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[/] [openrisc/] [trunk/] [or1ksim/] [cpu/] [dlx/] [execute.c] - Rev 318
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/* execute.c -- DLX dependent simulation Copyright (C) 1999 Damjan Lampret, lampret@opencores.org This file is part of OpenRISC 1000 Architectural Simulator. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ /* Most of the DLX simulation is done in this file. */ #include <stdlib.h> #include <stdio.h> #include <string.h> #include "arch.h" #include "branch_predict.h" #include "abstract.h" #include "parse.h" #include "trace.h" #include "execute.h" #include "stats.h" /* General purpose registers. */ machword reg[MAX_GPRS]; /* Instruction queue */ struct iqueue_entry iqueue[20]; /* Benchmark multi issue execution */ int multissue[20]; int supercycles; /* Load and store stalls */ int loadcycles, storecycles; /* Result forwarding stall cycles */ int forwardingcycles; /* Completition queue */ struct icomplet_entry icomplet[20]; /* Program counter */ unsigned long pc; /* Temporary program counter */ unsigned long pctemp; /* Cycles counts fetch stages */ int cycles; /* Implementation specific. Get an actual value of a specific register. */ machword eval_reg(char *regstr) { int regno; regno = atoi(regstr + 1); if (regno < MAX_GPRS) return reg[regno]; else { PRINTF("\nABORT: read out of registers\n"); cont_run = 0; return 0; } } /* Implementation specific. Set a specific register with value. */ void set_reg32(char *regstr, unsigned long value) { int regno; regno = atoi(regstr + 1); if (regno == 0) /* gpr0 is always zero */ value = 0; if (regno < MAX_GPRS) reg[regno] = value; else { PRINTF("\nABORT: write out of registers\n"); cont_run = 0; } return; } /* Does srcoperand depend on computation of dstoperand? Return non-zero if yes. Cycle t Cycle t+1 dst: irrelevant src: immediate always 0 dst: reg1 direct src: reg2 direct 0 if reg1 != reg2 dst: reg1 disp src: reg2 direct always 0 dst: reg1 direct src: reg2 disp 0 if reg1 != reg2 dst: reg1 disp src: reg2 disp always 1 (store must finish before load) */ int depend_operands(char *dstoperand, char *srcoperand) { char dst[OPERANDNAME_LEN]; char src[OPERANDNAME_LEN]; if (!srcoperand) return 0; if (!dstoperand) return 0; strcpy(dst, dstoperand); strcpy(src, srcoperand); if (*src == '#') /* immediate */ return 0; else if (!strstr(src, "(")) if (*src == 'r') { /* src: reg direct */ if (!strstr(dst, "(")) if (*dst == 'r') if (strcmp(dst, src) == 0) return 1; /* dst: reg direct */ else return 0; /* dst: reg direct */ else return 0; /* dst: addr */ else return 0; /* dst: reg disp */ } else return 0; /* src: addr */ else { /* src: register disp */ char *regstr; regstr = strstr(src, "(r") + 1; /* regstr == "rXX)" */ *strstr(regstr, ")") = '\0'; /* regstr == "rXX" */ if (!strstr(dst, "(")) if (*dst == 'r') if (strcmp(dst, regstr) == 0) return 1; /* dst: reg direct */ else return 0; /* dst: reg direct */ else return 0; /* dst: addr */ else return 1; /* dst: reg disp */ } return 0; } /* Implementation specific. Get an actual value represented by operand (register direct, register indirect (with displacement), immediate etc.). #n - immediate n rXX - register direct XX - relative or absolute address (labels) n(XX) - register indirect (with displacement) */ machword eval_operand(char *srcoperand,int* breakpoint) { char operand[OPERANDNAME_LEN]; strcpy(operand, srcoperand); if (*operand == '#') /* immediate */ return strtoul(&operand[1], NULL, 0); else if (!strstr(operand, "(")) /* not indirect but ...*/ if (*operand == 'r') /* ... register direct */ return eval_reg(operand); else /* ... rel. or abs. address */ return eval_label(operand); else { /* register indirect */ int disp; /* with possible displacement */ char *regstr; unsigned int memaddr; disp = atoi(operand); /* operand == "nn(rXX)" */ regstr = strstr(operand, "(r") + 1; /* regstr == "rXX)" */ *strstr(regstr, ")") = '\0'; /* regstr == "rXX" */ memaddr = eval_reg(regstr) + disp; return eval_mem32(memaddr,breakpoint); } return 0; } /* Implementation specific. Set destination operand (register direct, register indirect (with displacement) with value. */ void set_operand(char *dstoperand, unsigned long value,int* breakpoint) { char operand[OPERANDNAME_LEN]; strcpy(operand, dstoperand); if (*operand == '#') /* immediate */ PRINTF("INTERNAL ERROR: Can't set immediate operand.\n"); else if (!strstr(operand, "(")) /* not indirect but ...*/ if (*operand == 'r') /* ... register direct */ set_reg32(operand, value); else /* ... rel. or abs. address */ PRINTF("INTERNAL ERROR: Can't set addr operand.\n"); else { /* register indirect */ int disp; /* with possible displacement */ char *regstr; unsigned int memaddr; disp = atoi(operand); /* operand == "nn(rXX)" */ regstr = strstr(operand, "(r") + 1; /* regstr == "rXX)" */ *strstr(regstr, ")") = '\0'; /* regstr == "rXX" */ memaddr = eval_reg(regstr) + disp; set_mem32(memaddr, value, breakpoint); } return; } void reset() { cycles = 0; supercycles = 0; loadcycles = 0; storecycles = 0; forwardingcycles = 0; memset(reg, 0, sizeof(reg)); memset(iqueue, 0, sizeof(iqueue)); memset(icomplet, 0, sizeof(icomplet)); pctemp = eval_label("_main"); pc = pctemp; set_reg32(STACK_REG , MEMORY_LEN - STACK_SIZE); } void fetch() { /* Cycles after reset. */ cycles++; /* Simulate instruction cache */ ic_simulate(pc); /* Fetch instruction. */ strcpy(iqueue[0].insn, mem[pc].insn->insn); strcpy(iqueue[0].op1, mem[pc].insn->op1); strcpy(iqueue[0].op2, mem[pc].insn->op2); strcpy(iqueue[0].op3, mem[pc].insn->op3); iqueue[0].insn_addr = pc; iqueue[0].dependdst = NULL; iqueue[0].dependsrc1 = NULL; iqueue[0].dependsrc2 = NULL; /* Increment program counter. */ pc = pctemp; pctemp += 4; /* Check for breakpoint. */ if (mem[pc].brk) cont_run = 0; /* Breakpoint set. */ return; } void decode(struct iqueue_entry *cur) { int breakpoint = 0; cur->dependdst = cur->op1; cur->dependsrc1 = cur->op2; /* for calculating register */ cur->dependsrc2 = cur->op3; /* dependency */ cur->func_unit = unknown; if (strcmp(cur->insn, "sw") == 0) { cur->func_unit = store; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "sb") == 0) { cur->func_unit = store; set_operand(cur->op1, (eval_operand(cur->op2,&breakpoint) << 24) + (eval_operand(cur->op1,&breakpoint) & 0xffffff),&breakpoint); } else if (strcmp(cur->insn, "sh") == 0) { cur->func_unit = store; set_operand(cur->op1, (eval_operand(cur->op2,&breakpoint) << 16) + (eval_operand(cur->op1,&breakpoint) & 0xffff),&breakpoint); } else if (strcmp(cur->insn, "lw") == 0) { cur->func_unit = load; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "lb") == 0) { signed char temp = (eval_operand(cur->op2,&breakpoint) >> 24); cur->func_unit = load; set_operand(cur->op1, temp,&breakpoint); } else if (strcmp(cur->insn, "lbu") == 0) { unsigned char temp = (eval_operand(cur->op2,&breakpoint) >> 24); cur->func_unit = load; set_operand(cur->op1, temp,&breakpoint); } else if (strcmp(cur->insn, "lh") == 0) { signed short temp = (eval_operand(cur->op2,&breakpoint) >> 16); cur->func_unit = load; set_operand(cur->op1, temp,&breakpoint); } else if (strcmp(cur->insn, "lhu") == 0) { unsigned short temp = (eval_operand(cur->op2,&breakpoint) >> 16); cur->func_unit = load; set_operand(cur->op1, temp,&breakpoint); } else if (strcmp(cur->insn, "lwi") == 0) { cur->func_unit = movimm; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "lhi") == 0) { cur->func_unit = movimm; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) << 16,&breakpoint); } else if (strcmp(cur->insn, "and") == 0) { cur->func_unit = arith; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) & eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "andi") == 0) { cur->func_unit = arith; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) & eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "or") == 0) { cur->func_unit = arith; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) | eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "ori") == 0) { cur->func_unit = arith; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) | eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "xor") == 0) { cur->func_unit = arith; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) ^ eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "add") == 0) { signed long temp3, temp2, temp1; signed char temp4; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 + temp3; set_operand(cur->op1, temp1,&breakpoint); temp4 = temp1; if (temp4 == temp1) mstats.byteadd++; } else if (strcmp(cur->insn, "addi") == 0) { signed long temp3, temp2, temp1; signed char temp4; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 + temp3; set_operand(cur->op1, temp1,&breakpoint); temp4 = temp1; if (temp4 == temp1) mstats.byteadd++; } else if (strcmp(cur->insn, "addui") == 0) { unsigned long temp3, temp2, temp1; unsigned char temp4; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 + temp3; set_operand(cur->op1, temp1,&breakpoint); temp4 = temp1; if (temp4 == temp1) mstats.byteadd++; } else if (strcmp(cur->insn, "sub") == 0) { signed long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 - temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "subui") == 0) { unsigned long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 - temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "subi") == 0) { signed long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 - temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "mul") == 0) { signed long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 * temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "div") == 0) { signed long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 / temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "divu") == 0) { unsigned long temp3, temp2, temp1; cur->func_unit = arith; temp3 = eval_operand(cur->op3,&breakpoint); temp2 = eval_operand(cur->op2,&breakpoint); temp1 = temp2 / temp3; set_operand(cur->op1, temp1,&breakpoint); } else if (strcmp(cur->insn, "slli") == 0) { cur->func_unit = shift; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) << eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "sll") == 0) { cur->func_unit = shift; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) << eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "srl") == 0) { cur->func_unit = shift; set_operand(cur->op1, eval_operand(cur->op2,&breakpoint) >> eval_operand(cur->op3,&breakpoint),&breakpoint); } else if (strcmp(cur->insn, "srai") == 0) { cur->func_unit = shift; set_operand(cur->op1, (signed)eval_operand(cur->op2,&breakpoint) / (1 << eval_operand(cur->op3,&breakpoint)),&breakpoint); } else if (strcmp(cur->insn, "sra") == 0) { cur->func_unit = shift; set_operand(cur->op1, (signed)eval_operand(cur->op2,&breakpoint) / (1 << eval_operand(cur->op3,&breakpoint)),&breakpoint); } else if (strcmp(cur->insn, "jal") == 0) { cur->func_unit = jump; pctemp = eval_operand(cur->op1,&breakpoint); set_reg32(LINK_REG, pc + 4); } else if (strcmp(cur->insn, "jr") == 0) { cur->func_unit = jump; cur->dependsrc1 = cur->op1; pctemp = eval_operand(cur->op1,&breakpoint); } else if (strcmp(cur->insn, "j") == 0) { cur->func_unit = jump; pctemp = eval_operand(cur->op1,&breakpoint); } else if (strcmp(cur->insn, "nop") == 0) { cur->func_unit = nop; } else if (strcmp(cur->insn, "beqz") == 0) { cur->func_unit = branch; cur->dependsrc1 = cur->op1; if (eval_operand(cur->op1,&breakpoint) == 0) { pctemp = eval_operand(cur->op2,&breakpoint); mstats.beqz.taken++; bpb_update(cur->insn_addr, 1); btic_update(pctemp); } else { mstats.beqz.nottaken++; bpb_update(cur->insn_addr, 0); btic_update(pc); } } else if (strcmp(cur->insn, "bnez") == 0) { cur->func_unit = branch; cur->dependsrc1 = cur->op1; if (eval_operand(cur->op1,&breakpoint) != 0) { pctemp = eval_operand(cur->op2,&breakpoint); mstats.bnez.taken++; bpb_update(cur->insn_addr, 1); btic_update(pctemp); } else { mstats.bnez.nottaken++; bpb_update(cur->insn_addr, 0); btic_update(pc); } } else if (strcmp(cur->insn, "seq") == 0) { cur->func_unit = compare; if (eval_operand(cur->op2,&breakpoint) == eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "snei") == 0) { cur->func_unit = compare; if (eval_operand(cur->op2,&breakpoint) != eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sne") == 0) { cur->func_unit = compare; if (eval_operand(cur->op2,&breakpoint) != eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "seqi") == 0) { cur->func_unit = compare; if (eval_operand(cur->op2,&breakpoint) == eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sgt") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) > (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sgtui") == 0) { cur->func_unit = compare; if ((unsigned)eval_operand(cur->op2,&breakpoint) > (unsigned)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sgeui") == 0) { cur->func_unit = compare; if ((unsigned)eval_operand(cur->op2,&breakpoint) >= (unsigned)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sgei") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) >= (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sgti") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) > (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "slt") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) < (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "slti") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) < (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sle") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) <= (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "slei") == 0) { cur->func_unit = compare; if ((signed)eval_operand(cur->op2,&breakpoint) <= (signed)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sleui") == 0) { cur->func_unit = compare; if ((unsigned)eval_operand(cur->op2,&breakpoint) <= (unsigned)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "sleu") == 0) { cur->func_unit = compare; if ((unsigned)eval_operand(cur->op2,&breakpoint) <= (unsigned)eval_operand(cur->op3,&breakpoint)) set_operand(cur->op1, 1,&breakpoint); else set_operand(cur->op1, 0,&breakpoint); } else if (strcmp(cur->insn, "simrdtsc") == 0) { set_operand(cur->op1, cycles+loadcycles+storecycles+forwardingcycles,&breakpoint); } else if (strcmp(cur->insn, "simprintf") == 0) { unsigned long stackaddr; stackaddr = eval_reg(FRAME_REG); simprintf(stackaddr, 0); /* PRINTF("simprintf %x %x %x\n", stackaddr, fmtaddr, args); */ } else { PRINTF("\nABORT: illegal opcode %s ", cur->insn); PRINTF("at %.8lx\n", cur->insn_addr); cont_run = 0; } /* Dynamic, dependency stats. */ adddstats(icomplet[0].insn, iqueue[0].insn, 1, check_depend()); /* Dynamic, functional units stats. */ addfstats(icomplet[0].func_unit, iqueue[0].func_unit, 1, check_depend()); /* Dynamic, single stats. */ addsstats(iqueue[0].insn, 1, 0); if (cur->func_unit == store) storecycles += 0; if (cur->func_unit == load) loadcycles += 0; if (check_depend()) forwardingcycles += 0; /* Pseudo multiple issue benchmark */ if ((multissue[cur->func_unit] == 0) || (check_depend())) { int i; for (i = 0; i < 20; i++) multissue[i] = 9; supercycles++; multissue[arith] = 9; multissue[store] = 9; multissue[load] = 9; } multissue[cur->func_unit]--; return; } void execute() { int i; /* Here comes real execution someday... */ /* Instruction waits in completition buffer until retired. */ strcpy(icomplet[0].insn, iqueue[0].insn); strcpy(icomplet[0].op1, iqueue[0].op1); strcpy(icomplet[0].op2, iqueue[0].op2); strcpy(icomplet[0].op3, iqueue[0].op3); icomplet[0].func_unit = iqueue[0].func_unit; icomplet[0].insn_addr = iqueue[0].insn_addr; if (iqueue[0].dependdst == iqueue[0].op1) icomplet[0].dependdst = icomplet[0].op1; else if (iqueue[0].dependdst == iqueue[0].op2) icomplet[0].dependdst = icomplet[0].op2; else if (iqueue[0].dependdst == iqueue[0].op3) icomplet[0].dependdst = icomplet[0].op3; else icomplet[0].dependdst = NULL; if (iqueue[0].dependsrc1 == iqueue[0].op1) icomplet[0].dependsrc1 = icomplet[0].op1; else if (iqueue[0].dependsrc1 == iqueue[0].op2) icomplet[0].dependsrc1 = icomplet[0].op2; else if (iqueue[0].dependsrc1 == iqueue[0].op3) icomplet[0].dependsrc1 = icomplet[0].op3; else icomplet[0].dependsrc1 = NULL; if (iqueue[0].dependsrc2 == iqueue[0].op1) icomplet[0].dependsrc2 = icomplet[0].op1; else if (iqueue[0].dependsrc2 == iqueue[0].op2) icomplet[0].dependsrc2 = icomplet[0].op2; else if (iqueue[0].dependsrc2 == iqueue[0].op3) icomplet[0].dependsrc2 = icomplet[0].op3; else icomplet[0].dependsrc2 = NULL; /* History of execution */ for (i = HISTEXEC_LEN - 1; i; i--) histexec[i] = histexec[i - 1]; histexec[0] = icomplet[0].insn_addr; /* add last insn */ return; } void dumpreg() { int i; PRINTF("\n\nIQ[0]:"); dumpmemory(iqueue[0].insn_addr, iqueue[0].insn_addr + 4); PRINTF(" (just executed)\tCYCLES: %u \nSuperscalar CYCLES: %u\n", cycles, supercycles); PRINTF("Additional LOAD CYCLES: %u STORE CYCLES: %u\n", loadcycles, storecycles); PRINTF("Additional RESULT FORWARDING CYCLES: %u\nPC:", forwardingcycles); dumpmemory(pc, pc + 4); PRINTF(" (next insn)"); for(i = 0; i < MAX_GPRS; i++) { if (i % 4 == 0) PRINTF("\n"); PRINTF("GPR%.2u: %.8lx ", i, reg[i]); } }
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