format
+##include "m5/arch/sparc/isa_desc/formats/noop.format"
+
--- /dev/null
+
+// Declarations for execute() methods.
+def template BasicExecDeclare {{
+ Fault execute(%(CPU_exec_context)s *, Trace::InstRecord *) const;
+}};
+
+// Basic instruction class declaration template.
+def template BasicDeclare {{
+ /**
+ * Static instruction class for "%(mnemonic)s".
+ */
+ class %(class_name)s : public %(base_class)s
+ {
+ public:
+ /// Constructor.
+ %(class_name)s(MachInst machInst);
+ %(BasicExecDeclare)s
+ };
+}};
+
+// Basic instruction class constructor template.
+def template BasicConstructor {{
+ inline %(class_name)s::%(class_name)s(MachInst machInst) : %(base_class)s("%(mnemonic)s", machInst, %(op_class)s)
+ {
+ %(constructor)s;
+ }
+}};
+
+// Basic instruction class execute method template.
+def template BasicExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ Fault fault = No_Fault;
+
+ %(fp_enable_check)s;
+ %(op_decl)s;
+ %(op_rd)s;
+ %(code)s;
+
+ if(fault == No_Fault)
+ {
+ %(op_wb)s;
+ }
+ return fault;
+ }
+}};
+
+// Basic decode template.
+def template BasicDecode {{
+ return new %(class_name)s(machInst);
+}};
+
+// Basic decode template, passing mnemonic in as string arg to constructor.
+def template BasicDecodeWithMnemonic {{
+ return new %(class_name)s("%(mnemonic)s", machInst);
+}};
+
+// The most basic instruction format... used only for a few misc. insts
+def format BasicOperate(code, *flags) {{
+ iop = InstObjParams(name, Name, 'SparcStaticInst', CodeBlock(code), flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecode.subst(iop)
+ exec_output = BasicExecute.subst(iop)
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Branch instructions
+//
+
+output header {{
+ /**
+ * Base class for integer operations.
+ */
+ class Branch : public SparcStaticInst
+ {
+ protected:
+
+ /// Constructor
+ Branch(const char *mnem, MachInst _machInst, OpClass __opClass) : SparcStaticInst(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+}};
+
+output decoder {{
+ std::string Branch::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ return "Disassembly of integer instruction\n";
+ }
+}};
+
+def template BranchExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ //Attempt to execute the instruction
+ try
+ {
+ checkPriv;
+
+ %(op_decl)s;
+ %(op_rd)s;
+ %(code)s;
+ }
+ //If we have an exception for some reason,
+ //deal with it
+ catch(SparcException except)
+ {
+ //Deal with exception
+ return No_Fault;
+ }
+
+ //Write the resulting state to the execution context
+ %(op_wb)s;
+
+ return No_Fault;
+ }
+}};
+
+// Primary format for integer operate instructions:
+def format Branch(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = BranchExecute.subst(iop)
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Integer operate instructions
+//
+
+output header {{
+ /**
+ * Base class for integer operations.
+ */
+ class IntegerOp : public SparcStaticInst
+ {
+ protected:
+
+ /// Constructor
+ IntegerOp(const char *mnem, MachInst _machInst, OpClass __opClass) : SparcStaticInst(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+}};
+
+output decoder {{
+ std::string IntegerOp::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ return "Disassembly of integer instruction\n";
+ }
+}};
+
+def template IntegerExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ //These are set to constants when the execute method
+ //is generated
+ bool useCc = ;
+ bool checkPriv = ;
+
+ //Attempt to execute the instruction
+ try
+ {
+ checkPriv;
+
+ %(op_decl)s;
+ %(op_rd)s;
+ %(code)s;
+ }
+ //If we have an exception for some reason,
+ //deal with it
+ catch(SparcException except)
+ {
+ //Deal with exception
+ return No_Fault;
+ }
+
+ //Write the resulting state to the execution context
+ %(op_wb)s;
+ if(useCc)
+ {
+ xc->regs.miscRegFile.ccrFields.iccFields.n = Rd & (1 << 63);
+ xc->regs.miscRegFile.ccrFields.iccFields.z = (Rd == 0);
+ xc->regs.miscRegFile.ccrFields.iccFields.v = ivValue;
+ xc->regs.miscRegFile.ccrFields.iccFields.c = icValue;
+ xc->regs.miscRegFile.ccrFields.xccFields.n = Rd & (1 << 31);
+ xc->regs.miscRegFile.ccrFields.xccFields.z = ((Rd & 0xFFFFFFFF) == 0);
+ xc->regs.miscRegFile.ccrFields.xccFields.v = xvValue;
+ xc->regs.miscRegFile.ccrFields.xccFields.c = xcValue;
+ }
+ return No_Fault;
+ }
+}};
+
+// Primary format for integer operate instructions:
+def format IntegerOp(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ checkPriv = (code.find('checkPriv') != -1)
+ code.replace('checkPriv', '')
+ if checkPriv:
+ code.replace('checkPriv;', 'if(!xc->regs.miscRegFile.pstateFields.priv) throw privileged_opcode;')
+ else:
+ code.replace('checkPriv;', '')
+ for (marker, value) in (('ivValue', '0'), ('icValue', '0'),
+ ('xvValue', '0'), ('xcValue', '0')):
+ code.replace(marker, value)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = IntegerExecute.subst(iop)
+}};
+
+// Primary format for integer operate instructions:
+def format IntegerOpCc(code, icValue, ivValue, xcValue, xvValue, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ checkPriv = (code.find('checkPriv') != -1)
+ code.replace('checkPriv', '')
+ if checkPriv:
+ code.replace('checkPriv;', 'if(!xc->regs.miscRegFile.pstateFields.priv) throw privileged_opcode;')
+ else:
+ code.replace('checkPriv;', '')
+ for (marker, value) in (('ivValue', ivValue), ('icValue', icValue),
+ ('xvValue', xvValue), ('xcValue', xcValue)):
+ code.replace(marker, value)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = IntegerExecute.subst(iop)
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Mem instructions
+//
+
+output header {{
+ /**
+ * Base class for integer operations.
+ */
+ class Mem : public SparcStaticInst
+ {
+ protected:
+
+ /// Constructor
+ Mem(const char *mnem, MachInst _machInst, OpClass __opClass) : SparcStaticInst(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+}};
+
+output decoder {{
+ std::string Mem::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ return "Disassembly of integer instruction\n";
+ }
+}};
+
+def template MemExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ //Attempt to execute the instruction
+ try
+ {
+
+ %(op_decl)s;
+ %(op_rd)s;
+ ea_code
+ %(code)s;
+ }
+ //If we have an exception for some reason,
+ //deal with it
+ catch(SparcException except)
+ {
+ //Deal with exception
+ return No_Fault;
+ }
+
+ //Write the resulting state to the execution context
+ %(op_wb)s;
+
+ return No_Fault;
+ }
+}};
+
+// Primary format for integer operate instructions:
+def format Mem(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = MemExecute.subst(iop)
+ exec_output.replace('ea_code', 'EA = I ? (R1 + SIMM13) : R1 + R2;');
+}};
+
+def format Cas(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = MemExecute.subst(iop)
+ exec_output.replace('ea_code', 'EA = R1;');
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Noop instruction
+//
+
+output header {{
+ /**
+ * Base class for integer operations.
+ */
+ class Noop : public SparcStaticInst
+ {
+ protected:
+
+ /// Constructor
+ Noop(const char *mnem, MachInst _machInst, OpClass __opClass) : SparcStaticInst(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+}};
+
+output decoder {{
+ std::string Noop::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ return "Disassembly of integer instruction\n";
+ }
+}};
+
+def template NoopExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ //Nothing to see here, move along
+ return No_Fault;
+ }
+}};
+
+// Primary format for integer operate instructions:
+def format Noop(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = NoopExecute.subst(iop)
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Trap instructions
+//
+
+output header {{
+ /**
+ * Base class for integer operations.
+ */
+ class Trap : public SparcStaticInst
+ {
+ protected:
+
+ /// Constructor
+ Trap(const char *mnem, MachInst _machInst, OpClass __opClass) : SparcStaticInst(mnem, _machInst, __opClass)
+ {
+ }
+
+ std::string generateDisassembly(Addr pc, const SymbolTable *symtab) const;
+ };
+}};
+
+output decoder {{
+ std::string Trap::generateDisassembly(Addr pc, const SymbolTable *symtab) const
+ {
+ return "Disassembly of integer instruction\n";
+ }
+}};
+
+def template TrapExecute {{
+ Fault %(class_name)s::execute(%(CPU_exec_context)s *xc, Trace::InstRecord *traceData) const
+ {
+ //Call into the trap handler with the appropriate fault
+ return No_Fault;
+ }
+
+ //Write the resulting state to the execution context
+ %(op_wb)s;
+
+ return No_Fault;
+ }
+}};
+
+// Primary format for integer operate instructions:
+def format Trap(code, *opt_flags) {{
+ orig_code = code
+ cblk = CodeBlock(code)
+ iop = InstObjParams(name, Name, 'SparcStaticInst', cblk, opt_flags)
+ header_output = BasicDeclare.subst(iop)
+ decoder_output = BasicConstructor.subst(iop)
+ decode_block = BasicDecodeWithMnemonic.subst(iop)
+ exec_output = TrapExecute.subst(iop)
+}};
--- /dev/null
+////////////////////////////////////////////////////////////////////
+//
+// Output include file directives.
+//
+
+output header {{
+#include <sstream>
+#include <iostream>
+#include <iomanip>
+
+#include "cpu/static_inst.hh"
+#include "traps.hh"
+#include "mem/mem_req.hh" // some constructors use MemReq flags
+}};
+
+output decoder {{
+#include "base/cprintf.hh"
+#include "base/loader/symtab.hh"
+#include "cpu/exec_context.hh" // for Jump::branchTarget()
+
+#include <math.h>
+#if defined(linux)
+#include <fenv.h>
+#endif
+}};
+
+output exec {{
+#include <math.h>
+#if defined(linux)
+#include <fenv.h>
+#endif
+
+#ifdef FULL_SYSTEM
+//#include "arch/alpha/pseudo_inst.hh"
+#endif
+#include "cpu/base.hh"
+#include "cpu/exetrace.hh"
+#include "sim/sim_exit.hh"
+}};
+
--- /dev/null
+// -*- mode:c++ -*-
+
+//Copyright (c) 2003, 2004, 2005
+//The Regents of The University of Michigan
+//All Rights Reserved
+
+//This code is part of the M5 simulator, developed by Nathan Binkert,
+//Erik Hallnor, Steve Raasch, and Steve Reinhardt, with contributions
+//from Ron Dreslinski, Dave Greene, Lisa Hsu, Kevin Lim, Ali Saidi,
+//and Andrew Schultz.
+
+//Permission is granted to use, copy, create derivative works and
+//redistribute this software and such derivative works for any purpose,
+//so long as the copyright notice above, this grant of permission, and
+//the disclaimer below appear in all copies made; and so long as the
+//name of The University of Michigan is not used in any advertising or
+//publicity pertaining to the use or distribution of this software
+//without specific, written prior authorization.
+
+//THIS SOFTWARE IS PROVIDED AS IS, WITHOUT REPRESENTATION FROM THE
+//UNIVERSITY OF MICHIGAN AS TO ITS FITNESS FOR ANY PURPOSE, AND WITHOUT
+//WARRANTY BY THE UNIVERSITY OF MICHIGAN OF ANY KIND, EITHER EXPRESS OR
+//IMPLIED, INCLUDING WITHOUT LIMITATION THE IMPLIED WARRANTIES OF
+//MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. THE REGENTS OF
+//THE UNIVERSITY OF MICHIGAN SHALL NOT BE LIABLE FOR ANY DAMAGES,
+//INCLUDING DIRECT, SPECIAL, INDIRECT, INCIDENTAL, OR CONSEQUENTIAL
+//DAMAGES, WITH RESPECT TO ANY CLAIM ARISING OUT OF OR IN CONNECTION
+//WITH THE USE OF THE SOFTWARE, EVEN IF IT HAS BEEN OR IS HEREAFTER
+//ADVISED OF THE POSSIBILITY OF SUCH DAMAGES.
+
+////////////////////////////////////////////////////////////////////
+//
+// SPARC ISA description file.
+//
+////////////////////////////////////////////////////////////////////
+
+//Include the C++ include directives
+##include "m5/arch/sparc/isa_desc/includes.h"
+
+////////////////////////////////////////////////////////////////////
+//
+// Namespace statement. Everything below this line will be in the
+// SparcISAInst namespace.
+//
+
+namespace SparcISA;
+
+//Include the bitfield definitions
+##include "m5/arch/sparc/isa_desc/bitfields.h"
+
+//Include the operand_types and operand definitions
+##include "m5/arch/sparc/isa_desc/operands.h"
+
+//Include the base class for sparc instructions, and some support code
+##include "m5/arch/sparc/isa_desc/base.h"
+
+//Include the definitions for the instruction formats
+##include "m5/arch/sparc/isa_desc/formats.h"
+
+//Include the decoder definition
+##include "m5/arch/sparc/isa_desc/decoder.h"
--- /dev/null
+def operand_types {{
+ 'sb' : ('signed int', 8),
+ 'ub' : ('unsigned int', 8),
+ 'shw' : ('signed int', 16),
+ 'uhw' : ('unsigned int', 16),
+ 'sw' : ('signed int', 32),
+ 'uw' : ('unsigned int', 32),
+ 'sdw' : ('signed int', 64),
+ 'udw' : ('unsigned int', 64),
+ 'sf' : ('float', 32),
+ 'df' : ('float', 64),
+ 'qf' : ('float', 128)
+}};
+
+def operands {{
+ # Int regs default to unsigned, but code should not count on this.
+ # For clarity, descriptions that depend on unsigned behavior should
+ # explicitly specify '.uq'.
+ 'Rd': IntRegOperandTraits('udw', 'RD', 'IsInteger', 1),
+ 'Rs1': IntRegOperandTraits('udw', 'RS1', 'IsInteger', 2),
+ 'Rs2': IntRegOperandTraits('udw', 'RS2', 'IsInteger', 3),
+ #'Fa': FloatRegOperandTraits('df', 'FA', 'IsFloating', 1),
+ #'Fb': FloatRegOperandTraits('df', 'FB', 'IsFloating', 2),
+ #'Fc': FloatRegOperandTraits('df', 'FC', 'IsFloating', 3),
+ 'Mem': MemOperandTraits('udw', None,
+ ('IsMemRef', 'IsLoad', 'IsStore'), 4)
+ #'NPC': NPCOperandTraits('uq', None, ( None, None, 'IsControl' ), 4),
+ #'Runiq': ControlRegOperandTraits('uq', 'Uniq', None, 1),
+ #'FPCR': ControlRegOperandTraits('uq', 'Fpcr', None, 1),
+ # The next two are hacks for non-full-system call-pal emulation
+ #'R0': IntRegOperandTraits('uq', '0', None, 1),
+ #'R16': IntRegOperandTraits('uq', '16', None, 1)
+}};
--- /dev/null
+/*
+ * Copyright (c) 2003-2005 The Regents of The University of Michigan
+ * All rights reserved.
+ *
+ * Redistribution and use in source and binary forms, with or without
+ * modification, are permitted provided that the following conditions are
+ * met: redistributions of source code must retain the above copyright
+ * notice, this list of conditions and the following disclaimer;
+ * redistributions in binary form must reproduce the above copyright
+ * notice, this list of conditions and the following disclaimer in the
+ * documentation and/or other materials provided with the distribution;
+ * neither the name of the copyright holders nor the names of its
+ * contributors may be used to endorse or promote products derived from
+ * this software without specific prior written permission.
+ *
+ * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
+ * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
+ * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
+ * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
+ * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
+ * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
+ * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
+ * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
+ * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
+ * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
+ * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
+ */
+
+#ifndef __ARCH_SPARC_ISA_TRAITS_HH__
+#define __ARCH_SPARC_ISA_TRAITS_HH__
+
+#include "arch/sparc/faults.hh"
+#include "base/misc.hh"
+#include "sim/host.hh"
+
+class FastCPU;
+//class FullCPU;
+//class Checkpoint;
+
+#define TARGET_SPARC
+
+template <class ISA> class StaticInst;
+template <class ISA> class StaticInstPtr;
+
+//namespace EV5
+//{
+// int DTB_ASN_ASN(uint64_t reg);
+// int ITB_ASN_ASN(uint64_t reg);
+//}
+
+class SPARCISA
+{
+ public:
+
+ typedef uint32_t MachInst;
+ typedef uint64_t Addr;
+ typedef uint8_t RegIndex;
+
+ enum
+ {
+ MemoryEnd = 0xffffffffffffffffULL,
+
+ NumFloatRegs = 32,
+ NumMiscRegs = 32,
+
+ MaxRegsOfAnyType = 32,
+ // Static instruction parameters
+ MaxInstSrcRegs = 3,
+ MaxInstDestRegs = 2,
+
+ // Maximum trap level
+ MaxTL = 4
+
+ // semantically meaningful register indices
+ ZeroReg = 0, // architecturally meaningful
+ // the rest of these depend on the ABI
+ }
+ typedef uint64_t IntReg;
+
+ class IntRegFile
+ {
+ private:
+ //For right now, let's pretend the register file is static
+ IntReg regs[32];
+ public:
+ IntReg & operator [] (RegIndex index)
+ {
+ //Don't allow indexes outside of the 32 registers
+ index &= 0x1F
+ return regs[index];
+ }
+ };
+
+ void inline serialize(std::ostream & os)
+ {
+ SERIALIZE_ARRAY(regs, 32);
+ }
+
+ void inline unserialize(Checkpoint &*cp, const std::string §ion)
+ {
+ UNSERIALIZE_ARRAY(regs, 32);
+ }
+
+ class FloatRegFile
+ {
+ private:
+ //By using the largest data type, we ensure everything
+ //is aligned correctly in memory
+ union
+ {
+ double double rawRegs[16];
+ uint64_t regDump[32];
+ };
+ class QuadRegs
+ {
+ private:
+ FloatRegFile * parent;
+ public:
+ QuadRegs(FloatRegFile * p) : parent(p) {;}
+ double double & operator [] (RegIndex index)
+ {
+ //Quad floats are index by the single
+ //precision register the start on,
+ //and only 16 should be accessed
+ index = (index >> 2) & 0xF;
+ return parent->rawRegs[index];
+ }
+ };
+ class DoubleRegs
+ {
+ private:
+ FloatRegFile * parent;
+ public:
+ DoubleRegs(FloatRegFile * p) : parent(p) {;}
+ double & operator [] (RegIndex index)
+ {
+ //Double floats are index by the single
+ //precision register the start on,
+ //and only 32 should be accessed
+ index = (index >> 1) & 0x1F
+ return ((double [])parent->rawRegs)[index];
+ }
+ }
+ class SingleRegs
+ {
+ private:
+ FloatRegFile * parent;
+ public:
+ SingleRegs(FloatRegFile * p) : parent(p) {;}
+ double & operator [] (RegFile index)
+ {
+ //Only 32 single floats should be accessed
+ index &= 0x1F
+ return ((float [])parent->rawRegs)[index];
+ }
+ }
+ public:
+ void inline serialize(std::ostream & os)
+ {
+ SERIALIZE_ARRAY(regDump, 32);
+ }
+
+ void inline unserialize(Checkpoint &* cp, std::string & section)
+ {
+ UNSERIALIZE_ARRAY(regDump, 32);
+ }
+
+ QuadRegs quadRegs;
+ DoubleRegs doubleRegs;
+ SingleRegs singleRegs;
+ FloatRegFile() : quadRegs(this), doubleRegs(this), singleRegs(this)
+ {;}
+ };
+
+ // control register file contents
+ typedef uint64_t MiscReg;
+ // The control registers, broken out into fields
+ class MiscRegFile
+ {
+ public:
+ union
+ {
+ uint16_t pstate; // Process State Register
+ struct
+ {
+ uint16_t ag:1; // Alternate Globals
+ uint16_t ie:1; // Interrupt enable
+ uint16_t priv:1; // Privelege mode
+ uint16_t am:1; // Address mask
+ uint16_t pef:1; // PSTATE enable floating-point
+ uint16_t red:1; // RED (reset, error, debug) state
+ uint16_t mm:2; // Memory Model
+ uint16_t tle:1; // Trap little-endian
+ uint16_t cle:1; // Current little-endian
+ } pstateFields;
+ }
+ uint64_t tba; // Trap Base Address
+ union
+ {
+ uint64_t y; // Y (used in obsolete multiplication)
+ struct
+ {
+ uint64_t value:32; // The actual value stored in y
+ const uint64_t :32; // reserved bits
+ } yFields;
+ }
+ uint8_t pil; // Process Interrupt Register
+ uint8_t cwp; // Current Window Pointer
+ uint16_t tt[MaxTL]; // Trap Type (Type of trap which occured on the previous level)
+ union
+ {
+ uint8_t ccr; // Condition Code Register
+ struct
+ {
+ union
+ {
+ uint8_t icc:4; // 32-bit condition codes
+ struct
+ {
+ uint8_t c:1; // Carry
+ uint8_t v:1; // Overflow
+ uint8_t z:1; // Zero
+ uint8_t n:1; // Negative
+ } iccFields:4;
+ } :4;
+ union
+ {
+ uint8_t xcc:4; // 64-bit condition codes
+ struct
+ {
+ uint8_t c:1; // Carry
+ uint8_t v:1; // Overflow
+ uint8_t z:1; // Zero
+ uint8_t n:1; // Negative
+ } xccFields:4;
+ } :4;
+ } ccrFields;
+ }
+ uint8_t asi; // Address Space Identifier
+ uint8_t tl; // Trap Level
+ uint64_t tpc[MaxTL]; // Trap Program Counter (value from previous trap level)
+ uint64_t tnpc[MaxTL]; // Trap Next Program Counter (value from previous trap level)
+ union
+ {
+ uint64_t tstate[MaxTL]; // Trap State
+ struct
+ {
+ //Values are from previous trap level
+ uint64_t cwp:5; // Current Window Pointer
+ const uint64_t :2; // Reserved bits
+ uint64_t pstate:10; // Process State
+ const uint64_t :6; // Reserved bits
+ uint64_t asi:8; // Address Space Identifier
+ uint64_t ccr:8; // Condition Code Register
+ } tstateFields[MaxTL];
+ }
+ union
+ {
+ uint64_t tick; // Hardware clock-tick counter
+ struct
+ {
+ uint64_t counter:63; // Clock-tick count
+ uint64_t npt:1; // Non-priveleged trap
+ } tickFields;
+ }
+ uint8_t cansave; // Savable windows
+ uint8_t canrestore; // Restorable windows
+ uint8_t otherwin; // Other windows
+ uint8_t cleanwin; // Clean windows
+ union
+ {
+ uint8_t wstate; // Window State
+ struct
+ {
+ uint8_t normal:3; // Bits TT<4:2> are set to on a normal
+ // register window trap
+ uint8_t other:3; // Bits TT<4:2> are set to on an "otherwin"
+ // register window trap
+ } wstateFields;
+ }
+ union
+ {
+ uint64_t ver; // Version
+ struct
+ {
+ uint64_t maxwin:5; // Max CWP value
+ const uint64_t :2; // Reserved bits
+ uint64_t maxtl:8; // Maximum trap level
+ const uint64_t :8; // Reserved bits
+ uint64_t mask:8; // Processor mask set revision number
+ uint64_t impl:16; // Implementation identification number
+ uint64_t manuf:16; // Manufacturer code
+ } verFields;
+ }
+ union
+ {
+ uint64_t fsr; // Floating-Point State Register
+ struct
+ {
+ union
+ {
+ uint64_t cexc:5; // Current excpetion
+ struct
+ {
+ uint64_t nxc:1; // Inexact
+ uint64_t dzc:1; // Divide by zero
+ uint64_t ufc:1; // Underflow
+ uint64_t ofc:1; // Overflow
+ uint64_t nvc:1; // Invalid operand
+ } cexecFields:5;
+ } :5;
+ union
+ {
+ uint64_t aexc:5; // Accrued exception
+ struct
+ {
+ uint64_t nxc:1; // Inexact
+ uint64_t dzc:1; // Divide by zero
+ uint64_t ufc:1; // Underflow
+ uint64_t ofc:1; // Overflow
+ uint64_t nvc:1; // Invalid operand
+ } aexecFields:5;
+ } :5;
+ uint64_t fcc0:2; // Floating-Point condtion codes
+ const uint64_t :1; // Reserved bits
+ uint64_t qne:1; // Deferred trap queue not empty
+ // with no queue, it should read 0
+ uint64_t ftt:3; // Floating-Point trap type
+ uint64_t ver:3; // Version (of the FPU)
+ const uint64_t :2; // Reserved bits
+ uint64_t ns:1; // Nonstandard floating point
+ union
+ {
+ uint64_t tem:5; // Trap Enable Mask
+ struct
+ {
+ uint64_t nxm:1; // Inexact
+ uint64_t dzm:1; // Divide by zero
+ uint64_t ufm:1; // Underflow
+ uint64_t ofm:1; // Overflow
+ uint64_t nvm:1; // Invalid operand
+ } temFields:5;
+ } :5;
+ const uint64_t :2; // Reserved bits
+ uint64_t rd:2; // Rounding direction
+ uint64_t fcc1:2; // Floating-Point condition codes
+ uint64_t fcc2:2; // Floating-Point condition codes
+ uint64_t fcc3:2; // Floating-Point condition codes
+ const uint64_t :26; // Reserved bits
+ } fsrFields;
+ }
+ union
+ {
+ uint8_t fprs; // Floating-Point Register State
+ struct
+ {
+ dl:1; // Dirty lower
+ du:1; // Dirty upper
+ fef:1; // FPRS enable floating-Point
+ } fprsFields;
+ };
+
+ void serialize(std::ostream & os)
+ {
+ SERIALIZE_SCALAR(pstate);
+ SERIAlIZE_SCALAR(tba);
+ SERIALIZE_SCALAR(y);
+ SERIALIZE_SCALAR(pil);
+ SERIALIZE_SCALAR(cwp);
+ SERIALIZE_ARRAY(tt, MaxTL);
+ SERIALIZE_SCALAR(ccr);
+ SERIALIZE_SCALAR(asi);
+ SERIALIZE_SCALAR(tl);
+ SERIALIZE_SCALAR(tpc);
+ SERIALIZE_SCALAR(tnpc);
+ SERIALIZE_ARRAY(tstate, MaxTL);
+ SERIALIZE_SCALAR(tick);
+ SERIALIZE_SCALAR(cansave);
+ SERIALIZE_SCALAR(canrestore);
+ SERIALIZE_SCALAR(otherwin);
+ SERIALIZE_SCALAR(cleanwin);
+ SERIALIZE_SCALAR(wstate);
+ SERIALIZE_SCALAR(ver);
+ SERIALIZE_SCALAR(fsr);
+ SERIALIZE_SCALAR(fprs);
+ }
+
+ void unserialize(Checkpoint &* cp, std::string & section)
+ {
+ UNSERIALIZE_SCALAR(pstate);
+ UNSERIAlIZE_SCALAR(tba);
+ UNSERIALIZE_SCALAR(y);
+ UNSERIALIZE_SCALAR(pil);
+ UNSERIALIZE_SCALAR(cwp);
+ UNSERIALIZE_ARRAY(tt, MaxTL);
+ UNSERIALIZE_SCALAR(ccr);
+ UNSERIALIZE_SCALAR(asi);
+ UNSERIALIZE_SCALAR(tl);
+ UNSERIALIZE_SCALAR(tpc);
+ UNSERIALIZE_SCALAR(tnpc);
+ UNSERIALIZE_ARRAY(tstate, MaxTL);
+ UNSERIALIZE_SCALAR(tick);
+ UNSERIALIZE_SCALAR(cansave);
+ UNSERIALIZE_SCALAR(canrestore);
+ UNSERIALIZE_SCALAR(otherwin);
+ UNSERIALIZE_SCALAR(cleanwin);
+ UNSERIALIZE_SCALAR(wstate);
+ UNSERIALIZE_SCALAR(ver);
+ UNSERIALIZE_SCALAR(fsr);
+ UNSERIALIZE_SCALAR(fprs);
+ }
+ };
+
+ typedef union
+ {
+ IntReg intreg;
+ FloatReg fpreg;
+ MiscReg ctrlreg;
+ } AnyReg;
+
+ struct RegFile
+ {
+ IntRegFile intRegFile; // (signed) integer register file
+ FloatRegFile floatRegFile; // floating point register file
+ MiscRegFile miscRegFile; // control register file
+
+ Addr pc; // Program Counter
+ Addr npc; // Next Program Counter
+
+ void serialize(std::ostream &os);
+ void unserialize(Checkpoint *cp, const std::string §ion);
+ };
+
+ static StaticInstPtr<AlphaISA> decodeInst(MachInst);
+
+ // return a no-op instruction... used for instruction fetch faults
+ static const MachInst NoopMachInst;
+
+ // Instruction address compression hooks
+ static inline Addr realPCToFetchPC(const Addr &addr)
+ {
+ return addr;
+ }
+
+ static inline Addr fetchPCToRealPC(const Addr &addr)
+ {
+ return addr;
+ }
+
+ // the size of "fetched" instructions (not necessarily the size
+ // of real instructions for PISA)
+ static inline size_t fetchInstSize()
+ {
+ return sizeof(MachInst);
+ }
+
+ /**
+ * Function to insure ISA semantics about 0 registers.
+ * @param xc The execution context.
+ */
+ template <class XC>
+ static void zeroRegisters(XC *xc);
+};
+
+
+typedef SPARCISA TheISA;
+
+typedef TheISA::MachInst MachInst;
+typedef TheISA::Addr Addr;
+typedef TheISA::RegIndex RegIndex;
+typedef TheISA::IntReg IntReg;
+typedef TheISA::IntRegFile IntRegFile;
+typedef TheISA::FloatReg FloatReg;
+typedef TheISA::FloatRegFile FloatRegFile;
+typedef TheISA::MiscReg MiscReg;
+typedef TheISA::MiscRegFile MiscRegFile;
+typedef TheISA::AnyReg AnyReg;
+typedef TheISA::RegFile RegFile;
+
+const int VMPageSize = TheISA::VMPageSize;
+const int LogVMPageSize = TheISA::LogVMPageSize;
+const int ZeroReg = TheISA::ZeroReg;
+const int BranchPredAddrShiftAmt = TheISA::BranchPredAddrShiftAmt;
+const int MaxAddr = (Addr)-1;
+
+#ifndef FULL_SYSTEM
+class SyscallReturn {
+ public:
+ template <class T>
+ SyscallReturn(T v, bool s)
+ {
+ retval = (uint64_t)v;
+ success = s;
+ }
+
+ template <class T>
+ SyscallReturn(T v)
+ {
+ success = (v >= 0);
+ retval = (uint64_t)v;
+ }
+
+ ~SyscallReturn() {}
+
+ SyscallReturn& operator=(const SyscallReturn& s) {
+ retval = s.retval;
+ success = s.success;
+ return *this;
+ }
+
+ bool successful() { return success; }
+ uint64_t value() { return retval; }
+
+
+ private:
+ uint64_t retval;
+ bool success;
+};
+
+#endif
+
+
+#ifdef FULL_SYSTEM
+
+#include "arch/alpha/ev5.hh"
+#endif
+
+#endif // __ARCH_SPARC_ISA_TRAITS_HH__