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/* This file is part of the program psim.
Copyright (C) 1994-1995, Andrew Cagney <cagney@highland.com.au>
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., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
#ifndef _CPU_C_
#define _CPU_C_
#ifndef STATIC_INLINE_CPU
#define STATIC_INLINE_CPU STATIC_INLINE
#endif
#include <setjmp.h>
#include "cpu.h"
#include "idecode.h"
struct _cpu {
/* the registers */
registers regs;
/* current instruction address */
unsigned_word program_counter;
/* the memory maps */
core *physical; /* all of memory */
vm *virtual;
vm_instruction_map *instruction_map; /* instructions */
vm_data_map *data_map; /* data */
/* current state of interrupt inputs */
int external_exception_pending;
/* the system this processor is contained within */
psim *system;
event_queue *events;
int cpu_nr;
/* if required, a cache to store decoded instructions */
#if WITH_IDECODE_CACHE
idecode_cache icache[IDECODE_CACHE_SIZE];
#endif
/* address reservation: keep the physical address and the contents
of memory at that address */
memory_reservation reservation;
/* offset from event time to this cpu's idea of the local time */
signed64 time_base_local_time;
signed64 decrementer_local_time;
event_entry_tag decrementer_event;
/* Counts of number of instructions executed. */
long number_of_insns;
};
INLINE_CPU cpu *
cpu_create(psim *system,
core *memory,
event_queue *events,
int cpu_nr)
{
cpu *processor = ZALLOC(cpu);
/* create the virtual memory map from the core */
processor->physical = memory;
processor->virtual = vm_create(memory);
processor->instruction_map = vm_create_instruction_map(processor->virtual);
processor->data_map = vm_create_data_map(processor->virtual);
/* link back to core system */
processor->system = system;
processor->events = events;
processor->cpu_nr = cpu_nr;
return processor;
}
/* find ones way home */
INLINE_CPU psim *
cpu_system(cpu *processor)
{
return processor->system;
}
INLINE_CPU int
cpu_nr(cpu *processor)
{
return processor->cpu_nr;
}
INLINE_CPU event_queue *
cpu_event_queue(cpu *processor)
{
return processor->events;
}
/* The processors local concept of time */
INLINE_CPU signed64
cpu_get_time_base(cpu *processor)
{
return (event_queue_time(processor->events)
+ processor->time_base_local_time);
}
INLINE_CPU void
cpu_set_time_base(cpu *processor,
signed64 time_base)
{
processor->time_base_local_time = (event_queue_time(processor->events)
- time_base);
}
INLINE_CPU signed32
cpu_get_decrementer(cpu *processor)
{
return (processor->decrementer_local_time
- event_queue_time(processor->events));
}
STATIC_INLINE_CPU void
cpu_decrement_event(event_queue *queue,
void *data)
{
cpu *processor = (cpu*)data;
if (!decrementer_interrupt(processor)) {
processor->decrementer_event = event_queue_schedule(processor->events,
1, /* NOW! */
cpu_decrement_event,
processor);
}
}
INLINE_CPU void
cpu_set_decrementer(cpu *processor,
signed32 decrementer)
{
signed64 old_decrementer = (processor->decrementer_local_time
- event_queue_time(processor->events));
event_queue_deschedule(processor->events, processor->decrementer_event);
processor->decrementer_local_time = (event_queue_time(processor->events)
+ decrementer);
if (decrementer < 0 && old_decrementer >= 0)
/* dec interrupt occures if the sign of the decrement reg is
changed by the load operation */
processor->decrementer_event = event_queue_schedule(processor->events,
1, /* NOW! */
cpu_decrement_event,
processor);
else if (decrementer >= 0)
processor->decrementer_event = event_queue_schedule(processor->events,
decrementer,
cpu_decrement_event,
processor);
}
/* program counter manipulation */
INLINE_CPU void
cpu_set_program_counter(cpu *processor,
unsigned_word new_program_counter)
{
processor->program_counter = new_program_counter;
}
INLINE_CPU unsigned_word
cpu_get_program_counter(cpu *processor)
{
return processor->program_counter;
}
INLINE_CPU void
cpu_restart(cpu *processor,
unsigned_word nia)
{
processor->program_counter = nia;
psim_restart(processor->system, processor->cpu_nr);
}
INLINE_CPU void
cpu_halt(cpu *processor,
unsigned_word cia,
stop_reason reason,
int signal)
{
if (processor == NULL) {
error("cpu_halt() processor=NULL, cia=0x%x, reason=%d, signal=%d\n",
cia,
reason,
signal);
}
else {
processor->program_counter = cia;
psim_halt(processor->system, processor->cpu_nr, cia, reason, signal);
}
}
#if WITH_IDECODE_CACHE
/* allow access to the cpu's instruction cache */
INLINE_CPU idecode_cache *
cpu_icache(cpu *processor)
{
return processor->icache;
}
#endif
/* address map revelation */
INLINE_CPU vm_instruction_map *
cpu_instruction_map(cpu *processor)
{
return processor->instruction_map;
}
INLINE_CPU vm_data_map *
cpu_data_map(cpu *processor)
{
return processor->data_map;
}
/* reservation access */
INLINE_CPU memory_reservation *
cpu_reservation(cpu *processor)
{
return &processor->reservation;
}
/* register access */
INLINE_CPU registers *
cpu_registers(cpu *processor)
{
return &processor->regs;
}
INLINE_CPU void
cpu_synchronize_context(cpu *processor)
{
#if WITH_IDECODE_CACHE
/* kill off the contents of the cache */
int i;
for (i = 0; i < IDECODE_CACHE_SIZE; i++)
processor->icache[i].address = MASK(0,63);
#endif
/* don't allow the processor to change endian modes */
if ((cpu_registers(processor)->msr & msr_little_endian_mode)
&& CURRENT_TARGET_BYTE_ORDER != LITTLE_ENDIAN) {
error("vm_synchronize_context() - unsuported change of byte order\n");
}
/* update virtual memory */
vm_synchronize_context(processor->virtual,
processor->regs.spr,
processor->regs.sr,
processor->regs.msr);
}
/* # of instructions counter access */
INLINE_CPU void
cpu_increment_number_of_insns(cpu *processor)
{
processor->number_of_insns++;
}
INLINE_CPU long
cpu_get_number_of_insns(cpu *processor)
{
return processor->number_of_insns;
}
static INLINE_CPU char *
cpu_add_commas(char *endbuf, long value)
{
int comma = 3;
*--endbuf = '\0';
do {
if (comma-- == 0)
{
*--endbuf = ',';
comma = 2;
}
*--endbuf = (value % 10) + '0';
} while ((value /= 10) != 0);
return endbuf;
}
INLINE_CPU void
cpu_print_info(cpu *processor, int verbose)
{
char buffer[20];
printf_filtered("CPU #%d executed %s instructions.\n",
processor->cpu_nr+1,
cpu_add_commas(buffer + sizeof(buffer), processor->number_of_insns));
}
#endif /* _CPU_C_ */
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