DBT-RISE/DBT-RISE-TGC
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reorganized layout to only contain risc-v stuff

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This commit is contained in:
Eyck Jentzsch
2019-06-11 16:49:37 +00:00
parent eb8365f4c3
commit 67d9beb7bd
133 changed files with 1460 additions and 9277 deletions
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1
gen_input/.gitignore vendored Normal file
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/src-gen/

50
gen_input/RISCVBase.core_desc Normal file
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InsructionSet RISCVBase {
constants {
XLEN,
fence:=0,
fencei:=1,
fencevmal:=2,
fencevmau:=3
}
address_spaces {
MEM[8], CSR[XLEN], FENCE[XLEN], RES[8]
}
registers {
[31:0] X[XLEN],
PC[XLEN](is_pc),
alias ZERO[XLEN] is X[0],
alias RA[XLEN] is X[1],
alias SP[XLEN] is X[2],
alias GP[XLEN] is X[3],
alias TP[XLEN] is X[4],
alias T0[XLEN] is X[5],
alias T1[XLEN] is X[6],
alias T2[XLEN] is X[7],
alias S0[XLEN] is X[8],
alias S1[XLEN] is X[9],
alias A0[XLEN] is X[10],
alias A1[XLEN] is X[11],
alias A2[XLEN] is X[12],
alias A3[XLEN] is X[13],
alias A4[XLEN] is X[14],
alias A5[XLEN] is X[15],
alias A6[XLEN] is X[16],
alias A7[XLEN] is X[17],
alias S2[XLEN] is X[18],
alias S3[XLEN] is X[19],
alias S4[XLEN] is X[20],
alias S5[XLEN] is X[21],
alias S6[XLEN] is X[22],
alias S7[XLEN] is X[23],
alias S8[XLEN] is X[24],
alias S9[XLEN] is X[25],
alias S10[XLEN] is X[26],
alias S11[XLEN] is X[27],
alias T3[XLEN] is X[28],
alias T4[XLEN] is X[29],
alias T5[XLEN] is X[30],
alias T6[XLEN] is X[31]
}
}

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import "RISCVBase.core_desc"
InsructionSet RV32I extends RISCVBase{
instructions {
LUI{
encoding: imm[31:12]s | rd[4:0] | b0110111;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd!=0) X[rd] <= imm;
}
AUIPC{
encoding: imm[31:12]s | rd[4:0] | b0010111;
args_disass: "{name(rd)}, {imm:#08x}";
if(rd!=0) X[rd] <= PC's+imm;
}
JAL(no_cont){
encoding: imm[20:20]s | imm[10:1]s | imm[11:11]s | imm[19:12]s | rd[4:0] | b1101111;
args_disass: "{name(rd)}, {imm:#0x}";
if(rd!=0) X[rd] <= PC+4;
PC<=PC's+imm;
}
JALR(no_cont){
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b1100111;
args_disass: "{name(rd)}, {name(rs1)}, {imm:#0x}";
val new_pc[XLEN] <= X[rs1]'s+ imm;
val align[XLEN] <= new_pc & 0x2;
if(align != 0){
raise(0, 0);
} else {
if(rd!=0) X[rd] <= PC+4;
PC<=new_pc & ~0x1;
}
}
BEQ(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b000 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]==X[rs2], PC's+imm, PC+4);
}
BNE(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b001 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]!=X[rs2], PC's+imm, PC+4);
}
BLT(no_cont,cond){
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b100 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]s<X[rs2]s, PC's+imm, PC+4);
}
BGE(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b101 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]s>=X[rs2]s, PC's+imm, PC+4);
}
BLTU(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b110 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]<X[rs2],PC's+imm, PC+4);
}
BGEU(no_cont,cond) {
encoding: imm[12:12]s |imm[10:5]s | rs2[4:0] | rs1[4:0] | b111 | imm[4:1]s | imm[11:11]s | b1100011;
args_disass:"{name(rs1)}, {name(rs2)}, {imm:#0x}";
PC<=choose(X[rs1]>=X[rs2], PC's+imm, PC+4);
}
LB {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]);
}
LH {
encoding: imm[11:0]s | rs1[4:0] | b001 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{16});
}
LW {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{32});
}
LBU {
encoding: imm[11:0]s | rs1[4:0] | b100 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]);
}
LHU {
encoding: imm[11:0]s | rs1[4:0] | b101 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]{16});
}
SB {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b000 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs] <= X[rs2];
}
SH {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b001 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{16} <= X[rs2];
}
SW {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b010 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{32} <= X[rs2];
}
ADDI {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]'s + imm;
}
SLTI {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if (rd != 0) X[rd] <= choose(X[rs1]s < imm's, 1, 0);
}
SLTIU {
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
val full_imm[XLEN] <= imm's;
if (rd != 0) X[rd] <= choose(X[rs1]'u < full_imm'u, 1, 0);
}
XORI {
encoding: imm[11:0]s | rs1[4:0] | b100 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s ^ imm;
}
ORI {
encoding: imm[11:0]s | rs1[4:0] | b110 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s | imm;
}
ANDI {
encoding: imm[11:0]s | rs1[4:0] | b111 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0) X[rd] <= X[rs1]s & imm;
}
SLLI {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b001 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shll(X[rs1], shamt);
}
}
SRLI {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shrl(X[rs1], shamt);
}
}
SRAI {
encoding: b0100000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(shamt > 31){
raise(0,0);
} else {
if(rd != 0) X[rd] <= shra(X[rs1], shamt);
}
}
ADD {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] + X[rs2];
}
SUB {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] - X[rs2];
}
SLL {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shll(X[rs1], X[rs2]&(XLEN-1));
}
SLT {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if (rd != 0) X[rd] <= choose(X[rs1]s < X[rs2]s, 1, 0);
}
SLTU {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if (rd != 0) X[rd] <= choose(zext(X[rs1]) < zext(X[rs2]), 1, 0);
}
XOR {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] ^ X[rs2];
}
SRL {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shrl(X[rs1], X[rs2]&(XLEN-1));
}
SRA {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= shra(X[rs1], X[rs2]&(XLEN-1));
}
OR {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] | X[rs2];
}
AND {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0) X[rd] <= X[rs1] & X[rs2];
}
FENCE {
encoding: b0000 | pred[3:0] | succ[3:0] | rs1[4:0] | b000 | rd[4:0] | b0001111;
FENCE[fence] <= pred<<4 | succ;
}
FENCE_I(flush) {
encoding: imm[11:0] | rs1[4:0] | b001 | rd[4:0] | b0001111 ;
FENCE[fencei] <= imm;
}
ECALL(no_cont) {
encoding: b000000000000 | b00000 | b000 | b00000 | b1110011;
raise(0, 11);
}
EBREAK(no_cont) {
encoding: b000000000001 | b00000 | b000 | b00000 | b1110011;
raise(0, 3);
}
URET(no_cont) {
encoding: b0000000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(0);
}
SRET(no_cont) {
encoding: b0001000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(1);
}
MRET(no_cont) {
encoding: b0011000 | b00010 | b00000 | b000 | b00000 | b1110011;
leave(3);
}
WFI {
encoding: b0001000 | b00101 | b00000 | b000 | b00000 | b1110011;
wait(1);
}
SFENCE.VMA {
encoding: b0001001 | rs2[4:0] | rs1[4:0] | b000 | b00000 | b1110011;
FENCE[fencevmal] <= rs1;
FENCE[fencevmau] <= rs2;
}
CSRRW {
encoding: csr[11:0] | rs1[4:0] | b001 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val rs_val[XLEN] <= X[rs1];
if(rd!=0){
val csr_val[XLEN] <= CSR[csr];
CSR[csr] <= rs_val;
// make sure Xrd is updated once CSR write succeeds
X[rd] <= csr_val;
} else {
CSR[csr] <= rs_val;
}
}
CSRRS {
encoding: csr[11:0] | rs1[4:0] | b010 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val xrd[XLEN] <= CSR[csr];
val xrs1[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= xrd;
if(rs1!=0) CSR[csr] <= xrd | xrs1;
}
CSRRC {
encoding: csr[11:0] | rs1[4:0] | b011 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {name(rs1)}";
val xrd[XLEN] <= CSR[csr];
val xrs1[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= xrd;
if(rs1!=0) CSR[csr] <= xrd & ~xrs1;
}
CSRRWI {
encoding: csr[11:0] | zimm[4:0] | b101 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
if(rd!=0) X[rd] <= CSR[csr];
CSR[csr] <= zext(zimm);
}
CSRRSI {
encoding: csr[11:0] | zimm[4:0] | b110 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
val res[XLEN] <= CSR[csr];
if(zimm!=0) CSR[csr] <= res | zext(zimm);
// make sure rd is written after csr write succeeds
if(rd!=0) X[rd] <= res;
}
CSRRCI {
encoding: csr[11:0] | zimm[4:0] | b111 | rd[4:0] | b1110011;
args_disass:"{name(rd)}, {csr}, {zimm:#0x}";
val res[XLEN] <= CSR[csr];
if(rd!=0) X[rd] <= res;
if(zimm!=0) CSR[csr] <= res & ~zext(zimm, XLEN);
}
}
}

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import "RV32I.core_desc"
InsructionSet RV64I extends RV32I {
instructions{
LWU { // 80000104: 0000ef03 lwu t5,0(ra)
encoding: imm[11:0]s | rs1[4:0] | b110 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s+imm;
if(rd!=0) X[rd]<=zext(MEM[offs]{32});
}
LD{
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0000011;
args_disass:"{name(rd)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
if(rd!=0) X[rd]<=sext(MEM[offs]{64});
}
SD{
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b011 | imm[4:0]s | b0100011;
args_disass:"{name(rs2)}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{64} <= X[rs2];
}
SLLI {
encoding: b000000 | shamt[5:0] | rs1[4:0] | b001 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shll(X[rs1], shamt);
}
SRLI {
encoding: b000000 | shamt[5:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shrl(X[rs1], shamt);
}
SRAI {
encoding: b010000 | shamt[5:0] | rs1[4:0] | b101 | rd[4:0] | b0010011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0) X[rd] <= shra(X[rs1], shamt);
}
ADDIW {
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {imm}";
if(rd != 0){
val res[32] <= X[rs1]{32}'s + imm;
X[rd] <= sext(res);
}
}
SLLIW {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b001 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shll(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
SRLIW {
encoding: b0000000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shrl(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
SRAIW {
encoding: b0100000 | shamt[4:0] | rs1[4:0] | b101 | rd[4:0] | b0011011;
args_disass:"{name(rd)}, {name(rs1)}, {shamt}";
if(rd != 0){
val sh_val[32] <= shra(X[rs1]{32}, shamt);
X[rd] <= sext(sh_val);
}
}
ADDW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
if(rd != 0){
val res[32] <= X[rs1]{32} + X[rs2]{32};
X[rd] <= sext(res);
}
}
SUBW {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
if(rd != 0){
val res[32] <= X[rs1]{32} - X[rs2]{32};
X[rd] <= sext(res);
}
}
SLLW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shll(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
SRLW {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shrl(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
SRAW {
encoding: b0100000 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val mask[32] <= 0x1f;
val count[32] <= X[rs2]{32} & mask;
val sh_val[32] <= shra(X[rs1]{32}, count);
X[rd] <= sext(sh_val);
}
}
}
}

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import "RISCVBase.core_desc"
InsructionSet RV32A extends RISCVBase{
instructions{
LR.W {
encoding: b00010 | aq[0:0] | rl[0:0] | b00000 | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}";
if(rd!=0){
val offs[XLEN] <= X[rs1];
X[rd]<= sext(MEM[offs]{32}, XLEN);
RES[offs]{32}<=sext(-1, 32);
}
}
SC.W {
encoding: b00011 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)}";
val offs[XLEN] <= X[rs1];
val res1[32] <= RES[offs]{32};
if(res1!=0)
MEM[offs]{32} <= X[rs2];
if(rd!=0) X[rd]<= choose(res1!=zext(0, 32), 0, 1);
}
AMOSWAP.W{
encoding: b00001 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
if(rd!=0) X[rd]<=sext(MEM[offs]{32});
MEM[offs]{32}<=X[rs2];
}
AMOADD.W{
encoding: b00000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 + X[rs2];
MEM[offs]{32}<=res2;
}
AMOXOR.W{
encoding: b00100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 ^ X[rs2];
MEM[offs]{32}<=res2;
}
AMOAND.W{
encoding: b01100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN] <=res1 & X[rs2];
MEM[offs]{32}<=res2;
}
AMOOR.W {
encoding: b01000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<=res1 | X[rs2];
MEM[offs]{32}<=res2;
}
AMOMIN.W{
encoding: b10000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1's > X[rs2]s, X[rs2], res1);
MEM[offs]{32} <= res2;
}
AMOMAX.W{
encoding: b10100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<= choose(res1's<X[rs2]s, X[rs2], res1);
MEM[offs]{32}<=res2;
}
AMOMINU.W{
encoding: b11000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd]<=res1;
val res2[XLEN]<= choose(res1>X[rs2], X[rs2], res1);
MEM[offs]{32}<=res2;
}
AMOMAXU.W{
encoding: b11100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN]<=X[rs1];
val res1[XLEN] <= sext(MEM[offs]{32});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1 < X[rs2], X[rs2], res1);
MEM[offs]{32} <= res2;
}
}
}
InsructionSet RV64A extends RV32A {
instructions{
LR.D {
encoding: b00010 | aq[0:0] | rl[0:0] | b00000 | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}";
if(rd!=0){
val offs[XLEN] <= X[rs1];
X[rd]<= sext(MEM[offs]{64}, XLEN);
RES[offs]{64}<=sext(-1, 64);
}
}
SC.D {
encoding: b00011 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)}";
val offs[XLEN] <= X[rs1];
val res[64] <= RES[offs];
if(res!=0){
MEM[offs]{64} <= X[rs2];
if(rd!=0) X[rd]<=0;
} else{
if(rd!=0) X[rd]<= 1;
}
}
AMOSWAP.D{
encoding: b00001 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
if(rd!=0) X[rd] <= sext(MEM[offs]{64});
MEM[offs]{64} <= X[rs2];
}
AMOADD.D{
encoding: b00000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd]<=res;
val res2[XLEN] <= res + X[rs2];
MEM[offs]{64}<=res2;
}
AMOXOR.D{
encoding: b00100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res ^ X[rs2];
MEM[offs]{64} <= res2;
}
AMOAND.D{
encoding: b01100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res & X[rs2];
MEM[offs]{64} <= res2;
}
AMOOR.D {
encoding: b01000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= res | X[rs2];
MEM[offs]{64} <= res2;
}
AMOMIN.D{
encoding: b10000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res1[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1's > X[rs2]s, X[rs2], res1);
MEM[offs]{64} <= res2;
}
AMOMAX.D{
encoding: b10100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= choose(res s < X[rs2]s, X[rs2], res);
MEM[offs]{64} <= res2;
}
AMOMINU.D{
encoding: b11000 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res;
val res2[XLEN] <= choose(res > X[rs2], X[rs2], res);
MEM[offs]{64} <= res2;
}
AMOMAXU.D{
encoding: b11100 | aq[0:0] | rl[0:0] | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0101111;
args_disass: "{name(rd)}, {name(rs1)}, {name(rs2)} (aqu={aq},rel={rl})";
val offs[XLEN] <= X[rs1];
val res1[XLEN] <= sext(MEM[offs]{64});
if(rd!=0) X[rd] <= res1;
val res2[XLEN] <= choose(res1 < X[rs2], X[rs2], res1);
MEM[offs]{64} <= res2;
}
}
}

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import "RISCVBase.core_desc"
InsructionSet RV32IC extends RISCVBase{
instructions{
JALR(no_cont){ // overwriting the implementation if rv32i, alignment does not need to be word
encoding: imm[11:0]s | rs1[4:0] | b000 | rd[4:0] | b1100111;
args_disass: "{name(rd)}, {name(rs1)}, {imm:#0x}";
val new_pc[XLEN] <= X[rs1]s + imm;
if(rd!=0) X[rd] <= PC+4;
PC<=new_pc & ~0x1;
}
C.ADDI4SPN { //(RES, imm=0)
encoding: b000 | imm[5:4] | imm[9:6] | imm[2:2] | imm[3:3] | rd[2:0] | b00;
args_disass: "{name(rd)}, {imm:#05x}";
if(imm == 0) raise(0, 2);
X[rd+8] <= X[2] + imm;
}
C.LW { // (RV32)
encoding: b010 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rd[2:0] | b00;
args_disass: "{name(8+rd)}, {uimm:#05x}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
X[rd+8] <= sext(MEM[offs]{32});
}
C.SW {//(RV32)
encoding: b110 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rs2[2:0] | b00;
args_disass: "{name(8+rs2)}, {uimm:#05x}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{32} <= X[rs2+8];
}
C.ADDI {//(RV32)
encoding:b000 | imm[5:5]s | rs1[4:0] | imm[4:0]s | b01;
args_disass: "{name(rs1)}, {imm:#05x}";
X[rs1] <= X[rs1]'s + imm;
}
C.NOP {
encoding:b000 | b0 | b00000 | b00000 | b01;
}
// C.JAL will be overwritten by C.ADDIW for RV64/128
C.JAL(no_cont) {//(RV32)
encoding: b001 | imm[11:11]s | imm[4:4]s | imm[9:8]s | imm[10:10]s | imm[6:6]s | imm[7:7]s | imm[3:1]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
X[1] <= PC+2;
PC<=PC's+imm;
}
C.LI {//(RV32)
encoding:b010 | imm[5:5]s | rd[4:0] | imm[4:0]s | b01;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd == 0) raise(0, 2); //TODO: should it be handled as trap?
X[rd] <= imm;
}
// order matters here as C.ADDI16SP overwrites C.LUI vor rd==2
C.LUI {//(RV32)
encoding:b011 | imm[17:17] | rd[4:0] | imm[16:12]s | b01;
args_disass: "{name(rd)}, {imm:#05x}";
if(rd == 0) raise(0, 2); //TODO: should it be handled as trap?
if(imm == 0) raise(0, 2); //TODO: should it be handled as trap?
X[rd] <= imm;
}
C.ADDI16SP {//(RV32)
encoding:b011 | imm[9:9]s | b00010 | imm[4:4]s | imm[6:6]s | imm[8:7]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
X[2] <= X[2]s + imm;
}
C.SRLI {//(RV32 nse)
encoding:b100 | b0 | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV32)
encoding:b100 | b0 | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.ANDI {//(RV32)
encoding:b100 | imm[5:5]s | b10 | rs1[2:0] | imm[4:0]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
val rs1_idx[5] <= rs1 + 8;
X[rs1_idx] <= X[rs1_idx]s & imm;
}
C.SUB {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b00 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] - X[rs2 + 8];
}
C.XOR {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b01 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] ^ X[rs2 + 8];
}
C.OR {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b10 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] | X[rs2 + 8];
}
C.AND {//(RV32)
encoding:b100 | b0 | b11 | rd[2:0] | b11 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rs2)}";
val rd_idx[5] <= rd + 8;
X[rd_idx] <= X[rd_idx] & X[rs2 + 8];
}
C.J(no_cont) {//(RV32)
encoding:b101 | imm[11:11]s | imm[4:4]s | imm[9:8]s | imm[10:10]s | imm[6:6]s | imm[7:7]s | imm[3:1]s | imm[5:5]s | b01;
args_disass: "{imm:#05x}";
PC<=PC's+imm;
}
C.BEQZ(no_cont,cond) {//(RV32)
encoding:b110 | imm[8:8]s | imm[4:3]s | rs1[2:0] | imm[7:6]s |imm[2:1]s | imm[5:5]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
PC<=choose(X[rs1+8]==0, PC's+imm, PC+2);
}
C.BNEZ(no_cont,cond) {//(RV32)
encoding:b111 | imm[8:8]s | imm[4:3]s | rs1[2:0] | imm[7:6]s | imm[2:1]s | imm[5:5]s | b01;
args_disass: "{name(8+rs1)}, {imm:#05x}";
PC<=choose(X[rs1+8]!=0, PC's+imm, PC+2);
}
C.SLLI {//(RV32)
encoding:b000 | b0 | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LWSP {//
encoding:b010 | uimm[5:5] | rd[4:0] | uimm[4:2] | uimm[7:6] | b10;
args_disass: "{name(rd)}, sp, {uimm:#05x}";
val offs[XLEN] <= X[2] + uimm;
X[rd] <= sext(MEM[offs]{32});
}
// order matters as C.JR is a special case of C.MV
C.MV {//(RV32)
encoding:b100 | b0 | rd[4:0] | rs2[4:0] | b10;
args_disass: "{name(rd)}, {name(rs2)}";
X[rd] <= X[rs2];
}
C.JR(no_cont) {//(RV32)
encoding:b100 | b0 | rs1[4:0] | b00000 | b10;
args_disass: "{name(rs1)}";
PC <= X[rs1];
}
// order matters as C.EBREAK is a special case of C.JALR which is a special case of C.ADD
C.ADD {//(RV32)
encoding:b100 | b1 | rd[4:0] | rs2[4:0] | b10;
args_disass: "{name(rd)}, {name(rs2)}";
X[rd] <= X[rd] + X[rs2];
}
C.JALR(no_cont) {//(RV32)
encoding:b100 | b1 | rs1[4:0] | b00000 | b10;
args_disass: "{name(rs1)}";
X[1] <= PC+2;
PC<=X[rs1];
}
C.EBREAK(no_cont) {//(RV32)
encoding:b100 | b1 | b00000 | b00000 | b10;
raise(0, 3);
}
C.SWSP {//
encoding:b110 | uimm[5:2] | uimm[7:6] | rs2[4:0] | b10;
args_disass: "{name(rs2)}, {uimm:#05x}(sp)";
val offs[XLEN] <= X[2] + uimm;
MEM[offs]{32} <= X[rs2];
}
DII {
encoding:b000 | b0 | b00000 | b00000 | b00;
raise(0, 2);
}
}
}
InsructionSet RV32FC extends RV32IC{
constants {
FLEN
}
registers {
[31:0] F[FLEN]
}
instructions{
C.FLW {
encoding: b011 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rd[2:0] | b00;
args_disass:"f(8+{rd}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd+8] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd+8] <= (upper<<32) | zext(res, FLEN);
}
}
C.FSW {
encoding: b111 | uimm[5:3] | rs1[2:0] | uimm[2:2] | uimm[6:6] | rs2[2:0] | b00;
args_disass:"f(8+{rs2}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{32}<=F[rs2+8]{32};
}
C.FLWSP {
encoding:b011 | uimm[5:5] | rd[4:0] | uimm[4:2] | uimm[7:6] | b10;
args_disass:"f{rd}, {uimm}(x2)";
val offs[XLEN] <= X[2]+uimm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
C.FSWSP {
encoding:b111 | uimm[5:2] | uimm[7:6] | rs2[4:0] | b10;
args_disass:"f{rs2}, {uimm}(x2), ";
val offs[XLEN] <= X[2]+uimm;
MEM[offs]{32}<=F[rs2]{32};
}
}
}
InsructionSet RV32DC extends RV32IC{
constants {
FLEN
}
registers {
[31:0] F[FLEN]
}
instructions{
C.FLD { //(RV32/64)
encoding: b001 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
args_disass:"f(8+{rd}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd+8] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd+8] <= (upper<<64) | res;
}
}
C.FSD { //(RV32/64)
encoding: b101 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
args_disass:"f(8+{rs2}), {uimm}({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8]+uimm;
MEM[offs]{64}<=F[rs2+8]{64};
}
C.FLDSP {//(RV32/64)
encoding:b001 | uimm[5:5] | rd[4:0] | uimm[4:3] | uimm[8:6] | b10;
args_disass:"f{rd}, {uimm}(x2)";
val offs[XLEN] <= X[2]+uimm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | zext(res, FLEN);
}
}
C.FSDSP {//(RV32/64)
encoding:b101 | uimm[5:3] | uimm[8:6] | rs2[4:0] | b10;
args_disass:"f{rs2}, {uimm}(x2), ";
val offs[XLEN] <= X[2]+uimm;
MEM[offs]{64}<=F[rs2]{64};
}
}
}
InsructionSet RV64IC extends RV32IC {
instructions{
C.LD {//(RV64/128)
encoding:b011 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
args_disass: "{name(8+rd)}, {uimm},({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8] + uimm;
X[rd+8]<=sext(MEM[offs]{64});
}
C.SD { //(RV64/128)
encoding:b111 | uimm[5:3] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
args_disass: "{name(8+rs2)}, {uimm},({name(8+rs1)})";
val offs[XLEN] <= X[rs1+8] + uimm;
MEM[offs]{64} <= X[rs2+8];
}
C.SUBW {//(RV64/128, RV32 res)
encoding:b100 | b1 | b11 | rd[2:0] | b00 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rd)}, {name(8+rs2)}";
val res[32] <= X[rd+8]{32} - X[rs2+8]{32};
X[rd+8] <= sext(res);
}
C.ADDW {//(RV64/128 RV32 res)
encoding:b100 | b1 | b11 | rd[2:0] | b01 | rs2[2:0] | b01;
args_disass: "{name(8+rd)}, {name(8+rd)}, {name(8+rs2)}";
val res[32] <= X[rd+8]{32} + X[rs2+8]{32};
X[rd+8] <= sext(res);
}
C.ADDIW {//(RV64/128)
encoding:b001 | imm[5:5]s | rs1[4:0] | imm[4:0]s | b01;
args_disass: "{name(rs1)}, {imm:#05x}";
if(rs1 != 0){
val res[32] <= X[rs1]{32}'s + imm;
X[rs1] <= sext(res);
}
}
C.SRLI {//(RV64)
encoding:b100 | shamt[5:5] | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV64)
encoding:b100 | shamt[5:5] | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.SLLI {//(RV64)
encoding:b000 | shamt[5:5] | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LDSP {//(RV64/128
encoding:b011 | uimm[5:5] | rd[4:0] | uimm[4:3] | uimm[8:6] | b10;
args_disass:"{name(rd)}, {uimm}(sp)";
val offs[XLEN] <= X[2] + uimm;
if(rd!=0) X[rd]<=sext(MEM[offs]{64});
}
C.SDSP {//(RV64/128)
encoding:b111 | uimm[5:3] | uimm[8:6] | rs2[4:0] | b10;
args_disass:"{name(rs2)}, {uimm}(sp)";
val offs[XLEN] <= X[2] + uimm;
MEM[offs]{64} <= X[rs2];
}
}
}
InsructionSet RV128IC extends RV64IC {
instructions{
C.SRLI {//(RV128)
encoding:b100 | shamt[5:5] | b00 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shrl(X[rs1_idx], shamt);
}
C.SRAI {//(RV128)
encoding:b100 | shamt[5:5] | b01 | rs1[2:0] | shamt[4:0] | b01;
args_disass: "{name(8+rs1)}, {shamt}";
val rs1_idx[5] <= rs1+8;
X[rs1_idx] <= shra(X[rs1_idx], shamt);
}
C.SLLI {//(RV128)
encoding:b000 | shamt[5:5] | rs1[4:0] | shamt[4:0] | b10;
args_disass: "{name(rs1)}, {shamt}";
if(rs1 == 0) raise(0, 2);
X[rs1] <= shll(X[rs1], shamt);
}
C.LQ { //(RV128)
encoding:b001 | uimm[5:4] | uimm[8:8] | rs1[2:0] | uimm[7:6] | rd[2:0] | b00;
}
C.SQ { //(RV128)
encoding:b101 | uimm[5:4] | uimm[8:8] | rs1[2:0] | uimm[7:6] | rs2[2:0] | b00;
}
C.SQSP {//(RV128)
encoding:b101 | uimm[5:4] | uimm[9:6] | rs2[4:0] | b10;
}
}
}

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import "RISCVBase.core_desc"
InsructionSet RV32D extends RISCVBase{
constants {
FLEN, FFLAG_MASK := 0x1f
}
registers {
[31:0] F[FLEN], FCSR[32]
}
instructions{
FLD {
encoding: imm[11:0]s | rs1[4:0] | b011 | rd[4:0] | b0000111;
args_disass:"f{rd}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
val res[64] <= MEM[offs]{64};
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSD {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b011 | imm[4:0]s | b0100111;
args_disass:"f{rs2}, {imm}({name(rs1)})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{64}<=F[rs2]{64};
}
FMADD.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<= F[rs1]f * F[rs2]f + F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(0, 64), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMSUB.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000111;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=F[rs1]f * F[rs2]f - F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMADD.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001111;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f + F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMSUB.D {
encoding: rs3[4:0] | b01 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f - F[rs3]f;
val res[64] <= fdispatch_fmadd_d(F[rs1]{64}, F[rs2]{64}, F[rs3]{64}, zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FADD.D {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f + F[rs2]f;
val res[64] <= fdispatch_fadd_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSUB.D {
encoding: b0000101 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f - F[rs2]f;
val res[64] <= fdispatch_fsub_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMUL.D {
encoding: b0001001 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f * F[rs2]f;
val res[64] <= fdispatch_fmul_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FDIV.D {
encoding: b0001101 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f / F[rs2]f;
val res[64] <= fdispatch_fdiv_d(F[rs1]{64}, F[rs2]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSQRT.D {
encoding: b0101101 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//F[rd]f<=sqrt(F[rs1]f);
val res[64] <= fdispatch_fsqrt_d(F[rs1]{64}, choose(rm<7, rm{8}, FCSR{8}));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSGNJ.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val MSK2[64] <= MSK1-1;
val res[64] <= (F[rs1]{64} & MSK2) | (F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSGNJN.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val MSK2[64] <= MSK1-1;
val res[64] <= (F[rs1]{64} & MSK2) | (~F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FSGNJX.D {
encoding: b0010001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
val ONE[64] <= 1;
val MSK1[64] <= ONE<<63;
val res[64] <= F[rs1]{64} ^ (F[rs2]{64} & MSK1);
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FMIN.D {
encoding: b0010101 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f<F[rs2]f, F[rs1]f, F[rs2]f);
val res[64] <= fdispatch_fsel_d(F[rs1]{64}, F[rs2]{64}, zext(0, 32));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMAX.D {
encoding: b0010101 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f>F[rs2]f, F[rs1]f, F[rs2]f);
val res[64] <= fdispatch_fsel_d(F[rs1]{64}, F[rs2]{64}, zext(1, 32));
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.S.D {
encoding: b0100000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
val res[32] <= fdispatch_fconv_d2f(F[rs1], rm{8});
// NaN boxing
val upper[FLEN] <= -1;
F[rd] <= upper<<32 | zext(res, FLEN);
}
FCVT.D.S {
encoding: b0100001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
val res[64] <= fdispatch_fconv_f2d(F[rs1]{32}, rm{8});
if(FLEN==64){
F[rd] <= res;
} else {
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FEQ.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(0, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLT.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(2, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLE.D {
encoding: b1010001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
X[rd]<=zext(fdispatch_fcmp_d(F[rs1]{64}, F[rs2]{64}, zext(1, 32)));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCLASS.D {
encoding: b1110001 | b00000 | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=fdispatch_fclass_d(F[rs1]{64});
}
FCVT.W.D {
encoding: b1100001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_64_32(F[rs1]{64}, zext(0, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.WU.D {
encoding: b1100001 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//FIXME: should be zext accodring to spec but needs to be sext according to tests
X[rd]<= sext(fdispatch_fcvt_64_32(F[rs1]{64}, zext(1, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.D.W {
encoding: b1101001 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <= fdispatch_fcvt_32_64(sext(X[rs1]{32},64), zext(2, 32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FCVT.D.WU {
encoding: b1101001 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <=fdispatch_fcvt_32_64(zext(X[rs1]{32},64), zext(3,32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
}
}
InsructionSet RV64D extends RV32D{
instructions{
FCVT.L.D {
encoding: b1100001 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_d(F[rs1]{64}, zext(0, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.LU.D {
encoding: b1100001 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<= sext(fdispatch_fcvt_d(F[rs1]{64}, zext(1, 32), rm{8}), XLEN);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.D.L {
encoding: b1101001 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <= fdispatch_fcvt_d(sext(X[rs1],64), zext(2, 32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FCVT.D.LU {
encoding: b1101001 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
val res[64] <=fdispatch_fcvt_d(zext(X[rs1],64), zext(3,32), rm{8});
if(FLEN==64)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<64) | res;
}
}
FMV.X.D {
encoding: b1110001 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=sext(F[rs1]);
}
FMV.D.X {
encoding: b1111001 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
F[rd] <= zext(X[rs1]);
}
}
}

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import "RV32I.core_desc"
InsructionSet RV32F extends RV32I{
constants {
FLEN, FFLAG_MASK := 0x1f
}
registers {
[31:0] F[FLEN], FCSR[32]
}
instructions{
FLW {
encoding: imm[11:0]s | rs1[4:0] | b010 | rd[4:0] | b0000111;
args_disass:"f{rd}, {imm}(x{rs1})";
val offs[XLEN] <= X[rs1]'s + imm;
val res[32] <= MEM[offs]{32};
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSW {
encoding: imm[11:5]s | rs2[4:0] | rs1[4:0] | b010 | imm[4:0]s | b0100111;
args_disass:"f{rs2}, {imm}(x{rs1})";
val offs[XLEN] <= X[rs1]'s + imm;
MEM[offs]{32}<=F[rs2]{32};
}
FMADD.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000011;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<= F[rs1]f * F[rs2]f + F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(0, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(0, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMSUB.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1000111;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=F[rs1]f * F[rs2]f - F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(1, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMADD.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001111;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f + F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(2, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FNMSUB.S {
encoding: rs3[4:0] | b00 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1001011;
args_disass:"x{rd}, f{rs1}, f{rs2}, f{rs3}";
//F[rd]f<=-F[rs1]f * F[rs2]f - F[rs3]f;
if(FLEN==32)
F[rd] <= fdispatch_fmadd_s(F[rs1], F[rs2], F[rs3], zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val frs3[32] <= fdispatch_unbox_s(F[rs3]);
val res[32] <= fdispatch_fmadd_s(frs1, frs2, frs3, zext(3, 32), choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FADD.S {
encoding: b0000000 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f + F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fadd_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fadd_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSUB.S {
encoding: b0000100 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f - F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fsub_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsub_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMUL.S {
encoding: b0001000 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f * F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fmul_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fmul_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FDIV.S {
encoding: b0001100 | rs2[4:0] | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
// F[rd]f <= F[rs1]f / F[rs2]f;
if(FLEN==32)
F[rd] <= fdispatch_fdiv_s(F[rs1], F[rs2], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fdiv_s(frs1, frs2, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSQRT.S {
encoding: b0101100 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}";
//F[rd]f<=sqrt(F[rs1]f);
if(FLEN==32)
F[rd] <= fdispatch_fsqrt_s(F[rs1], choose(rm<7, rm{8}, FCSR{8}));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val res[32] <= fdispatch_fsqrt_s(frs1, choose(rm<7, rm{8}, FCSR{8}));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FSGNJ.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= (F[rs1] & 0x7fffffff) | (F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= (frs1 & 0x7fffffff) | (frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSGNJN.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= (F[rs1] & 0x7fffffff) | (~F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= (frs1 & 0x7fffffff) | (~frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FSGNJX.S {
encoding: b0010000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
if(FLEN==32)
F[rd] <= F[rs1] ^ (F[rs2] & 0x80000000);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= frs1 ^ (frs2 & 0x80000000);
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FMIN.S {
encoding: b0010100 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f<F[rs2]f, F[rs1]f, F[rs2]f);
if(FLEN==32)
F[rd] <= fdispatch_fsel_s(F[rs1], F[rs2], zext(0, 32));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsel_s(frs1, frs2, zext(0, 32));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FMAX.S {
encoding: b0010100 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"f{rd}, f{rs1}, f{rs2}";
//F[rd]f<= choose(F[rs1]f>F[rs2]f, F[rs1]f, F[rs2]f);
if(FLEN==32)
F[rd] <= fdispatch_fsel_s(F[rs1], F[rs2], zext(1, 32));
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
val res[32] <= fdispatch_fsel_s(frs1, frs2, zext(1, 32));
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.W.S {
encoding: b1100000 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
if(FLEN==32)
X[rd] <= sext(fdispatch_fcvt_s(F[rs1], zext(0, 32), rm{8}), XLEN);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
X[rd]<= sext(fdispatch_fcvt_s(frs1, zext(0, 32), rm{8}), XLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.WU.S {
encoding: b1100000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
//FIXME: according to the spec it should be zero-extended not sign extended
if(FLEN==32)
X[rd]<= sext(fdispatch_fcvt_s(F[rs1], zext(1, 32), rm{8}), XLEN);
else { // NaN boxing
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
X[rd]<= sext(fdispatch_fcvt_s(frs1, zext(1, 32), rm{8}), XLEN);
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FEQ.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(0, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(0, 32)));
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLT.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(2, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(2, 32)));
}
X[rd]<=fdispatch_fcmp_s(F[rs1]{32}, F[rs2]{32}, zext(2, 32));
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FLE.S {
encoding: b1010000 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}, f{rs2}";
if(FLEN==32)
X[rd]<=zext(fdispatch_fcmp_s(F[rs1], F[rs2], zext(1, 32)));
else {
val frs1[32] <= fdispatch_unbox_s(F[rs1]);
val frs2[32] <= fdispatch_unbox_s(F[rs2]);
X[rd]<=zext(fdispatch_fcmp_s(frs1, frs2, zext(1, 32)));
}
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCLASS.S {
encoding: b1110000 | b00000 | rs1[4:0] | b001 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=fdispatch_fclass_s(fdispatch_unbox_s(F[rs1]));
}
FCVT.S.W {
encoding: b1101000 | b00000 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <= fdispatch_fcvt_s(X[rs1]{32}, zext(2, 32), rm{8});
else { // NaN boxing
val res[32] <= fdispatch_fcvt_s(X[rs1]{32}, zext(2, 32), rm{8});
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FCVT.S.WU {
encoding: b1101000 | b00001 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <=fdispatch_fcvt_s(X[rs1]{32}, zext(3,32), rm{8});
else { // NaN boxing
val res[32] <=fdispatch_fcvt_s(X[rs1]{32}, zext(3,32), rm{8});
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FMV.X.W {
encoding: b1110000 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"{name(rd)}, f{rs1}";
X[rd]<=sext(F[rs1]{32});
}
FMV.W.X {
encoding: b1111000 | b00000 | rs1[4:0] | b000 | rd[4:0] | b1010011;
args_disass:"f{rd}, {name(rs1)}";
if(FLEN==32)
F[rd] <= X[rs1]{32};
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(X[rs1]{32}, FLEN);
}
}
}
}
InsructionSet RV64F extends RV32F{
instructions{
FCVT.L.S { // fp to 64bit signed integer
encoding: b1100000 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"x{rd}, f{rs1}";
val res[64] <= fdispatch_fcvt_32_64(fdispatch_unbox_s(F[rs1]), zext(0, 32), rm{8});
X[rd]<= sext(res);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.LU.S { // fp to 64bit unsigned integer
encoding: b1100000 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"x{rd}, f{rs1}";
val res[64] <= fdispatch_fcvt_32_64(fdispatch_unbox_s(F[rs1]), zext(1, 32), rm{8});
X[rd]<= zext(res);
val flags[32] <= fdispatch_fget_flags();
FCSR <= (FCSR & ~FFLAG_MASK) + flags{5};
}
FCVT.S.L { // 64bit signed int to to fp
encoding: b1101000 | b00010 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, x{rs1}";
val res[32] <= fdispatch_fcvt_64_32(X[rs1], zext(2, 32));
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
FCVT.S.LU { // 64bit unsigned int to to fp
encoding: b1101000 | b00011 | rs1[4:0] | rm[2:0] | rd[4:0] | b1010011;
args_disass:"f{rd}, x{rs1}";
val res[32] <=fdispatch_fcvt_64_32(X[rs1], zext(3,32));
if(FLEN==32)
F[rd] <= res;
else { // NaN boxing
val upper[FLEN] <= -1;
F[rd] <= (upper<<32) | zext(res, FLEN);
}
}
}
}

160
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import "RISCVBase.core_desc"
InsructionSet RV32M extends RISCVBase {
constants {
MAXLEN:=128
}
instructions{
MUL{
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= zext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res , XLEN);
}
}
MULH {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b001 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= sext(X[rs1], MAXLEN) * sext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
MULHSU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b010 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= sext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
MULHU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b011 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
val res[MAXLEN] <= zext(X[rs1], MAXLEN) * zext(X[rs2], MAXLEN);
X[rd]<= zext(res >> XLEN, XLEN);
}
}
DIV {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0){
val M1[XLEN] <= -1;
val XLM1[8] <= XLEN-1;
val ONE[XLEN] <= 1;
val MMIN[XLEN] <= ONE<<XLM1;
if(X[rs1]==MMIN && X[rs2]==M1)
X[rd] <= MMIN;
else
X[rd] <= X[rs1]s / X[rs2]s;
}else
X[rd] <= -1;
}
}
DIVU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0)
X[rd] <= X[rs1] / X[rs2];
else
X[rd] <= -1;
}
}
REM {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0) {
val M1[XLEN] <= -1; // constant -1
val XLM1[32] <= XLEN-1;
val ONE[XLEN] <= 1;
val MMIN[XLEN] <= ONE<<XLM1; // -2^(XLEN-1)
if(X[rs1]==MMIN && X[rs2]==M1)
X[rd] <= 0;
else
X[rd] <= X[rs1]'s % X[rs2]'s;
} else
X[rd] <= X[rs1];
}
}
REMU {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0110011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0)
X[rd] <= X[rs1] % X[rs2];
else
X[rd] <= X[rs1];
}
}
}
}
InsructionSet RV64M extends RV32M {
instructions{
MULW{
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b000 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
X[rd]<= sext(X[rs1]{32} * X[rs2]{32});
}
}
DIVW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b100 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0){
val M1[32] <= -1;
val ONE[32] <= 1;
val MMIN[32] <= ONE<<31;
if(X[rs1]{32}==MMIN && X[rs2]{32}==M1)
X[rd] <= -1<<31;
else
X[rd] <= sext(X[rs1]{32}s / X[rs2]{32}s);
}else
X[rd] <= -1;
}
}
DIVUW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b101 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]{32}!=0)
X[rd] <= sext(X[rs1]{32} / X[rs2]{32});
else
X[rd] <= -1;
}
}
REMW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b110 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]!=0) {
val M1[32] <= -1; // constant -1
val ONE[32] <= 1;
val MMIN[32] <= ONE<<31; // -2^(XLEN-1)
if(X[rs1]{32}==MMIN && X[rs2]==M1)
X[rd] <= 0;
else
X[rd] <= sext(X[rs1]{32}s % X[rs2]{32}s);
} else
X[rd] <= sext(X[rs1]{32});
}
}
REMUW {
encoding: b0000001 | rs2[4:0] | rs1[4:0] | b111 | rd[4:0] | b0111011;
args_disass:"{name(rd)}, {name(rs1)}, {name(rs2)}";
if(rd != 0){
if(X[rs2]{32}!=0)
X[rd] <= sext(X[rs1]{32} % X[rs2]{32});
else
X[rd] <= sext(X[rs1]{32});
}
}
}
}

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import "RV32I.core_desc"
import "RV64I.core_desc"
import "RVM.core_desc"
import "RVA.core_desc"
import "RVC.core_desc"
import "RVF.core_desc"
import "RVD.core_desc"
Core RV32IMAC provides RV32I, RV32M, RV32A, RV32IC {
constants {
XLEN:=32;
PCLEN:=32;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100000101;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}
Core RV32GC provides RV32I, RV32M, RV32A, RV32F, RV32D, RV32IC, RV32FC, RV32DC {
constants {
XLEN:=32;
FLEN:=64;
PCLEN:=32;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100101101;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}
Core RV64I provides RV64I {
constants {
XLEN:=64;
PCLEN:=64;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b10000000000001000000000100000000;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}
Core RV64GC provides RV64I, RV64M, RV64A, RV64F, RV64D, RV64IC, RV32FC, RV32DC {
constants {
XLEN:=64;
FLEN:=64;
PCLEN:=64;
// definitions for the architecture wrapper
// XL ZYXWVUTSRQPONMLKJIHGFEDCBA
MISA_VAL:=0b01000000000101000001000100101101;
PGSIZE := 0x1000; //1 << 12;
PGMASK := 0xfff; //PGSIZE-1
}
}

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{
"${coreDef.name}" : [<%instructions.eachWithIndex{instr,index -> %>${index==0?"":","}
{
"name" : "${instr.name}",
"size" : ${instr.length},
"delay" : ${generator.hasAttribute(instr.instruction, com.minres.coredsl.coreDsl.InstrAttribute.COND)?[1,1]:1}
}<%}%>
]
}

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/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 HOLDER 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.
*
*******************************************************************************/
<%
import com.minres.coredsl.coreDsl.Register
import com.minres.coredsl.coreDsl.RegisterFile
import com.minres.coredsl.coreDsl.RegisterAlias
def getTypeSize(size){
if(size > 32) 64 else if(size > 16) 32 else if(size > 8) 16 else 8
}
def getOriginalName(reg){
if( reg.original instanceof RegisterFile) {
if( reg.index != null ) {
return reg.original.name+generator.generateHostCode(reg.index)
} else {
return reg.original.name
}
} else if(reg.original instanceof Register){
return reg.original.name
}
}
def getRegisterNames(){
def regNames = []
allRegs.each { reg ->
if( reg instanceof RegisterFile) {
(reg.range.right..reg.range.left).each{
regNames+=reg.name.toLowerCase()+it
}
} else if(reg instanceof Register){
regNames+=reg.name.toLowerCase()
}
}
return regNames
}
def getRegisterAliasNames(){
def regMap = allRegs.findAll{it instanceof RegisterAlias }.collectEntries {[getOriginalName(it), it.name]}
return allRegs.findAll{it instanceof Register || it instanceof RegisterFile}.collect{reg ->
if( reg instanceof RegisterFile) {
return (reg.range.right..reg.range.left).collect{ (regMap[reg.name]?:regMap[reg.name+it]?:reg.name.toLowerCase()+it).toLowerCase() }
} else if(reg instanceof Register){
regMap[reg.name]?:reg.name.toLowerCase()
}
}.flatten()
}
%>
#ifndef _${coreDef.name.toUpperCase()}_H_
#define _${coreDef.name.toUpperCase()}_H_
#include <array>
#include <iss/arch/traits.h>
#include <iss/arch_if.h>
#include <iss/vm_if.h>
namespace iss {
namespace arch {
struct ${coreDef.name.toLowerCase()};
template <> struct traits<${coreDef.name.toLowerCase()}> {
constexpr static char const* const core_type = "${coreDef.name}";
static constexpr std::array<const char*, ${getRegisterNames().size}> reg_names{
{"${getRegisterNames().join("\", \"")}"}};
static constexpr std::array<const char*, ${getRegisterAliasNames().size}> reg_aliases{
{"${getRegisterAliasNames().join("\", \"")}"}};
enum constants {${coreDef.constants.collect{c -> c.name+"="+c.value}.join(', ')}};
constexpr static unsigned FP_REGS_SIZE = ${coreDef.constants.find {it.name=='FLEN'}?.value?:0};
enum reg_e {<%
allRegs.each { reg ->
if( reg instanceof RegisterFile) {
(reg.range.right..reg.range.left).each{%>
${reg.name}${it},<%
}
} else if(reg instanceof Register){ %>
${reg.name},<%
}
}%>
NUM_REGS,
NEXT_${pc.name}=NUM_REGS,
TRAP_STATE,
PENDING_TRAP,
MACHINE_STATE,
LAST_BRANCH,
ICOUNT<%
allRegs.each { reg ->
if(reg instanceof RegisterAlias){ def aliasname=getOriginalName(reg)%>,
${reg.name} = ${aliasname}<%
}
}%>
};
using reg_t = uint${regDataWidth}_t;
using addr_t = uint${addrDataWidth}_t;
using code_word_t = uint${addrDataWidth}_t; //TODO: check removal
using virt_addr_t = iss::typed_addr_t<iss::address_type::VIRTUAL>;
using phys_addr_t = iss::typed_addr_t<iss::address_type::PHYSICAL>;
static constexpr std::array<const uint32_t, ${regSizes.size}> reg_bit_widths{
{${regSizes.join(",")}}};
static constexpr std::array<const uint32_t, ${regOffsets.size}> reg_byte_offsets{
{${regOffsets.join(",")}}};
static const uint64_t addr_mask = (reg_t(1) << (XLEN - 1)) | ((reg_t(1) << (XLEN - 1)) - 1);
enum sreg_flag_e { FLAGS };
enum mem_type_e { ${allSpaces.collect{s -> s.name}.join(', ')} };
};
struct ${coreDef.name.toLowerCase()}: public arch_if {
using virt_addr_t = typename traits<${coreDef.name.toLowerCase()}>::virt_addr_t;
using phys_addr_t = typename traits<${coreDef.name.toLowerCase()}>::phys_addr_t;
using reg_t = typename traits<${coreDef.name.toLowerCase()}>::reg_t;
using addr_t = typename traits<${coreDef.name.toLowerCase()}>::addr_t;
${coreDef.name.toLowerCase()}();
~${coreDef.name.toLowerCase()}();
void reset(uint64_t address=0) override;
uint8_t* get_regs_base_ptr() override;
/// deprecated
void get_reg(short idx, std::vector<uint8_t>& value) override {}
void set_reg(short idx, const std::vector<uint8_t>& value) override {}
/// deprecated
bool get_flag(int flag) override {return false;}
void set_flag(int, bool value) override {};
/// deprecated
void update_flags(operations op, uint64_t opr1, uint64_t opr2) override {};
inline uint64_t get_icount() { return reg.icount; }
inline bool should_stop() { return interrupt_sim; }
inline phys_addr_t v2p(const iss::addr_t& addr){
if (addr.space != traits<${coreDef.name.toLowerCase()}>::MEM || addr.type == iss::address_type::PHYSICAL ||
addr_mode[static_cast<uint16_t>(addr.access)&0x3]==address_type::PHYSICAL) {
return phys_addr_t(addr.access, addr.space, addr.val&traits<${coreDef.name.toLowerCase()}>::addr_mask);
} else
return virt2phys(addr);
}
virtual phys_addr_t virt2phys(const iss::addr_t& addr);
virtual iss::sync_type needed_sync() const { return iss::NO_SYNC; }
inline uint32_t get_last_branch() { return reg.last_branch; }
protected:
struct ${coreDef.name}_regs {<%
allRegs.each { reg ->
if( reg instanceof RegisterFile) {
(reg.range.right..reg.range.left).each{%>
uint${generator.getSize(reg)}_t ${reg.name}${it} = 0;<%
}
} else if(reg instanceof Register){ %>
uint${generator.getSize(reg)}_t ${reg.name} = 0;<%
}
}%>
uint${generator.getSize(pc)}_t NEXT_${pc.name} = 0;
uint32_t trap_state = 0, pending_trap = 0, machine_state = 0, last_branch = 0;
uint64_t icount = 0;
} reg;
std::array<address_type, 4> addr_mode;
bool interrupt_sim=false;
<%
def fcsr = allRegs.find {it.name=='FCSR'}
if(fcsr != null) {%>
uint${generator.getSize(fcsr)}_t get_fcsr(){return reg.FCSR;}
void set_fcsr(uint${generator.getSize(fcsr)}_t val){reg.FCSR = val;}
<%} else { %>
uint32_t get_fcsr(){return 0;}
void set_fcsr(uint32_t val){}
<%}%>
};
}
}
#endif /* _${coreDef.name.toUpperCase()}_H_ */

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/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 HOLDER 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.
*
*******************************************************************************/
<%
import com.minres.coredsl.coreDsl.Register
import com.minres.coredsl.coreDsl.RegisterFile
import com.minres.coredsl.coreDsl.RegisterAlias
def getOriginalName(reg){
if( reg.original instanceof RegisterFile) {
if( reg.index != null ) {
return reg.original.name+generator.generateHostCode(reg.index)
} else {
return reg.original.name
}
} else if(reg.original instanceof Register){
return reg.original.name
}
}
def getRegisterNames(){
def regNames = []
allRegs.each { reg ->
if( reg instanceof RegisterFile) {
(reg.range.right..reg.range.left).each{
regNames+=reg.name.toLowerCase()+it
}
} else if(reg instanceof Register){
regNames+=reg.name.toLowerCase()
}
}
return regNames
}
def getRegisterAliasNames(){
def regMap = allRegs.findAll{it instanceof RegisterAlias }.collectEntries {[getOriginalName(it), it.name]}
return allRegs.findAll{it instanceof Register || it instanceof RegisterFile}.collect{reg ->
if( reg instanceof RegisterFile) {
return (reg.range.right..reg.range.left).collect{ (regMap[reg.name]?:regMap[reg.name+it]?:reg.name.toLowerCase()+it).toLowerCase() }
} else if(reg instanceof Register){
regMap[reg.name]?:reg.name.toLowerCase()
}
}.flatten()
}
%>
#include "util/ities.h"
#include <util/logging.h>
#include <elfio/elfio.hpp>
#include <iss/arch/${coreDef.name.toLowerCase()}.h>
#ifdef __cplusplus
extern "C" {
#endif
#include <ihex.h>
#ifdef __cplusplus
}
#endif
#include <cstdio>
#include <cstring>
#include <fstream>
using namespace iss::arch;
constexpr std::array<const char*, ${getRegisterNames().size}> iss::arch::traits<iss::arch::${coreDef.name.toLowerCase()}>::reg_names;
constexpr std::array<const char*, ${getRegisterAliasNames().size}> iss::arch::traits<iss::arch::${coreDef.name.toLowerCase()}>::reg_aliases;
constexpr std::array<const uint32_t, ${regSizes.size}> iss::arch::traits<iss::arch::${coreDef.name.toLowerCase()}>::reg_bit_widths;
constexpr std::array<const uint32_t, ${regOffsets.size}> iss::arch::traits<iss::arch::${coreDef.name.toLowerCase()}>::reg_byte_offsets;
${coreDef.name.toLowerCase()}::${coreDef.name.toLowerCase()}() {
reg.icount = 0;
}
${coreDef.name.toLowerCase()}::~${coreDef.name.toLowerCase()}() = default;
void ${coreDef.name.toLowerCase()}::reset(uint64_t address) {
for(size_t i=0; i<traits<${coreDef.name.toLowerCase()}>::NUM_REGS; ++i) set_reg(i, std::vector<uint8_t>(sizeof(traits<${coreDef.name.toLowerCase()}>::reg_t),0));
reg.PC=address;
reg.NEXT_PC=reg.PC;
reg.trap_state=0;
reg.machine_state=0x0;
reg.icount=0;
}
uint8_t *${coreDef.name.toLowerCase()}::get_regs_base_ptr() {
return reinterpret_cast<uint8_t*>(&reg);
}
${coreDef.name.toLowerCase()}::phys_addr_t ${coreDef.name.toLowerCase()}::virt2phys(const iss::addr_t &pc) {
return phys_addr_t(pc); // change logical address to physical address
}

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/*******************************************************************************
* Copyright (C) 2017, 2018 MINRES Technologies GmbH
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. 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.
*
* 3. Neither the name of the copyright holder 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 HOLDER 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.
*
*******************************************************************************/
#include <iss/arch/${coreDef.name.toLowerCase()}.h>
#include <iss/arch/riscv_hart_msu_vp.h>
#include <iss/debugger/gdb_session.h>
#include <iss/debugger/server.h>
#include <iss/iss.h>
#include <iss/llvm/vm_base.h>
#include <util/logging.h>
#define FMT_HEADER_ONLY
#include <fmt/format.h>
#include <array>
#include <iss/debugger/riscv_target_adapter.h>
namespace iss {
namespace vm {
namespace fp_impl {
void add_fp_functions_2_module(llvm::Module *, unsigned, unsigned);
}
}
namespace ${coreDef.name.toLowerCase()} {
using namespace iss::arch;
using namespace llvm;
using namespace iss::debugger;
using namespace iss::vm::llvm;
template <typename ARCH> class vm_impl : public vm_base<ARCH> {
public:
using super = typename iss::vm::llvm::vm_base<ARCH>;
using virt_addr_t = typename super::virt_addr_t;
using phys_addr_t = typename super::phys_addr_t;
using code_word_t = typename super::code_word_t;
using addr_t = typename super::addr_t;
vm_impl();
vm_impl(ARCH &core, unsigned core_id = 0, unsigned cluster_id = 0);
void enableDebug(bool enable) { super::sync_exec = super::ALL_SYNC; }
target_adapter_if *accquire_target_adapter(server_if *srv) override {
debugger_if::dbg_enabled = true;
if (vm_base<ARCH>::tgt_adapter == nullptr)
vm_base<ARCH>::tgt_adapter = new riscv_target_adapter<ARCH>(srv, this->get_arch());
return vm_base<ARCH>::tgt_adapter;
}
protected:
using vm_base<ARCH>::get_reg_ptr;
inline const char *name(size_t index){return traits<ARCH>::reg_aliases.at(index);}
template <typename T> inline ConstantInt *size(T type) {
return ConstantInt::get(getContext(), APInt(32, type->getType()->getScalarSizeInBits()));
}
void setup_module(Module* m) override {
super::setup_module(m);
iss::vm::fp_impl::add_fp_functions_2_module(m, traits<ARCH>::FP_REGS_SIZE, traits<ARCH>::XLEN);
}
inline Value *gen_choose(Value *cond, Value *trueVal, Value *falseVal, unsigned size) {
return super::gen_cond_assign(cond, this->gen_ext(trueVal, size), this->gen_ext(falseVal, size));
}
std::tuple<continuation_e, BasicBlock *> gen_single_inst_behavior(virt_addr_t &, unsigned int &, BasicBlock *) override;
void gen_leave_behavior(BasicBlock *leave_blk) override;
void gen_raise_trap(uint16_t trap_id, uint16_t cause);
void gen_leave_trap(unsigned lvl);
void gen_wait(unsigned type);
void gen_trap_behavior(BasicBlock *) override;
void gen_trap_check(BasicBlock *bb);
inline Value *gen_reg_load(unsigned i, unsigned level = 0) {
return this->builder.CreateLoad(get_reg_ptr(i), false);
}
inline void gen_set_pc(virt_addr_t pc, unsigned reg_num) {
Value *next_pc_v = this->builder.CreateSExtOrTrunc(this->gen_const(traits<ARCH>::XLEN, pc.val),
this->get_type(traits<ARCH>::XLEN));
this->builder.CreateStore(next_pc_v, get_reg_ptr(reg_num), true);
}
// some compile time constants
// enum { MASK16 = 0b1111110001100011, MASK32 = 0b11111111111100000111000001111111 };
enum { MASK16 = 0b1111111111111111, MASK32 = 0b11111111111100000111000001111111 };
enum { EXTR_MASK16 = MASK16 >> 2, EXTR_MASK32 = MASK32 >> 2 };
enum { LUT_SIZE = 1 << util::bit_count(EXTR_MASK32), LUT_SIZE_C = 1 << util::bit_count(EXTR_MASK16) };
using this_class = vm_impl<ARCH>;
using compile_func = std::tuple<continuation_e, BasicBlock *> (this_class::*)(virt_addr_t &pc,
code_word_t instr,
BasicBlock *bb);
std::array<compile_func, LUT_SIZE> lut;
std::array<compile_func, LUT_SIZE_C> lut_00, lut_01, lut_10;
std::array<compile_func, LUT_SIZE> lut_11;
std::array<compile_func *, 4> qlut;
std::array<const uint32_t, 4> lutmasks = {{EXTR_MASK16, EXTR_MASK16, EXTR_MASK16, EXTR_MASK32}};
void expand_bit_mask(int pos, uint32_t mask, uint32_t value, uint32_t valid, uint32_t idx, compile_func lut[],
compile_func f) {
if (pos < 0) {
lut[idx] = f;
} else {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, idx, lut, f);
} else {
if ((valid & bitmask) == 0) {
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1), lut, f);
expand_bit_mask(pos - 1, mask, value, valid, (idx << 1) + 1, lut, f);
} else {
auto new_val = idx << 1;
if ((value & bitmask) != 0) new_val++;
expand_bit_mask(pos - 1, mask, value, valid, new_val, lut, f);
}
}
}
}
inline uint32_t extract_fields(uint32_t val) { return extract_fields(29, val >> 2, lutmasks[val & 0x3], 0); }
uint32_t extract_fields(int pos, uint32_t val, uint32_t mask, uint32_t lut_val) {
if (pos >= 0) {
auto bitmask = 1UL << pos;
if ((mask & bitmask) == 0) {
lut_val = extract_fields(pos - 1, val, mask, lut_val);
} else {
auto new_val = lut_val << 1;
if ((val & bitmask) != 0) new_val++;
lut_val = extract_fields(pos - 1, val, mask, new_val);
}
}
return lut_val;
}
private:
/****************************************************************************
* start opcode definitions
****************************************************************************/
struct InstructionDesriptor {
size_t length;
uint32_t value;
uint32_t mask;
compile_func op;
};
const std::array<InstructionDesriptor, ${instructions.size}> instr_descr = {{
/* entries are: size, valid value, valid mask, function ptr */<%instructions.each{instr -> %>
/* instruction ${instr.instruction.name} */
{${instr.length}, ${instr.value}, ${instr.mask}, &this_class::__${generator.functionName(instr.name)}},<%}%>
}};
/* instruction definitions */<%instructions.eachWithIndex{instr, idx -> %>
/* instruction ${idx}: ${instr.name} */
std::tuple<continuation_e, BasicBlock*> __${generator.functionName(instr.name)}(virt_addr_t& pc, code_word_t instr, BasicBlock* bb){<%instr.code.eachLine{%>
${it}<%}%>
}
<%}%>
/****************************************************************************
* end opcode definitions
****************************************************************************/
std::tuple<continuation_e, BasicBlock *> illegal_intruction(virt_addr_t &pc, code_word_t instr, BasicBlock *bb) {
this->gen_sync(iss::PRE_SYNC, instr_descr.size());
this->builder.CreateStore(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), true),
get_reg_ptr(traits<ARCH>::PC), true);
this->builder.CreateStore(
this->builder.CreateAdd(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::ICOUNT), true),
this->gen_const(64U, 1)),
get_reg_ptr(traits<ARCH>::ICOUNT), true);
pc = pc + ((instr & 3) == 3 ? 4 : 2);
this->gen_raise_trap(0, 2); // illegal instruction trap
this->gen_sync(iss::POST_SYNC, instr_descr.size());
this->gen_trap_check(this->leave_blk);
return std::make_tuple(BRANCH, nullptr);
}
};
template <typename CODE_WORD> void debug_fn(CODE_WORD insn) {
volatile CODE_WORD x = insn;
insn = 2 * x;
}
template <typename ARCH> vm_impl<ARCH>::vm_impl() { this(new ARCH()); }
template <typename ARCH>
vm_impl<ARCH>::vm_impl(ARCH &core, unsigned core_id, unsigned cluster_id)
: vm_base<ARCH>(core, core_id, cluster_id) {
qlut[0] = lut_00.data();
qlut[1] = lut_01.data();
qlut[2] = lut_10.data();
qlut[3] = lut_11.data();
for (auto instr : instr_descr) {
auto quantrant = instr.value & 0x3;
expand_bit_mask(29, lutmasks[quantrant], instr.value >> 2, instr.mask >> 2, 0, qlut[quantrant], instr.op);
}
}
template <typename ARCH>
std::tuple<continuation_e, BasicBlock *>
vm_impl<ARCH>::gen_single_inst_behavior(virt_addr_t &pc, unsigned int &inst_cnt, BasicBlock *this_block) {
// we fetch at max 4 byte, alignment is 2
enum {TRAP_ID=1<<16};
code_word_t insn = 0;
const typename traits<ARCH>::addr_t upper_bits = ~traits<ARCH>::PGMASK;
phys_addr_t paddr(pc);
auto *const data = (uint8_t *)&insn;
paddr = this->core.v2p(pc);
if ((pc.val & upper_bits) != ((pc.val + 2) & upper_bits)) { // we may cross a page boundary
auto res = this->core.read(paddr, 2, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
if ((insn & 0x3) == 0x3) { // this is a 32bit instruction
res = this->core.read(this->core.v2p(pc + 2), 2, data + 2);
}
} else {
auto res = this->core.read(paddr, 4, data);
if (res != iss::Ok) throw trap_access(TRAP_ID, pc.val);
}
if (insn == 0x0000006f || (insn&0xffff)==0xa001) throw simulation_stopped(0); // 'J 0' or 'C.J 0'
// curr pc on stack
++inst_cnt;
auto lut_val = extract_fields(insn);
auto f = qlut[insn & 0x3][lut_val];
if (f == nullptr) {
f = &this_class::illegal_intruction;
}
return (this->*f)(pc, insn, this_block);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_behavior(BasicBlock *leave_blk) {
this->builder.SetInsertPoint(leave_blk);
this->builder.CreateRet(this->builder.CreateLoad(get_reg_ptr(arch::traits<ARCH>::NEXT_PC), false));
}
template <typename ARCH> void vm_impl<ARCH>::gen_raise_trap(uint16_t trap_id, uint16_t cause) {
auto *TRAP_val = this->gen_const(32, 0x80 << 24 | (cause << 16) | trap_id);
this->builder.CreateStore(TRAP_val, get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_leave_trap(unsigned lvl) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, lvl)) };
this->builder.CreateCall(this->mod->getFunction("leave_trap"), args);
auto *PC_val = this->gen_read_mem(traits<ARCH>::CSR, (lvl << 8) + 0x41, traits<ARCH>::XLEN / 8);
this->builder.CreateStore(PC_val, get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()), get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
}
template <typename ARCH> void vm_impl<ARCH>::gen_wait(unsigned type) {
std::vector<Value *> args{ this->core_ptr, ConstantInt::get(getContext(), APInt(64, type)) };
this->builder.CreateCall(this->mod->getFunction("wait"), args);
}
template <typename ARCH> void vm_impl<ARCH>::gen_trap_behavior(BasicBlock *trap_blk) {
this->builder.SetInsertPoint(trap_blk);
auto *trap_state_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::TRAP_STATE), true);
this->builder.CreateStore(this->gen_const(32U, std::numeric_limits<uint32_t>::max()),
get_reg_ptr(traits<ARCH>::LAST_BRANCH), false);
std::vector<Value *> args{this->core_ptr, this->adj_to64(trap_state_val),
this->adj_to64(this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::PC), false))};
this->builder.CreateCall(this->mod->getFunction("enter_trap"), args);
auto *trap_addr_val = this->builder.CreateLoad(get_reg_ptr(traits<ARCH>::NEXT_PC), false);
this->builder.CreateRet(trap_addr_val);
}
template <typename ARCH> inline void vm_impl<ARCH>::gen_trap_check(BasicBlock *bb) {
auto *v = this->builder.CreateLoad(get_reg_ptr(arch::traits<ARCH>::TRAP_STATE), true);
this->gen_cond_branch(this->builder.CreateICmp(
ICmpInst::ICMP_EQ, v,
ConstantInt::get(getContext(), APInt(v->getType()->getIntegerBitWidth(), 0))),
bb, this->trap_blk, 1);
}
} // namespace ${coreDef.name.toLowerCase()}
template <>
std::unique_ptr<vm_if> create<arch::${coreDef.name.toLowerCase()}>(arch::${coreDef.name.toLowerCase()} *core, unsigned short port, bool dump) {
auto ret = new ${coreDef.name.toLowerCase()}::vm_impl<arch::${coreDef.name.toLowerCase()}>(*core, dump);
if (port != 0) debugger::server<debugger::gdb_session>::run_server(ret, port);
return std::unique_ptr<vm_if>(ret);
}
} // namespace iss