sim-bpred.c

一个很有名的硬件模拟器。可以模拟CPU

                   "instruction per branch",
                   "sim_num_insn / sim_num_branches", /* format */NULL);

  /* register predictor stats */
  if (pred)
    bpred_reg_stats(pred, sdb);
}

/* initialize the simulator */
void
sim_init(void)
{
  sim_num_refs = 0;

  /* allocate and initialize register file */
  regs_init(&regs);

  /* allocate and initialize memory space */
  mem = mem_create("mem");
  mem_init(mem);
}

/* local machine state accessor */
static char *					/* err str, NULL for no err */
bpred_mstate_obj(FILE *stream,			/* output stream */
		 char *cmd,			/* optional command string */
		 struct regs_t *regs,		/* register to access */
		 struct mem_t *mem)		/* memory to access */
{
  /* just dump intermediate stats */
  sim_print_stats(stream);

  /* no error */
  return NULL;
}

/* load program into simulated state */
void
sim_load_prog(char *fname,		/* program to load */
	      int argc, char **argv,	/* program arguments */
	      char **envp)		/* program environment */
{
  /* load program text and data, set up environment, memory, and regs */
  ld_load_prog(fname, argc, argv, envp, &regs, mem, TRUE);

  /* initialize the DLite debugger */
  dlite_init(md_reg_obj, dlite_mem_obj, bpred_mstate_obj);
}

/* print simulator-specific configuration information */
void
sim_aux_config(FILE *stream)		/* output stream */
{
  /* nothing currently */
}

/* dump simulator-specific auxiliary simulator statistics */
void
sim_aux_stats(FILE *stream)		/* output stream */
{
  /* nada */
}

/* un-initialize simulator-specific state */
void
sim_uninit(void)
{
  /* nada */
}


/*
 * configure the execution engine
 */

/*
 * precise architected register accessors
 */

/* next program counter */
#define SET_NPC(EXPR)		(regs.regs_NPC = (EXPR))

/* target program counter */
#undef  SET_TPC
#define SET_TPC(EXPR)		(target_PC = (EXPR))

/* current program counter */
#define CPC			(regs.regs_PC)

/* general purpose registers */
#define GPR(N)			(regs.regs_R[N])
#define SET_GPR(N,EXPR)		(regs.regs_R[N] = (EXPR))

#if defined(TARGET_PISA)

/* floating point registers, L->word, F->single-prec, D->double-prec */
#define FPR_L(N)		(regs.regs_F.l[(N)])
#define SET_FPR_L(N,EXPR)	(regs.regs_F.l[(N)] = (EXPR))
#define FPR_F(N)		(regs.regs_F.f[(N)])
#define SET_FPR_F(N,EXPR)	(regs.regs_F.f[(N)] = (EXPR))
#define FPR_D(N)		(regs.regs_F.d[(N) >> 1])
#define SET_FPR_D(N,EXPR)	(regs.regs_F.d[(N) >> 1] = (EXPR))

/* miscellaneous register accessors */
#define SET_HI(EXPR)		(regs.regs_C.hi = (EXPR))
#define HI			(regs.regs_C.hi)
#define SET_LO(EXPR)		(regs.regs_C.lo = (EXPR))
#define LO			(regs.regs_C.lo)
#define FCC			(regs.regs_C.fcc)
#define SET_FCC(EXPR)		(regs.regs_C.fcc = (EXPR))

#elif defined(TARGET_ALPHA)

/* floating point registers, L->word, F->single-prec, D->double-prec */
#define FPR_Q(N)		(regs.regs_F.q[N])
#define SET_FPR_Q(N,EXPR)	(regs.regs_F.q[N] = (EXPR))
#define FPR(N)			(regs.regs_F.d[N])
#define SET_FPR(N,EXPR)		(regs.regs_F.d[N] = (EXPR))

/* miscellaneous register accessors */
#define FPCR			(regs.regs_C.fpcr)
#define SET_FPCR(EXPR)		(regs.regs_C.fpcr = (EXPR))
#define UNIQ			(regs.regs_C.uniq)
#define SET_UNIQ(EXPR)		(regs.regs_C.uniq = (EXPR))

#else
#error No ISA target defined...
#endif

/* precise architected memory state help functions */
#define READ_BYTE(SRC, FAULT)						\
  ((FAULT) = md_fault_none, addr = (SRC), MEM_READ_BYTE(mem, addr))
#define READ_HALF(SRC, FAULT)						\
  ((FAULT) = md_fault_none, addr = (SRC), MEM_READ_HALF(mem, addr))
#define READ_WORD(SRC, FAULT)						\
  ((FAULT) = md_fault_none, addr = (SRC), MEM_READ_WORD(mem, addr))
#ifdef HOST_HAS_QWORD
#define READ_QWORD(SRC, FAULT)						\
  ((FAULT) = md_fault_none, addr = (SRC), MEM_READ_QWORD(mem, addr))
#endif /* HOST_HAS_QWORD */

#define WRITE_BYTE(SRC, DST, FAULT)					\
  ((FAULT) = md_fault_none, addr = (DST), MEM_WRITE_BYTE(mem, addr, (SRC)))
#define WRITE_HALF(SRC, DST, FAULT)					\
  ((FAULT) = md_fault_none, addr = (DST), MEM_WRITE_HALF(mem, addr, (SRC)))
#define WRITE_WORD(SRC, DST, FAULT)					\
  ((FAULT) = md_fault_none, addr = (DST), MEM_WRITE_WORD(mem, addr, (SRC)))
#ifdef HOST_HAS_QWORD
#define WRITE_QWORD(SRC, DST, FAULT)					\
  ((FAULT) = md_fault_none, addr = (DST), MEM_WRITE_QWORD(mem, addr, (SRC)))
#endif /* HOST_HAS_QWORD */

/* system call handler macro */
#define SYSCALL(INST)	sys_syscall(&regs, mem_access, mem, INST, TRUE)

/* start simulation, program loaded, processor precise state initialized */
void
sim_main(void)
{
  md_inst_t inst;
  register md_addr_t addr, target_PC = 0;
  enum md_opcode op;
  register int is_write;
  int stack_idx;
  enum md_fault_type fault;

  fprintf(stderr, "sim: ** starting functional simulation w/ predictors **\n");

  /* set up initial default next PC */
  regs.regs_NPC = regs.regs_PC + sizeof(md_inst_t);

  /* check for DLite debugger entry condition */
  if (dlite_check_break(regs.regs_PC, /* no access */0, /* addr */0, 0, 0))
    dlite_main(regs.regs_PC - sizeof(md_inst_t), regs.regs_PC,
	       sim_num_insn, &regs, mem);

  while (TRUE)
    {
      /* maintain $r0 semantics */
      regs.regs_R[MD_REG_ZERO] = 0;
#ifdef TARGET_ALPHA
      regs.regs_F.d[MD_REG_ZERO] = 0.0;
#endif /* TARGET_ALPHA */

      /* get the next instruction to execute */
      MD_FETCH_INST(inst, mem, regs.regs_PC);

      /* keep an instruction count */
      sim_num_insn++;

      /* set default reference address and access mode */
      addr = 0; is_write = FALSE;

      /* set default fault - none */
      fault = md_fault_none;

      /* decode the instruction */
      MD_SET_OPCODE(op, inst);

      /* execute the instruction */
      switch (op)
	{
#define DEFINST(OP,MSK,NAME,OPFORM,RES,FLAGS,O1,O2,I1,I2,I3)		\
	case OP:							\
          SYMCAT(OP,_IMPL);						\
          break;
#define DEFLINK(OP,MSK,NAME,MASK,SHIFT)					\
        case OP:							\
          panic("attempted to execute a linking opcode");
#define CONNECT(OP)
#define DECLARE_FAULT(FAULT)						\
	  { fault = (FAULT); break; }
#include "machine.def"
	default:
	  panic("attempted to execute a bogus opcode");
      }

      if (fault != md_fault_none)
	fatal("fault (%d) detected @ 0x%08p", fault, regs.regs_PC);

      if (MD_OP_FLAGS(op) & F_MEM)
	{
	  sim_num_refs++;
	  if (MD_OP_FLAGS(op) & F_STORE)
	    is_write = TRUE;
	}

      if (MD_OP_FLAGS(op) & F_CTRL)
	{
	  md_addr_t pred_PC;
	  struct bpred_update_t update_rec;

	  sim_num_branches++;

	  if (pred)
	    {
	      /* get the next predicted fetch address */
	      pred_PC = bpred_lookup(pred,
				     /* branch addr */regs.regs_PC,
				     /* target */target_PC,
				     /* inst opcode */op,
				     /* call? */MD_IS_CALL(op),
				     /* return? */MD_IS_RETURN(op),
				     /* stash an update ptr */&update_rec,
				     /* stash return stack ptr */&stack_idx);

	      /* valid address returned from branch predictor? */
	      if (!pred_PC)
		{
		  /* no predicted taken target, attempt not taken target */
		  pred_PC = regs.regs_PC + sizeof(md_inst_t);
		}

	      bpred_update(pred,
			   /* branch addr */regs.regs_PC,
			   /* resolved branch target */regs.regs_NPC,
			   /* taken? */regs.regs_NPC != (regs.regs_PC +
							 sizeof(md_inst_t)),
			   /* pred taken? */pred_PC != (regs.regs_PC +
							sizeof(md_inst_t)),
			   /* correct pred? */pred_PC == regs.regs_NPC,
			   /* opcode */op,
			   /* predictor update pointer */&update_rec);
	    }
	}

      /* check for DLite debugger entry condition */
      if (dlite_check_break(regs.regs_NPC,
			    is_write ? ACCESS_WRITE : ACCESS_READ,
			    addr, sim_num_insn, sim_num_insn))
	dlite_main(regs.regs_PC, regs.regs_NPC, sim_num_insn, &regs, mem);

      /* go to the next instruction */
      regs.regs_PC = regs.regs_NPC;
      regs.regs_NPC += sizeof(md_inst_t);

      /* finish early? */
      if (max_insts && sim_num_insn >= max_insts)
	return;
    }
}