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https://opencores.org/ocsvn/eco32/eco32/trunk
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[/] [eco32/] [trunk/] [sim/] [cpu.c] - Rev 128
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/* * cpu.c -- CPU simulation */ #include <stdio.h> #include <stdlib.h> #include <string.h> #include <setjmp.h> #include "common.h" #include "console.h" #include "error.h" #include "except.h" #include "instr.h" #include "cpu.h" #include "mmu.h" #include "timer.h" /**************************************************************/ #define RR(n) r[n] #define WR(n,d) ((void) ((n) != 0 ? r[n] = (d) : (d))) #define V (psw & PSW_V) #define UM (psw & PSW_UM) #define PUM (psw & PSW_PUM) #define OUM (psw & PSW_OUM) #define IE (psw & PSW_IE) #define PIE (psw & PSW_PIE) #define OIE (psw & PSW_OIE) /**************************************************************/ static Bool debugIRQ = false; /* set to true if debugging IRQs */ static Word pc; /* program counter */ static Word psw; /* processor status word */ static Word r[32]; /* general purpose registers */ static unsigned irqPending; /* one bit for each pending IRQ */ static Bool breakSet; /* breakpoint set if true */ static Word breakAddr; /* if breakSet, this is where */ static Word total; /* counts total number of instrs */ static Bool run; /* CPU runs continuously if true */ static Word startAddr; /* start of ROM (or start of RAM, */ /* in case a program was loaded) */ /**************************************************************/ static void handleInterrupts(void) { unsigned irqMask; unsigned irqSeen; int priority; /* handle exceptions and interrupts */ if (irqPending == 0) { /* no exception or interrupt pending */ return; } /* at least one exception or interrupt is pending */ irqMask = ~PSW_IRQ_MASK | (psw & PSW_IRQ_MASK); if (debugIRQ) { cPrintf("**** IRQ = 0x%08X ****\n", irqPending); cPrintf("**** MASK = 0x%08X ****\n", irqMask); } irqSeen = irqPending & irqMask; if (irqSeen == 0) { /* none that gets through */ return; } /* determine the one with the highest priority */ for (priority = 31; priority >= 0; priority--) { if ((irqSeen & ((unsigned) 1 << priority)) != 0) { /* highest priority among visible ones found */ break; } } /* acknowledge exception, or interrupt if enabled */ if (priority >= 16 || IE != 0) { if (priority >= 16) { /* clear corresponding bit in irqPending vector */ /* only done for exceptions, since interrupts are level-sensitive */ irqPending &= ~((unsigned) 1 << priority); } /* copy and reset interrupt enable bit in PSW */ if (PIE != 0) { psw |= PSW_OIE; } else { psw &= ~PSW_OIE; } if (IE != 0) { psw |= PSW_PIE; } else { psw &= ~PSW_PIE; } psw &= ~PSW_IE; /* copy and reset user mode enable bit in PSW */ if (PUM != 0) { psw |= PSW_OUM; } else { psw &= ~PSW_OUM; } if (UM != 0) { psw |= PSW_PUM; } else { psw &= ~PSW_PUM; } psw &= ~PSW_UM; /* reflect priority in PSW */ psw &= ~PSW_PRIO_MASK; psw |= priority << PSW_PRIO_SHFT; /* save interrupt return address and start service routine */ WR(30, pc); if (V == 0) { /* exceptions and interrupts are vectored to ROM */ pc = 0xC0000000 | ROM_BASE; } else { /* exceptions and interrupts are vectored to RAM */ pc = 0xC0000000; } if (priority == EXC_TLB_MISS && (mmuGetBadAddr() & 0x80000000) == 0) { /* user TLB miss exception */ pc |= 0x00000008; } else { /* any other exception or interrupt */ pc |= 0x00000004; } } } static void execNextInstruction(void) { Word instr; Word next; int op, reg1, reg2, reg3; Half immed; Word offset; int scnt; Word smsk; Word aux; /* count the instruction */ total++; /* fetch the instruction */ instr = mmuReadWord(pc, UM); /* decode the instruction */ op = (instr >> 26) & 0x3F; reg1 = (instr >> 21) & 0x1F; reg2 = (instr >> 16) & 0x1F; reg3 = (instr >> 11) & 0x1F; immed = instr & 0x0000FFFF; offset = instr & 0x03FFFFFF; next = pc + 4; /* execute the instruction */ switch (op) { case OP_ADD: WR(reg3, (signed int) RR(reg1) + (signed int) RR(reg2)); break; case OP_ADDI: WR(reg2, (signed int) RR(reg1) + (signed int) SEXT16(immed)); break; case OP_SUB: WR(reg3, (signed int) RR(reg1) - (signed int) RR(reg2)); break; case OP_SUBI: WR(reg2, (signed int) RR(reg1) - (signed int) SEXT16(immed)); break; case OP_MUL: WR(reg3, (signed int) RR(reg1) * (signed int) RR(reg2)); break; case OP_MULI: WR(reg2, (signed int) RR(reg1) * (signed int) SEXT16(immed)); break; case OP_MULU: WR(reg3, RR(reg1) * RR(reg2)); break; case OP_MULUI: WR(reg2, RR(reg1) * ZEXT16(immed)); break; case OP_DIV: if (RR(reg2) == 0) { throwException(EXC_DIVIDE); } WR(reg3, (signed int) RR(reg1) / (signed int) RR(reg2)); break; case OP_DIVI: if (SEXT16(immed) == 0) { throwException(EXC_DIVIDE); } WR(reg2, (signed int) RR(reg1) / (signed int) SEXT16(immed)); break; case OP_DIVU: if (RR(reg2) == 0) { throwException(EXC_DIVIDE); } WR(reg3, RR(reg1) / RR(reg2)); break; case OP_DIVUI: if (SEXT16(immed) == 0) { throwException(EXC_DIVIDE); } WR(reg2, RR(reg1) / ZEXT16(immed)); break; case OP_REM: if (RR(reg2) == 0) { throwException(EXC_DIVIDE); } WR(reg3, (signed int) RR(reg1) % (signed int) RR(reg2)); break; case OP_REMI: if (SEXT16(immed) == 0) { throwException(EXC_DIVIDE); } WR(reg2, (signed int) RR(reg1) % (signed int) SEXT16(immed)); break; case OP_REMU: if (RR(reg2) == 0) { throwException(EXC_DIVIDE); } WR(reg3, RR(reg1) % RR(reg2)); break; case OP_REMUI: if (SEXT16(immed) == 0) { throwException(EXC_DIVIDE); } WR(reg2, RR(reg1) % ZEXT16(immed)); break; case OP_AND: WR(reg3, RR(reg1) & RR(reg2)); break; case OP_ANDI: WR(reg2, RR(reg1) & ZEXT16(immed)); break; case OP_OR: WR(reg3, RR(reg1) | RR(reg2)); break; case OP_ORI: WR(reg2, RR(reg1) | ZEXT16(immed)); break; case OP_XOR: WR(reg3, RR(reg1) ^ RR(reg2)); break; case OP_XORI: WR(reg2, RR(reg1) ^ ZEXT16(immed)); break; case OP_XNOR: WR(reg3, ~(RR(reg1) ^ RR(reg2))); break; case OP_XNORI: WR(reg2, ~(RR(reg1) ^ ZEXT16(immed))); break; case OP_SLL: scnt = RR(reg2) & 0x1F; WR(reg3, RR(reg1) << scnt); break; case OP_SLLI: scnt = immed & 0x1F; WR(reg2, RR(reg1) << scnt); break; case OP_SLR: scnt = RR(reg2) & 0x1F; WR(reg3, RR(reg1) >> scnt); break; case OP_SLRI: scnt = immed & 0x1F; WR(reg2, RR(reg1) >> scnt); break; case OP_SAR: scnt = RR(reg2) & 0x1F; smsk = (RR(reg1) & 0x80000000 ? ~(((Word) 0xFFFFFFFF) >> scnt) : 0); WR(reg3, smsk | (RR(reg1) >> scnt)); break; case OP_SARI: scnt = immed & 0x1F; smsk = (RR(reg1) & 0x80000000 ? ~(((Word) 0xFFFFFFFF) >> scnt) : 0); WR(reg2, smsk | (RR(reg1) >> scnt)); break; case OP_LDHI: WR(reg2, ZEXT16(immed) << 16); break; case OP_BEQ: if (RR(reg1) == RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BNE: if (RR(reg1) != RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BLE: if ((signed int) RR(reg1) <= (signed int) RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BLEU: if (RR(reg1) <= RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BLT: if ((signed int) RR(reg1) < (signed int) RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BLTU: if (RR(reg1) < RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BGE: if ((signed int) RR(reg1) >= (signed int) RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BGEU: if (RR(reg1) >= RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BGT: if ((signed int) RR(reg1) > (signed int) RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_BGTU: if (RR(reg1) > RR(reg2)) { next += SEXT16(immed) << 2; } break; case OP_J: next += SEXT26(offset) << 2; break; case OP_JR: next = RR(reg1); break; case OP_JAL: WR(31, next); next += SEXT26(offset) << 2; break; case OP_JALR: aux = RR(reg1); WR(31, next); next = aux; break; case OP_TRAP: throwException(EXC_TRAP); break; case OP_RFX: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } if (PIE != 0) { psw |= PSW_IE; } else { psw &= ~PSW_IE; } if (OIE != 0) { psw |= PSW_PIE; } else { psw &= ~PSW_PIE; } if (PUM != 0) { psw |= PSW_UM; } else { psw &= ~PSW_UM; } if (OUM != 0) { psw |= PSW_PUM; } else { psw &= ~PSW_PUM; } next = RR(30); break; case OP_LDW: WR(reg2, mmuReadWord(RR(reg1) + SEXT16(immed), UM)); break; case OP_LDH: WR(reg2, (signed int) (signed short) mmuReadHalf(RR(reg1) + SEXT16(immed), UM)); break; case OP_LDHU: WR(reg2, mmuReadHalf(RR(reg1) + SEXT16(immed), UM)); break; case OP_LDB: WR(reg2, (signed int) (signed char) mmuReadByte(RR(reg1) + SEXT16(immed), UM)); break; case OP_LDBU: WR(reg2, mmuReadByte(RR(reg1) + SEXT16(immed), UM)); break; case OP_STW: mmuWriteWord(RR(reg1) + SEXT16(immed), RR(reg2), UM); break; case OP_STH: mmuWriteHalf(RR(reg1) + SEXT16(immed), RR(reg2), UM); break; case OP_STB: mmuWriteByte(RR(reg1) + SEXT16(immed), RR(reg2), UM); break; case OP_MVFS: switch (immed) { case 0: WR(reg2, psw); break; case 1: WR(reg2, mmuGetIndex()); break; case 2: WR(reg2, mmuGetEntryHi()); break; case 3: WR(reg2, mmuGetEntryLo()); break; case 4: WR(reg2, mmuGetBadAddr()); break; default: throwException(EXC_ILL_INSTRCT); break; } break; case OP_MVTS: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } switch (immed) { case 0: psw = RR(reg2); break; case 1: mmuSetIndex(RR(reg2)); break; case 2: mmuSetEntryHi(RR(reg2)); break; case 3: mmuSetEntryLo(RR(reg2)); break; case 4: mmuSetBadAddr(RR(reg2)); break; default: throwException(EXC_ILL_INSTRCT); break; } break; case OP_TBS: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } mmuTbs(); break; case OP_TBWR: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } mmuTbwr(); break; case OP_TBRI: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } mmuTbri(); break; case OP_TBWI: if (UM != 0) { throwException(EXC_PRV_INSTRCT); } mmuTbwi(); break; default: throwException(EXC_ILL_INSTRCT); break; } /* update PC */ pc = next; } /**************************************************************/ Word cpuGetPC(void) { return pc; } void cpuSetPC(Word addr) { pc = addr; } Word cpuGetReg(int regnum) { return RR(regnum & 0x1F); } void cpuSetReg(int regnum, Word value) { WR(regnum & 0x1F, value); } Word cpuGetPSW(void) { return psw; } void cpuSetPSW(Word value) { psw = value; } Word cpuGetIRQ(void) { return irqPending; } Bool cpuTestBreak(void) { return breakSet; } Word cpuGetBreak(void) { return breakAddr; } void cpuSetBreak(Word addr) { breakAddr = addr; breakSet = true; } void cpuResetBreak(void) { breakSet = false; } Word cpuGetTotal(void) { return total; } void cpuStep(void) { jmp_buf myEnvironment; int exception; exception = setjmp(myEnvironment); if (exception == 0) { /* initialization */ pushEnvironment(&myEnvironment); timerTick(); execNextInstruction(); handleInterrupts(); } else { /* an exception was thrown */ cpuSetInterrupt(exception); handleInterrupts(); } popEnvironment(); } void cpuRun(void) { jmp_buf myEnvironment; int exception; run = true; exception = setjmp(myEnvironment); if (exception == 0) { /* initialization */ pushEnvironment(&myEnvironment); } else { /* an exception was thrown */ cpuSetInterrupt(exception); handleInterrupts(); if (breakSet && pc == breakAddr) { run = false; } } while (run) { timerTick(); execNextInstruction(); handleInterrupts(); if (breakSet && pc == breakAddr) { run = false; } } popEnvironment(); } void cpuHalt(void) { run = false; } void cpuSetInterrupt(int priority) { irqPending |= ((unsigned) 1 << priority); } void cpuResetInterrupt(int priority) { irqPending &= ~((unsigned) 1 << priority); } void cpuReset(void) { int i; cPrintf("Resetting CPU...\n"); /* most registers are in a random state */ for (i = 1; i < 32; i++) { r[i] = rand(); } /* but not all */ pc = startAddr; r[0] = 0; psw = 0; /* reset simulator control variables */ irqPending = 0; total = 0; } void cpuInit(Word initialPC) { startAddr = initialPC; cpuReset(); } void cpuExit(void) { }
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