citra-emu
/
citra-canary
Archived
1
0
Fork 0

ARM: Removed unnecessary and unused SkyEye MMU code.

Added license header back in. I originally removed this because I mostly rewrote the file, but meh
This commit is contained in:
bunnei 2014-10-07 18:56:40 -04:00
parent 3c823c0028
commit 818ba32746
22 changed files with 350 additions and 7767 deletions

View File

@ -6,19 +6,10 @@ set(SRCS
arm/dyncom/arm_dyncom_interpreter.cpp arm/dyncom/arm_dyncom_interpreter.cpp
arm/dyncom/arm_dyncom_run.cpp arm/dyncom/arm_dyncom_run.cpp
arm/dyncom/arm_dyncom_thumb.cpp arm/dyncom/arm_dyncom_thumb.cpp
arm/interpreter/mmu/arm1176jzf_s_mmu.cpp
arm/interpreter/mmu/cache.cpp
arm/interpreter/mmu/maverick.cpp
arm/interpreter/mmu/rb.cpp
arm/interpreter/mmu/sa_mmu.cpp
arm/interpreter/mmu/tlb.cpp
arm/interpreter/mmu/wb.cpp
arm/interpreter/mmu/xscale_copro.cpp
arm/interpreter/arm_interpreter.cpp arm/interpreter/arm_interpreter.cpp
arm/interpreter/armcopro.cpp arm/interpreter/armcopro.cpp
arm/interpreter/armemu.cpp arm/interpreter/armemu.cpp
arm/interpreter/arminit.cpp arm/interpreter/arminit.cpp
arm/interpreter/armmmu.cpp
arm/interpreter/armsupp.cpp arm/interpreter/armsupp.cpp
arm/interpreter/armvirt.cpp arm/interpreter/armvirt.cpp
arm/interpreter/thumbemu.cpp arm/interpreter/thumbemu.cpp
@ -72,12 +63,6 @@ set(HEADERS
arm/dyncom/arm_dyncom_run.h arm/dyncom/arm_dyncom_run.h
arm/dyncom/arm_dyncom_thumb.h arm/dyncom/arm_dyncom_thumb.h
arm/interpreter/arm_interpreter.h arm/interpreter/arm_interpreter.h
arm/interpreter/mmu/arm1176jzf_s_mmu.h
arm/interpreter/mmu/cache.h
arm/interpreter/mmu/rb.h
arm/interpreter/mmu/sa_mmu.h
arm/interpreter/mmu/tlb.h
arm/interpreter/mmu/wb.h
arm/skyeye_common/arm_regformat.h arm/skyeye_common/arm_regformat.h
arm/skyeye_common/armcpu.h arm/skyeye_common/armcpu.h
arm/skyeye_common/armdefs.h arm/skyeye_common/armdefs.h

View File

@ -27,7 +27,6 @@ ARM_DynCom::ARM_DynCom() : ticks(0) {
ARMul_SelectProcessor(state.get(), ARM_v6_Prop | ARM_v5_Prop | ARM_v5e_Prop); ARMul_SelectProcessor(state.get(), ARM_v6_Prop | ARM_v5_Prop | ARM_v5e_Prop);
state->lateabtSig = LOW; state->lateabtSig = LOW;
mmu_init(state);
// Reset the core to initial state // Reset the core to initial state
ARMul_CoProInit(state.get()); ARMul_CoProInit(state.get());

View File

@ -22,7 +22,6 @@ ARM_Interpreter::ARM_Interpreter() {
ARMul_SelectProcessor(state, ARM_v6_Prop | ARM_v5_Prop | ARM_v5e_Prop); ARMul_SelectProcessor(state, ARM_v6_Prop | ARM_v5_Prop | ARM_v5e_Prop);
state->lateabtSig = LOW; state->lateabtSig = LOW;
mmu_init(state);
// Reset the core to initial state // Reset the core to initial state
ARMul_CoProInit(state); ARMul_CoProInit(state);

File diff suppressed because it is too large Load Diff

View File

@ -1,238 +0,0 @@
/*
armmmu.c - Memory Management Unit emulation.
ARMulator extensions for the ARM7100 family.
Copyright (C) 1999 Ben Williamson
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
*/
#include <assert.h>
#include <string.h>
#include "core/arm/skyeye_common/armdefs.h"
/* two header for arm disassemble */
//#include "skyeye_arch.h"
#include "core/arm/skyeye_common/armcpu.h"
extern mmu_ops_t xscale_mmu_ops;
exception_t arm_mmu_write(short size, u32 addr, uint32_t *value);
exception_t arm_mmu_read(short size, u32 addr, uint32_t *value);
#define MMU_OPS (state->mmu.ops)
ARMword skyeye_cachetype = -1;
int
mmu_init (ARMul_State * state)
{
int ret;
state->mmu.control = 0x70;
state->mmu.translation_table_base = 0xDEADC0DE;
state->mmu.domain_access_control = 0xDEADC0DE;
state->mmu.fault_status = 0;
state->mmu.fault_address = 0;
state->mmu.process_id = 0;
switch (state->cpu->cpu_val & state->cpu->cpu_mask) {
//case SA1100:
//case SA1110:
// NOTICE_LOG(ARM11, "SKYEYE: use sa11xx mmu ops\n");
// state->mmu.ops = sa_mmu_ops;
// break;
//case PXA250:
//case PXA270: //xscale
// NOTICE_LOG(ARM11, "SKYEYE: use xscale mmu ops\n");
// state->mmu.ops = xscale_mmu_ops;
// break;
//case 0x41807200: //arm720t
//case 0x41007700: //arm7tdmi
//case 0x41007100: //arm7100
// NOTICE_LOG(ARM11, "SKYEYE: use arm7100 mmu ops\n");
// state->mmu.ops = arm7100_mmu_ops;
// break;
//case 0x41009200:
// NOTICE_LOG(ARM11, "SKYEYE: use arm920t mmu ops\n");
// state->mmu.ops = arm920t_mmu_ops;
// break;
//case 0x41069260:
// NOTICE_LOG(ARM11, "SKYEYE: use arm926ejs mmu ops\n");
// state->mmu.ops = arm926ejs_mmu_ops;
// break;
/* case 0x560f5810: */
case 0x0007b000:
NOTICE_LOG(ARM11, "SKYEYE: use arm11jzf-s mmu ops\n");
state->mmu.ops = arm1176jzf_s_mmu_ops;
break;
default:
ERROR_LOG (ARM11,
"SKYEYE: armmmu.c : mmu_init: unknown cpu_val&cpu_mask 0x%x\n",
state->cpu->cpu_val & state->cpu->cpu_mask);
break;
};
ret = state->mmu.ops.init (state);
state->mmu_inited = (ret == 0);
/* initialize mmu_read and mmu_write for disassemble */
//skyeye_config_t *config = get_current_config();
//generic_arch_t *arch_instance = get_arch_instance(config->arch->arch_name);
//arch_instance->mmu_read = arm_mmu_read;
//arch_instance->mmu_write = arm_mmu_write;
return ret;
}
int
mmu_reset (ARMul_State * state)
{
if (state->mmu_inited)
mmu_exit (state);
return mmu_init (state);
}
void
mmu_exit (ARMul_State * state)
{
MMU_OPS.exit (state);
state->mmu_inited = 0;
}
fault_t
mmu_read_byte (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
return MMU_OPS.read_byte (state, virt_addr, data);
};
fault_t
mmu_read_halfword (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
return MMU_OPS.read_halfword (state, virt_addr, data);
};
fault_t
mmu_read_word (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
return MMU_OPS.read_word (state, virt_addr, data);
};
fault_t
mmu_write_byte (ARMul_State * state, ARMword virt_addr, ARMword data)
{
fault_t fault;
//static int count = 0;
//count ++;
fault = MMU_OPS.write_byte (state, virt_addr, data);
return fault;
}
fault_t
mmu_write_halfword (ARMul_State * state, ARMword virt_addr, ARMword data)
{
fault_t fault;
//static int count = 0;
//count ++;
fault = MMU_OPS.write_halfword (state, virt_addr, data);
return fault;
}
fault_t
mmu_write_word (ARMul_State * state, ARMword virt_addr, ARMword data)
{
fault_t fault;
fault = MMU_OPS.write_word (state, virt_addr, data);
/*used for debug for MMU*
if (!fault){
ARMword tmp;
if (mmu_read_word(state, virt_addr, &tmp)){
err_msg("load back\n");
exit(-1);
}else{
if (tmp != data){
err_msg("load back not equal %d %x\n", count, virt_addr);
}
}
}
*/
return fault;
};
fault_t
mmu_load_instr (ARMul_State * state, ARMword virt_addr, ARMword * instr)
{
return MMU_OPS.load_instr (state, virt_addr, instr);
}
ARMword
mmu_mrc (ARMul_State * state, ARMword instr, ARMword * value)
{
return MMU_OPS.mrc (state, instr, value);
}
void
mmu_mcr (ARMul_State * state, ARMword instr, ARMword value)
{
MMU_OPS.mcr (state, instr, value);
}
/*ywc 20050416*/
int
mmu_v2p_dbct (ARMul_State * state, ARMword virt_addr, ARMword * phys_addr)
{
return (MMU_OPS.v2p_dbct (state, virt_addr, phys_addr));
}
//
//
///* dis_mmu_read for disassemble */
//exception_t arm_mmu_read(short size, uint32_t addr, uint32_t * value)
//{
// ARMul_State *state;
// ARM_CPU_State *cpu = get_current_cpu();
// state = &cpu->core[0];
// switch(size){
// case 8:
// MMU_OPS.read_byte (state, addr, value);
// break;
// case 16:
// case 32:
// break;
// default:
// ERROR_LOG(ARM11, "Error size %d", size);
// break;
// }
// return No_exp;
//}
///* dis_mmu_write for disassemble */
//exception_t arm_mmu_write(short size, uint32_t addr, uint32_t *value)
//{
// ARMul_State *state;
// ARM_CPU_State *cpu = get_current_cpu();
// state = &cpu->core[0];
// switch(size){
// case 8:
// MMU_OPS.write_byte (state, addr, value);
// break;
// case 16:
// case 32:
// break;
// default:
// printf("In %s error size %d Line %d\n", __func__, size, __LINE__);
// break;
// }
// return No_exp;
//}

View File

@ -24,657 +24,142 @@ freed as they might be needed again. A single area of memory may be
defined to generate aborts. */ defined to generate aborts. */
#include "core/arm/skyeye_common/armdefs.h" #include "core/arm/skyeye_common/armdefs.h"
#include "core/arm/skyeye_common/skyeye_defs.h" #include "core/arm/skyeye_common/armemu.h"
//#include "code_cov.h"
#ifdef VALIDATE /* for running the validate suite */ #include "core/mem_map.h"
#define TUBE 48 * 1024 * 1024 /* write a char on the screen */
#define ABORTS 1
#endif
/* #define ABORTS */ #define dumpstack 1
#define dumpstacksize 0x10
#define maxdmupaddr 0x0033a850
#ifdef ABORTS /* the memory system will abort */ /*ARMword ARMul_GetCPSR (ARMul_State * state) {
/* For the old test suite Abort between 32 Kbytes and 32 Mbytes return 0;
For the new test suite Abort between 8 Mbytes and 26 Mbytes */ }
/* #define LOWABORT 32 * 1024 ARMword ARMul_GetSPSR (ARMul_State * state, ARMword mode) {
#define HIGHABORT 32 * 1024 * 1024 */ return 0;
#define LOWABORT 8 * 1024 * 1024 }
#define HIGHABORT 26 * 1024 * 1024 void ARMul_SetCPSR (ARMul_State * state, ARMword value) {
#endif }
void ARMul_SetSPSR (ARMul_State * state, ARMword mode, ARMword value) {
#define NUMPAGES 64 * 1024 }*/
#define PAGESIZE 64 * 1024
#define PAGEBITS 16
#define OFFSETBITS 0xffff
//chy 2003-08-19: seems no use ????
int SWI_vector_installed = FALSE;
extern ARMword skyeye_cachetype;
/***************************************************************************\ void ARMul_Icycles(ARMul_State * state, unsigned number, ARMword address) {
* Get a byte into Virtual Memory, maybe allocating the page *
\***************************************************************************/
static fault_t
GetByte (ARMul_State * state, ARMword address, ARMword * data)
{
fault_t fault;
fault = mmu_read_byte (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
// printf("SKYEYE: GetByte fault %d \n", fault);
}
return fault;
} }
/***************************************************************************\ void ARMul_Ccycles(ARMul_State * state, unsigned number, ARMword address) {
* Get a halfword into Virtual Memory, maybe allocating the page *
\***************************************************************************/
static fault_t
GetHalfWord (ARMul_State * state, ARMword address, ARMword * data)
{
fault_t fault;
fault = mmu_read_halfword (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
// printf("SKYEYE: GetHalfWord fault %d \n", fault);
}
return fault;
} }
/***************************************************************************\ ARMword ARMul_LoadInstrS(ARMul_State * state, ARMword address, ARMword isize) {
* Get a Word from Virtual Memory, maybe allocating the page * state->NumScycles++;
\***************************************************************************/
static fault_t
GetWord (ARMul_State * state, ARMword address, ARMword * data)
{
fault_t fault;
fault = mmu_read_word (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
#if 0
/* XXX */ extern int hack;
hack = 1;
#endif
#if 0
printf ("mmu_read_word at 0x%08x: ", address);
switch (fault) {
case ALIGNMENT_FAULT:
printf ("ALIGNMENT_FAULT");
break;
case SECTION_TRANSLATION_FAULT:
printf ("SECTION_TRANSLATION_FAULT");
break;
case PAGE_TRANSLATION_FAULT:
printf ("PAGE_TRANSLATION_FAULT");
break;
case SECTION_DOMAIN_FAULT:
printf ("SECTION_DOMAIN_FAULT");
break;
case SECTION_PERMISSION_FAULT:
printf ("SECTION_PERMISSION_FAULT");
break;
case SUBPAGE_PERMISSION_FAULT:
printf ("SUBPAGE_PERMISSION_FAULT");
break;
default:
printf ("Unrecognized fault number!");
}
printf ("\tpc = 0x%08x\n", state->Reg[15]);
#endif
}
return fault;
}
//2003-07-10 chy: lyh change
/****************************************************************************\
* Load a Instrion Word into Virtual Memory *
\****************************************************************************/
static fault_t
LoadInstr (ARMul_State * state, ARMword address, ARMword * instr)
{
fault_t fault;
fault = mmu_load_instr (state, address, instr);
return fault;
//if (fault)
// log_msg("load_instr fault = %d, address = %x\n", fault, address);
}
/***************************************************************************\
* Put a byte into Virtual Memory, maybe allocating the page *
\***************************************************************************/
static fault_t
PutByte (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
fault = mmu_write_byte (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
// printf("SKYEYE: PutByte fault %d \n", fault);
}
return fault;
}
/***************************************************************************\
* Put a halfword into Virtual Memory, maybe allocating the page *
\***************************************************************************/
static fault_t
PutHalfWord (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
fault = mmu_write_halfword (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
// printf("SKYEYE: PutHalfWord fault %d \n", fault);
}
return fault;
}
/***************************************************************************\
* Put a Word into Virtual Memory, maybe allocating the page *
\***************************************************************************/
static fault_t
PutWord (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
fault = mmu_write_word (state, address, data);
if (fault) {
//chy 2003-07-11: sometime has fault, but linux can continue running !!!!????
#if 0
/* XXX */ extern int hack;
hack = 1;
#endif
#if 0
printf ("mmu_write_word at 0x%08x: ", address);
switch (fault) {
case ALIGNMENT_FAULT:
printf ("ALIGNMENT_FAULT");
break;
case SECTION_TRANSLATION_FAULT:
printf ("SECTION_TRANSLATION_FAULT");
break;
case PAGE_TRANSLATION_FAULT:
printf ("PAGE_TRANSLATION_FAULT");
break;
case SECTION_DOMAIN_FAULT:
printf ("SECTION_DOMAIN_FAULT");
break;
case SECTION_PERMISSION_FAULT:
printf ("SECTION_PERMISSION_FAULT");
break;
case SUBPAGE_PERMISSION_FAULT:
printf ("SUBPAGE_PERMISSION_FAULT");
break;
default:
printf ("Unrecognized fault number!");
}
printf ("\tpc = 0x%08x\n", state->Reg[15]);
#endif
}
return fault;
}
/***************************************************************************\
* Initialise the memory interface *
\***************************************************************************/
unsigned
ARMul_MemoryInit (ARMul_State * state, unsigned int initmemsize)
{
return TRUE;
}
/***************************************************************************\
* Remove the memory interface *
\***************************************************************************/
void
ARMul_MemoryExit (ARMul_State * state)
{
}
/***************************************************************************\
* ReLoad Instruction *
\***************************************************************************/
ARMword
ARMul_ReLoadInstr (ARMul_State * state, ARMword address, ARMword isize)
{
ARMword data;
fault_t fault;
#ifdef ABORTS
if (address >= LOWABORT && address < HIGHABORT) {
ARMul_PREFETCHABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
#endif
#if 0
/* do profiling for code coverage */
if (skyeye_config.code_cov.prof_on)
cov_prof(EXEC_FLAG, address);
#endif
#if 1
if ((isize == 2) && (address & 0x2)) {
ARMword lo, hi;
if (!(skyeye_cachetype == INSTCACHE))
fault = GetHalfWord (state, address, &lo);
else
fault = LoadInstr (state, address, &lo);
#if 0
if (!fault) {
if (!(skyeye_cachetype == INSTCACHE))
fault = GetHalfWord (state, address + isize, &hi);
else
fault = LoadInstr (state, address + isize, &hi);
}
#endif
if (fault) {
ARMul_PREFETCHABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
return lo;
#if 0
if (state->bigendSig == HIGH)
return (lo << 16) | (hi >> 16);
else
return ((hi & 0xFFFF) << 16) | (lo >> 16);
#endif
}
#endif
if (!(skyeye_cachetype == INSTCACHE))
fault = GetWord (state, address, &data);
else
fault = LoadInstr (state, address, &data);
if (fault) {
/* dyf add for s3c6410 no instcache temporary 2010.9.17 */
if (!(skyeye_cachetype == INSTCACHE)) {
/* set translation fault on prefetch abort */
state->mmu.fault_statusi = fault & 0xFF;
state->mmu.fault_address = address;
}
/* add end */
ARMul_PREFETCHABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
return data;
}
/***************************************************************************\
* Load Instruction, Sequential Cycle *
\***************************************************************************/
ARMword
ARMul_LoadInstrS (ARMul_State * state, ARMword address, ARMword isize)
{
state->NumScycles++;
#ifdef HOURGLASS #ifdef HOURGLASS
if ((state->NumScycles & HOURGLASS_RATE) == 0) { if ((state->NumScycles & HOURGLASS_RATE) == 0) {
HOURGLASS; HOURGLASS;
} }
#endif #endif
if (isize == 2)
return ARMul_ReLoadInstr (state, address, isize); return (u16)Memory::Read16(address);
else
return (u32)Memory::Read32(address);
} }
/***************************************************************************\ ARMword ARMul_LoadInstrN(ARMul_State * state, ARMword address, ARMword isize) {
* Load Instruction, Non Sequential Cycle * state->NumNcycles++;
\***************************************************************************/
ARMword if (isize == 2)
ARMul_LoadInstrN (ARMul_State * state, ARMword address, ARMword isize) return (u16)Memory::Read16(address);
else
return (u32)Memory::Read32(address);
}
ARMword ARMul_ReLoadInstr(ARMul_State * state, ARMword address, ARMword isize) {
ARMword data;
if ((isize == 2) && (address & 0x2)) {
ARMword lo;
lo = (u16)Memory::Read16(address);
return lo;
}
data = (u32)Memory::Read32(address);
return data;
}
ARMword ARMul_ReadWord(ARMul_State * state, ARMword address) {
ARMword data;
data = Memory::Read32(address);
return data;
}
ARMword ARMul_LoadWordS(ARMul_State * state, ARMword address) {
state->NumScycles++;
return ARMul_ReadWord(state, address);
}
ARMword ARMul_LoadWordN(ARMul_State * state, ARMword address) {
state->NumNcycles++;
return ARMul_ReadWord(state, address);
}
ARMword ARMul_LoadHalfWord(ARMul_State * state, ARMword address) {
state->NumNcycles++;
return (u16)Memory::Read16(address);;
}
ARMword ARMul_ReadByte(ARMul_State * state, ARMword address) {
return (u8)Memory::Read8(address);
}
ARMword ARMul_LoadByte(ARMul_State * state, ARMword address) {
state->NumNcycles++;
return ARMul_ReadByte(state, address);
}
void ARMul_StoreHalfWord(ARMul_State * state, ARMword address, ARMword data) {
state->NumNcycles++;
Memory::Write16(address, data);
}
void ARMul_StoreByte(ARMul_State * state, ARMword address, ARMword data) {
state->NumNcycles++;
ARMul_WriteByte(state, address, data);
}
ARMword ARMul_SwapWord(ARMul_State * state, ARMword address, ARMword data) {
ARMword temp;
state->NumNcycles++;
temp = ARMul_ReadWord(state, address);
state->NumNcycles++;
Memory::Write32(address, data);
return temp;
}
ARMword ARMul_SwapByte(ARMul_State * state, ARMword address, ARMword data) {
ARMword temp;
temp = ARMul_LoadByte(state, address);
Memory::Write8(address, data);
return temp;
}
void ARMul_WriteWord(ARMul_State * state, ARMword address, ARMword data) {
Memory::Write32(address, data);
}
void ARMul_WriteByte(ARMul_State * state, ARMword address, ARMword data)
{ {
state->NumNcycles++; Memory::Write8(address, data);
return ARMul_ReLoadInstr (state, address, isize);
} }
/***************************************************************************\ void ARMul_StoreWordS(ARMul_State * state, ARMword address, ARMword data)
* Read Word (but don't tell anyone!) *
\***************************************************************************/
ARMword
ARMul_ReadWord (ARMul_State * state, ARMword address)
{ {
ARMword data; state->NumScycles++;
fault_t fault; ARMul_WriteWord(state, address, data);
#ifdef ABORTS
if (address >= LOWABORT && address < HIGHABORT) {
ARMul_DATAABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
#endif
fault = GetWord (state, address, &data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
return data;
} }
/***************************************************************************\ void ARMul_StoreWordN(ARMul_State * state, ARMword address, ARMword data)
* Load Word, Sequential Cycle *
\***************************************************************************/
ARMword
ARMul_LoadWordS (ARMul_State * state, ARMword address)
{ {
state->NumScycles++; state->NumNcycles++;
ARMul_WriteWord(state, address, data);
return ARMul_ReadWord (state, address);
}
/***************************************************************************\
* Load Word, Non Sequential Cycle *
\***************************************************************************/
ARMword
ARMul_LoadWordN (ARMul_State * state, ARMword address)
{
state->NumNcycles++;
return ARMul_ReadWord (state, address);
}
/***************************************************************************\
* Load Halfword, (Non Sequential Cycle) *
\***************************************************************************/
ARMword
ARMul_LoadHalfWord (ARMul_State * state, ARMword address)
{
ARMword data;
fault_t fault;
state->NumNcycles++;
fault = GetHalfWord (state, address, &data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
return data;
}
/***************************************************************************\
* Read Byte (but don't tell anyone!) *
\***************************************************************************/
int ARMul_ICE_ReadByte(ARMul_State * state, ARMword address, ARMword *presult)
{
ARMword data;
fault_t fault;
fault = GetByte (state, address, &data);
if (fault) {
*presult=-1; fault=ALIGNMENT_FAULT; return fault;
}else{
*(char *)presult=(unsigned char)(data & 0xff); fault=NO_FAULT; return fault;
}
}
ARMword
ARMul_ReadByte (ARMul_State * state, ARMword address)
{
ARMword data;
fault_t fault;
fault = GetByte (state, address, &data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return ARMul_ABORTWORD;
}
else {
ARMul_CLEARABORT;
}
return data;
}
/***************************************************************************\
* Load Byte, (Non Sequential Cycle) *
\***************************************************************************/
ARMword
ARMul_LoadByte (ARMul_State * state, ARMword address)
{
state->NumNcycles++;
return ARMul_ReadByte (state, address);
}
/***************************************************************************\
* Write Word (but don't tell anyone!) *
\***************************************************************************/
void
ARMul_WriteWord (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
#ifdef ABORTS
if (address >= LOWABORT && address < HIGHABORT) {
ARMul_DATAABORT (address);
return;
}
else {
ARMul_CLEARABORT;
}
#endif
fault = PutWord (state, address, data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return;
}
else {
ARMul_CLEARABORT;
}
}
/***************************************************************************\
* Store Word, Sequential Cycle *
\***************************************************************************/
void
ARMul_StoreWordS (ARMul_State * state, ARMword address, ARMword data)
{
state->NumScycles++;
ARMul_WriteWord (state, address, data);
}
/***************************************************************************\
* Store Word, Non Sequential Cycle *
\***************************************************************************/
void
ARMul_StoreWordN (ARMul_State * state, ARMword address, ARMword data)
{
state->NumNcycles++;
ARMul_WriteWord (state, address, data);
}
/***************************************************************************\
* Store HalfWord, (Non Sequential Cycle) *
\***************************************************************************/
void
ARMul_StoreHalfWord (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
state->NumNcycles++;
fault = PutHalfWord (state, address, data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return;
}
else {
ARMul_CLEARABORT;
}
}
//chy 2006-04-15
int ARMul_ICE_WriteByte (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
fault = PutByte (state, address, data);
if (fault)
return 1;
else
return 0;
}
/***************************************************************************\
* Write Byte (but don't tell anyone!) *
\***************************************************************************/
//chy 2003-07-10, add real write byte fun
void
ARMul_WriteByte (ARMul_State * state, ARMword address, ARMword data)
{
fault_t fault;
fault = PutByte (state, address, data);
if (fault) {
state->mmu.fault_status =
(fault | (state->mmu.last_domain << 4)) & 0xFF;
state->mmu.fault_address = address;
ARMul_DATAABORT (address);
return;
}
else {
ARMul_CLEARABORT;
}
}
/***************************************************************************\
* Store Byte, (Non Sequential Cycle) *
\***************************************************************************/
void
ARMul_StoreByte (ARMul_State * state, ARMword address, ARMword data)
{
state->NumNcycles++;
#ifdef VALIDATE
if (address == TUBE) {
if (data == 4)
state->Emulate = FALSE;
else
(void) putc ((char) data, stderr); /* Write Char */
return;
}
#endif
ARMul_WriteByte (state, address, data);
}
/***************************************************************************\
* Swap Word, (Two Non Sequential Cycles) *
\***************************************************************************/
ARMword
ARMul_SwapWord (ARMul_State * state, ARMword address, ARMword data)
{
ARMword temp;
state->NumNcycles++;
temp = ARMul_ReadWord (state, address);
state->NumNcycles++;
PutWord (state, address, data);
return temp;
}
/***************************************************************************\
* Swap Byte, (Two Non Sequential Cycles) *
\***************************************************************************/
ARMword
ARMul_SwapByte (ARMul_State * state, ARMword address, ARMword data)
{
ARMword temp;
temp = ARMul_LoadByte (state, address);
ARMul_StoreByte (state, address, data);
return temp;
}
/***************************************************************************\
* Count I Cycles *
\***************************************************************************/
void
ARMul_Icycles (ARMul_State * state, unsigned number,
ARMword address)
{
state->NumIcycles += number;
ARMul_CLEARABORT;
}
/***************************************************************************\
* Count C Cycles *
\***************************************************************************/
void
ARMul_Ccycles (ARMul_State * state, unsigned number,
ARMword address)
{
state->NumCcycles += number;
ARMul_CLEARABORT;
} }

File diff suppressed because it is too large Load Diff

View File

@ -1,37 +0,0 @@
/*
arm1176JZF-S_mmu.h - ARM1176JZF-S Memory Management Unit emulation.
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 _ARM1176JZF_S_MMU_H_
#define _ARM1176JZF_S_MMU_H_
#if 0
typedef struct arm1176jzf-s_mmu_s
{
tlb_t i_tlb;
cache_t i_cache;
tlb_t d_tlb;
cache_t d_cache;
wb_t wb_t;
} arm1176jzf-s_mmu_t;
#endif
extern mmu_ops_t arm1176jzf_s_mmu_ops;
ARMword
arm1176jzf_s_mmu_mrc (ARMul_State *state, ARMword instr, ARMword *value);
#endif /*_ARM1176JZF_S_MMU_H_*/

View File

@ -1,370 +0,0 @@
#include "core/arm/skyeye_common/armdefs.h"
/* mmu cache init
*
* @cache_t :cache_t to init
* @width :cache line width in byte
* @way :way of each cache set
* @set :cache set num
*
* $ -1: error
* 0: sucess
*/
int
mmu_cache_init (cache_s * cache_t, int width, int way, int set, int w_mode)
{
int i, j;
cache_set_t *sets;
cache_line_t *lines;
/*alloc cache set */
sets = NULL;
lines = NULL;
//fprintf(stderr, "mmu_cache_init: mallloc beg size %d,sets 0x%x\n", sizeof(cache_set_t) * set,sets);
//exit(-1);
sets = (cache_set_t *) malloc (sizeof (cache_set_t) * set);
if (sets == NULL) {
ERROR_LOG(ARM11, "set malloc size %d\n", sizeof (cache_set_t) * set);
goto sets_error;
}
//fprintf(stderr, "mmu_cache_init: mallloc end sets 0x%x\n", sets);
cache_t->sets = sets;
/*init cache set */
for (i = 0; i < set; i++) {
/*alloc cache line */
lines = (cache_line_t *) malloc (sizeof (cache_line_t) * way);
if (lines == NULL) {
ERROR_LOG(ARM11, "line malloc size %d\n",
sizeof (cache_line_t) * way);
goto lines_error;
}
/*init cache line */
for (j = 0; j < way; j++) {
lines[j].tag = 0; //invalid
lines[j].data = (ARMword *) malloc (width);
if (lines[j].data == NULL) {
ERROR_LOG(ARM11, "data alloc size %d\n", width);
goto data_error;
}
}
sets[i].lines = lines;
sets[i].cycle = 0;
}
cache_t->width = width;
cache_t->set = set;
cache_t->way = way;
cache_t->w_mode = w_mode;
return 0;
data_error:
/*free data */
while (j-- > 0)
free (lines[j].data);
/*free data error line */
free (lines);
lines_error:
/*free lines already alloced */
while (i-- > 0) {
for (j = 0; j < way; j++)
free (sets[i].lines[j].data);
free (sets[i].lines);
}
/*free sets */
free (sets);
sets_error:
return -1;
};
/* free a cache_t's inner data, the ptr self is not freed,
* when needed do like below:
* mmu_cache_exit(cache);
* free(cache_t);
*
* @cache_t : the cache_t to free
*/
void
mmu_cache_exit (cache_s * cache_t)
{
int i, j;
cache_set_t *sets, *set;
cache_line_t *lines, *line;
/*free all set */
sets = cache_t->sets;
for (set = sets, i = 0; i < cache_t->set; i++, set++) {
/*free all line */
lines = set->lines;
for (line = lines, j = 0; j < cache_t->way; j++, line++)
free (line->data);
free (lines);
}
free (sets);
}
/* mmu cache search
*
* @state :ARMul_State
* @cache_t :cache_t to search
* @va :virtual address
*
* $ NULL: no cache match
* cache :cache matched
*/
cache_line_t *
mmu_cache_search (ARMul_State * state, cache_s * cache_t, ARMword va)
{
int i;
int set = va_cache_set (va, cache_t);
ARMword tag = va_cache_align (va, cache_t);
cache_line_t *cache;
cache_set_t *cache_set = cache_t->sets + set;
for (i = 0, cache = cache_set->lines; i < cache_t->way; i++, cache++) {
if ((cache->tag & TAG_VALID_FLAG)
&& (tag == va_cache_align (cache->tag, cache_t)))
return cache;
}
return NULL;
}
/* mmu cache search by set/index
*
* @state :ARMul_State
* @cache_t :cache_t to search
* @index :set/index value.
*
* $ NULL: no cache match
* cache :cache matched
*/
cache_line_t *
mmu_cache_search_by_index (ARMul_State * state, cache_s * cache_t,
ARMword index)
{
int way = cache_t->way;
int set_v = index_cache_set (index, cache_t);
int i = 0, index_v = 0;
cache_set_t *set;
while ((way >>= 1) >= 1)
i++;
index_v = index >> (32 - i);
set = cache_t->sets + set_v;
return set->lines + index_v;
}
/* mmu cache alloc
*
* @state :ARMul_State
* @cache_t :cache_t to alloc from
* @va :virtual address that require cache alloc, need not cache aligned
* @pa :physical address of va
*
* $ cache_alloced, always alloc OK
*/
cache_line_t *
mmu_cache_alloc (ARMul_State * state, cache_s * cache_t, ARMword va,
ARMword pa)
{
cache_line_t *cache;
cache_set_t *set;
int i;
va = va_cache_align (va, cache_t);
pa = va_cache_align (pa, cache_t);
set = &cache_t->sets[va_cache_set (va, cache_t)];
/*robin-round */
cache = &set->lines[set->cycle++];
if (set->cycle == cache_t->way)
set->cycle = 0;
if (cache_t->w_mode == CACHE_WRITE_BACK) {
ARMword t;
/*if cache valid, try to write back */
if (cache->tag & TAG_VALID_FLAG) {
mmu_cache_write_back (state, cache_t, cache);
}
/*read in cache_line */
t = pa;
for (i = 0; i < (cache_t->width >> WORD_SHT);
i++, t += WORD_SIZE) {
//cache->data[i] = mem_read_word (state, t);
bus_read(32, t, &cache->data[i]);
}
}
/*store tag and pa */
cache->tag = va | TAG_VALID_FLAG;
cache->pa = pa;
return cache;
};
/* mmu_cache_write_back write cache data to memory
* @state
* @cache_t :cache_t of the cache line
* @cache : cache line
*/
void
mmu_cache_write_back (ARMul_State * state, cache_s * cache_t,
cache_line_t * cache)
{
ARMword pa = cache->pa;
int nw = cache_t->width >> WORD_SHT;
ARMword *data = cache->data;
int i;
int t0, t1, t2;
if ((cache->tag & 1) == 0)
return;
switch (cache->
tag & ~1 & (TAG_FIRST_HALF_DIRTY | TAG_LAST_HALF_DIRTY)) {
case 0:
return;
case TAG_FIRST_HALF_DIRTY:
nw /= 2;
break;
case TAG_LAST_HALF_DIRTY:
nw /= 2;
pa += nw << WORD_SHT;
data += nw;
break;
case TAG_FIRST_HALF_DIRTY | TAG_LAST_HALF_DIRTY:
break;
}
for (i = 0; i < nw; i++, data++, pa += WORD_SIZE)
//mem_write_word (state, pa, *data);
bus_write(32, pa, *data);
cache->tag &= ~(TAG_FIRST_HALF_DIRTY | TAG_LAST_HALF_DIRTY);
};
/* mmu_cache_clean: clean a cache of va in cache_t
*
* @state :ARMul_State
* @cache_t :cache_t to clean
* @va :virtaul address
*/
void
mmu_cache_clean (ARMul_State * state, cache_s * cache_t, ARMword va)
{
cache_line_t *cache;
cache = mmu_cache_search (state, cache_t, va);
if (cache)
mmu_cache_write_back (state, cache_t, cache);
}
/* mmu_cache_clean_by_index: clean a cache by set/index format value
*
* @state :ARMul_State
* @cache_t :cache_t to clean
* @va :set/index format value
*/
void
mmu_cache_clean_by_index (ARMul_State * state, cache_s * cache_t,
ARMword index)
{
cache_line_t *cache;
cache = mmu_cache_search_by_index (state, cache_t, index);
if (cache)
mmu_cache_write_back (state, cache_t, cache);
}
/* mmu_cache_invalidate : invalidate a cache of va
*
* @state :ARMul_State
* @cache_t :cache_t to invalid
* @va :virt_addr to invalid
*/
void
mmu_cache_invalidate (ARMul_State * state, cache_s * cache_t, ARMword va)
{
cache_line_t *cache;
cache = mmu_cache_search (state, cache_t, va);
if (cache) {
mmu_cache_write_back (state, cache_t, cache);
cache->tag = 0;
}
}
/* mmu_cache_invalidate_by_index : invalidate a cache by index format
*
* @state :ARMul_State
* @cache_t :cache_t to invalid
* @index :set/index data
*/
void
mmu_cache_invalidate_by_index (ARMul_State * state, cache_s * cache_t,
ARMword index)
{
cache_line_t *cache;
cache = mmu_cache_search_by_index (state, cache_t, index);
if (cache) {
mmu_cache_write_back (state, cache_t, cache);
cache->tag = 0;
}
}
/* mmu_cache_invalidate_all
*
* @state:
* @cache_t
* */
void
mmu_cache_invalidate_all (ARMul_State * state, cache_s * cache_t)
{
int i, j;
cache_set_t *set;
cache_line_t *cache;
set = cache_t->sets;
for (i = 0; i < cache_t->set; i++, set++) {
cache = set->lines;
for (j = 0; j < cache_t->way; j++, cache++) {
mmu_cache_write_back (state, cache_t, cache);
cache->tag = 0;
}
}
};
void
mmu_cache_soft_flush (ARMul_State * state, cache_s * cache_t, ARMword pa)
{
ARMword set, way;
cache_line_t *cache;
pa = (pa / cache_t->width);
way = pa & (cache_t->way - 1);
set = (pa / cache_t->way) & (cache_t->set - 1);
cache = &cache_t->sets[set].lines[way];
mmu_cache_write_back (state, cache_t, cache);
cache->tag = 0;
}
cache_line_t* mmu_cache_dirty_cache(ARMul_State *state,cache_s *cache){
int i;
int j;
cache_line_t *cache_line = NULL;
cache_set_t *cache_set = cache->sets;
int sets = cache->set;
for (i = 0; i < sets; i++){
for(j = 0,cache_line = &cache_set[i].lines[0]; j < cache->way; j++,cache_line++){
if((cache_line->tag & TAG_FIRST_HALF_DIRTY) || (cache_line->tag & TAG_LAST_HALF_DIRTY))
return cache_line;
}
}
return NULL;
}

View File

@ -1,168 +0,0 @@
#ifndef _MMU_CACHE_H_
#define _MMU_CACHE_H_
typedef struct cache_line_t
{
ARMword tag; /* cache line align address |
bit2: last half dirty
bit1: first half dirty
bit0: cache valid flag
*/
ARMword pa; /*physical address */
ARMword *data; /*array of cached data */
} cache_line_t;
#define TAG_VALID_FLAG 0x00000001
#define TAG_FIRST_HALF_DIRTY 0x00000002
#define TAG_LAST_HALF_DIRTY 0x00000004
/*cache set association*/
typedef struct cache_set_s
{
cache_line_t *lines;
int cycle;
} cache_set_t;
enum
{
CACHE_WRITE_BACK,
CACHE_WRITE_THROUGH,
};
typedef struct cache_s
{
int width; /*bytes in a line */
int way; /*way of set asscociate */
int set; /*num of set */
int w_mode; /*write back or write through */
//int a_mode; /*alloc mode: random or round-bin*/
cache_set_t *sets;
/**/} cache_s;
typedef struct cache_desc_s
{
int width;
int way;
int set;
int w_mode;
// int a_mode;
} cache_desc_t;
/*virtual address to cache set index*/
#define va_cache_set(va, cache_t) \
(((va) / (cache_t)->width) & ((cache_t)->set - 1))
/*virtual address to cahce line aligned*/
#define va_cache_align(va, cache_t) \
((va) & ~((cache_t)->width - 1))
/*virtaul address to cache line word index*/
#define va_cache_index(va, cache_t) \
(((va) & ((cache_t)->width - 1)) >> WORD_SHT)
/*see Page 558 in arm manual*/
/*set/index format value to cache set value*/
#define index_cache_set(index, cache_t) \
(((index) / (cache_t)->width) & ((cache_t)->set - 1))
/*************************cache********************/
/* mmu cache init
*
* @cache_t :cache_t to init
* @width :cache line width in byte
* @way :way of each cache set
* @set :cache set num
* @w_mode :cache w_mode
*
* $ -1: error
* 0: sucess
*/
int
mmu_cache_init (cache_s * cache_t, int width, int way, int set, int w_mode);
/* free a cache_t's inner data, the ptr self is not freed,
* when needed do like below:
* mmu_cache_exit(cache);
* free(cache_t);
*
* @cache_t : the cache_t to free
*/
void mmu_cache_exit (cache_s * cache_t);
/* mmu cache search
*
* @state :ARMul_State
* @cache_t :cache_t to search
* @va :virtual address
*
* $ NULL: no cache match
* cache :cache matched
* */
cache_line_t *mmu_cache_search (ARMul_State * state, cache_s * cache_t,
ARMword va);
/* mmu cache search by set/index
*
* @state :ARMul_State
* @cache_t :cache_t to search
* @index :set/index value.
*
* $ NULL: no cache match
* cache :cache matched
* */
cache_line_t *mmu_cache_search_by_index (ARMul_State * state,
cache_s * cache_t, ARMword index);
/* mmu cache alloc
*
* @state :ARMul_State
* @cache_t :cache_t to alloc from
* @va :virtual address that require cache alloc, need not cache aligned
* @pa :physical address of va
*
* $ cache_alloced, always alloc OK
*/
cache_line_t *mmu_cache_alloc (ARMul_State * state, cache_s * cache_t,
ARMword va, ARMword pa);
/* mmu_cache_write_back write cache data to memory
*
* @state:
* @cache_t :cache_t of the cache line
* @cache : cache line
*/
void
mmu_cache_write_back (ARMul_State * state, cache_s * cache_t,
cache_line_t * cache);
/* mmu_cache_clean: clean a cache of va in cache_t
*
* @state :ARMul_State
* @cache_t :cache_t to clean
* @va :virtaul address
*/
void mmu_cache_clean (ARMul_State * state, cache_s * cache_t, ARMword va);
void
mmu_cache_clean_by_index (ARMul_State * state, cache_s * cache_t,
ARMword index);
/* mmu_cache_invalidate : invalidate a cache of va
*
* @state :ARMul_State
* @cache_t :cache_t to invalid
* @va :virt_addr to invalid
*/
void
mmu_cache_invalidate (ARMul_State * state, cache_s * cache_t, ARMword va);
void
mmu_cache_invalidate_by_index (ARMul_State * state, cache_s * cache_t,
ARMword index);
void mmu_cache_invalidate_all (ARMul_State * state, cache_s * cache_t);
void
mmu_cache_soft_flush (ARMul_State * state, cache_s * cache_t, ARMword pa);
cache_line_t* mmu_cache_dirty_cache(ARMul_State * state, cache_s * cache_t);
#endif /*_MMU_CACHE_H_*/

File diff suppressed because it is too large Load Diff

View File

@ -1,126 +0,0 @@
#include "core/arm/skyeye_common/armdefs.h"
/*chy 2004-06-06, fix bug found by wenye@cs.ucsb.edu*/
ARMword rb_masks[] = {
0x0, //RB_INVALID
4, //RB_1
16, //RB_4
32, //RB_8
};
/*mmu_rb_init
* @rb_t :rb_t to init
* @num :number of entry
* */
int
mmu_rb_init (rb_s * rb_t, int num)
{
int i;
rb_entry_t *entrys;
entrys = (rb_entry_t *) malloc (sizeof (*entrys) * num);
if (entrys == NULL) {
printf ("SKYEYE:mmu_rb_init malloc error\n");
return -1;
}
for (i = 0; i < num; i++) {
entrys[i].type = RB_INVALID;
entrys[i].fault = NO_FAULT;
}
rb_t->entrys = entrys;
rb_t->num = num;
return 0;
}
/*mmu_rb_exit*/
void
mmu_rb_exit (rb_s * rb_t)
{
free (rb_t->entrys);
};
/*mmu_rb_search
* @rb_t :rb_t to serach
* @va :va address to math
*
* $ NULL :not match
* NO-NULL:
* */
rb_entry_t *
mmu_rb_search (rb_s * rb_t, ARMword va)
{
int i;
rb_entry_t *rb = rb_t->entrys;
DEBUG_LOG(ARM11, "va = %x\n", va);
for (i = 0; i < rb_t->num; i++, rb++) {
//2004-06-06 lyh bug from wenye@cs.ucsb.edu
if (rb->type) {
if ((va >= rb->va)
&& (va < (rb->va + rb_masks[rb->type])))
return rb;
}
}
return NULL;
};
void
mmu_rb_invalidate_entry (rb_s * rb_t, int i)
{
rb_t->entrys[i].type = RB_INVALID;
}
void
mmu_rb_invalidate_all (rb_s * rb_t)
{
int i;
for (i = 0; i < rb_t->num; i++)
mmu_rb_invalidate_entry (rb_t, i);
};
void
mmu_rb_load (ARMul_State * state, rb_s * rb_t, int i_rb, int type, ARMword va)
{
rb_entry_t *rb;
int i;
ARMword max_start, min_end;
fault_t fault;
tlb_entry_t *tlb;
/*align va according to type */
va &= ~(rb_masks[type] - 1);
/*invalidate all RB match [va, va + rb_masks[type]] */
for (rb = rb_t->entrys, i = 0; i < rb_t->num; i++, rb++) {
if (rb->type) {
max_start = max (va, rb->va);
min_end =
min (va + rb_masks[type],
rb->va + rb_masks[rb->type]);
if (max_start < min_end)
rb->type = RB_INVALID;
}
}
/*load word */
rb = &rb_t->entrys[i_rb];
rb->type = type;
fault = translate (state, va, D_TLB (), &tlb);
if (fault) {
rb->fault = fault;
return;
}
fault = check_access (state, va, tlb, 1);
if (fault) {
rb->fault = fault;
return;
}
rb->fault = NO_FAULT;
va = tlb_va_to_pa (tlb, va);
//2004-06-06 lyh bug from wenye@cs.ucsb.edu
for (i = 0; i < (rb_masks[type] / 4); i++, va += WORD_SIZE) {
//rb->data[i] = mem_read_word (state, va);
bus_read(32, va, &rb->data[i]);
};
}

View File

@ -1,55 +0,0 @@
#ifndef _MMU_RB_H
#define _MMU_RB_H
enum rb_type_t
{
RB_INVALID = 0, //invalid
RB_1, //1 word
RB_4, //4 word
RB_8, //8 word
};
/*bytes of each rb_type*/
extern ARMword rb_masks[];
#define RB_WORD_NUM 8
typedef struct rb_entry_s
{
ARMword data[RB_WORD_NUM]; //array to store data
ARMword va; //first word va
int type; //rb type
fault_t fault; //fault set by rb alloc
} rb_entry_t;
typedef struct rb_s
{
int num;
rb_entry_t *entrys;
} rb_s;
/*mmu_rb_init
* @rb_t :rb_t to init
* @num :number of entry
* */
int mmu_rb_init (rb_s * rb_t, int num);
/*mmu_rb_exit*/
void mmu_rb_exit (rb_s * rb_t);
/*mmu_rb_search
* @rb_t :rb_t to serach
* @va :va address to math
*
* $ NULL :not match
* NO-NULL:
* */
rb_entry_t *mmu_rb_search (rb_s * rb_t, ARMword va);
void mmu_rb_invalidate_entry (rb_s * rb_t, int i);
void mmu_rb_invalidate_all (rb_s * rb_t);
void mmu_rb_load (ARMul_State * state, rb_s * rb_t, int i_rb,
int type, ARMword va);
#endif /*_MMU_RB_H_*/

View File

@ -1,864 +0,0 @@
/*
armmmu.c - Memory Management Unit emulation.
ARMulator extensions for the ARM7100 family.
Copyright (C) 1999 Ben Williamson
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
*/
#include <assert.h>
#include <string.h>
#include "core/arm/skyeye_common/armdefs.h"
/**
* The interface of read data from bus
*/
int bus_read(short size, int addr, uint32_t * value) {
ERROR_LOG(ARM11, "unimplemented bus_read");
return 0;
}
/**
* The interface of write data from bus
*/
int bus_write(short size, int addr, uint32_t value) {
ERROR_LOG(ARM11, "unimplemented bus_write");
return 0;
}
typedef struct sa_mmu_desc_s
{
int i_tlb;
cache_desc_t i_cache;
int d_tlb;
cache_desc_t main_d_cache;
cache_desc_t mini_d_cache;
int rb;
wb_desc_t wb;
} sa_mmu_desc_t;
static sa_mmu_desc_t sa11xx_mmu_desc = {
32,
{32, 32, 16, CACHE_WRITE_BACK},
32,
{32, 32, 8, CACHE_WRITE_BACK},
{32, 2, 8, CACHE_WRITE_BACK},
4,
//{8, 4}, for word size
{8, 16}, //for byte size, chy 2003-07-11
};
static fault_t sa_mmu_write (ARMul_State * state, ARMword va, ARMword data,
ARMword datatype);
static fault_t sa_mmu_read (ARMul_State * state, ARMword va, ARMword * data,
ARMword datatype);
static fault_t update_cache (ARMul_State * state, ARMword va, ARMword data,
ARMword datatype, cache_line_t * cache,
cache_s * cache_t, ARMword real_va);
void
mmu_wb_write_bytes (ARMul_State * state, wb_s * wb_t, ARMword pa,
ARMbyte * data, int n);
int
sa_mmu_init (ARMul_State * state)
{
sa_mmu_desc_t *desc;
cache_desc_t *c_desc;
state->mmu.control = 0x70;
state->mmu.translation_table_base = 0xDEADC0DE;
state->mmu.domain_access_control = 0xDEADC0DE;
state->mmu.fault_status = 0;
state->mmu.fault_address = 0;
state->mmu.process_id = 0;
desc = &sa11xx_mmu_desc;
if (mmu_tlb_init (I_TLB (), desc->i_tlb)) {
ERROR_LOG(ARM11, "i_tlb init %d\n", -1);
goto i_tlb_init_error;
}
c_desc = &desc->i_cache;
if (mmu_cache_init (I_CACHE (), c_desc->width, c_desc->way,
c_desc->set, c_desc->w_mode)) {
ERROR_LOG(ARM11, "i_cache init %d\n", -1);
goto i_cache_init_error;
}
if (mmu_tlb_init (D_TLB (), desc->d_tlb)) {
ERROR_LOG(ARM11, "d_tlb init %d\n", -1);
goto d_tlb_init_error;
}
c_desc = &desc->main_d_cache;
if (mmu_cache_init (MAIN_D_CACHE (), c_desc->width, c_desc->way,
c_desc->set, c_desc->w_mode)) {
ERROR_LOG(ARM11, "main_d_cache init %d\n", -1);
goto main_d_cache_init_error;
}
c_desc = &desc->mini_d_cache;
if (mmu_cache_init (MINI_D_CACHE (), c_desc->width, c_desc->way,
c_desc->set, c_desc->w_mode)) {
ERROR_LOG(ARM11, "mini_d_cache init %d\n", -1);
goto mini_d_cache_init_error;
}
if (mmu_wb_init (WB (), desc->wb.num, desc->wb.nb)) {
ERROR_LOG(ARM11, "wb init %d\n", -1);
goto wb_init_error;
}
if (mmu_rb_init (RB (), desc->rb)) {
ERROR_LOG(ARM11, "rb init %d\n", -1);
goto rb_init_error;
}
return 0;
rb_init_error:
mmu_wb_exit (WB ());
wb_init_error:
mmu_cache_exit (MINI_D_CACHE ());
mini_d_cache_init_error:
mmu_cache_exit (MAIN_D_CACHE ());
main_d_cache_init_error:
mmu_tlb_exit (D_TLB ());
d_tlb_init_error:
mmu_cache_exit (I_CACHE ());
i_cache_init_error:
mmu_tlb_exit (I_TLB ());
i_tlb_init_error:
return -1;
}
void
sa_mmu_exit (ARMul_State * state)
{
mmu_rb_exit (RB ());
mmu_wb_exit (WB ());
mmu_cache_exit (MINI_D_CACHE ());
mmu_cache_exit (MAIN_D_CACHE ());
mmu_tlb_exit (D_TLB ());
mmu_cache_exit (I_CACHE ());
mmu_tlb_exit (I_TLB ());
};
static fault_t
sa_mmu_load_instr (ARMul_State * state, ARMword va, ARMword * instr)
{
fault_t fault;
tlb_entry_t *tlb;
cache_line_t *cache;
int c; //cache bit
ARMword pa; //physical addr
static int debug_count = 0; //used for debug
DEBUG_LOG(ARM11, "va = %x\n", va);
va = mmu_pid_va_map (va);
if (MMU_Enabled) {
/*align check */
if ((va & (WORD_SIZE - 1)) && MMU_Aligned) {
DEBUG_LOG(ARM11, "align\n");
return ALIGNMENT_FAULT;
}
else
va &= ~(WORD_SIZE - 1);
/*translate tlb */
fault = translate (state, va, I_TLB (), &tlb);
if (fault) {
DEBUG_LOG(ARM11, "translate\n");
return fault;
}
/*check access */
fault = check_access (state, va, tlb, 1);
if (fault) {
DEBUG_LOG(ARM11, "check_fault\n");
return fault;
}
}
/*search cache no matter MMU enabled/disabled */
cache = mmu_cache_search (state, I_CACHE (), va);
if (cache) {
*instr = cache->data[va_cache_index (va, I_CACHE ())];
return NO_FAULT;
}
/*if MMU disabled or C flag is set alloc cache */
if (MMU_Disabled) {
c = 1;
pa = va;
}
else {
c = tlb_c_flag (tlb);
pa = tlb_va_to_pa (tlb, va);
}
if (c) {
int index;
debug_count++;
cache = mmu_cache_alloc (state, I_CACHE (), va, pa);
index = va_cache_index (va, I_CACHE ());
*instr = cache->data[va_cache_index (va, I_CACHE ())];
}
else
//*instr = mem_read_word (state, pa);
bus_read(32, pa, instr);
return NO_FAULT;
};
static fault_t
sa_mmu_read_byte (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
//ARMword temp,offset;
fault_t fault;
fault = sa_mmu_read (state, virt_addr, data, ARM_BYTE_TYPE);
return fault;
}
static fault_t
sa_mmu_read_halfword (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
//ARMword temp,offset;
fault_t fault;
fault = sa_mmu_read (state, virt_addr, data, ARM_HALFWORD_TYPE);
return fault;
}
static fault_t
sa_mmu_read_word (ARMul_State * state, ARMword virt_addr, ARMword * data)
{
return sa_mmu_read (state, virt_addr, data, ARM_WORD_TYPE);
}
static fault_t
sa_mmu_read (ARMul_State * state, ARMword va, ARMword * data,
ARMword datatype)
{
fault_t fault;
rb_entry_t *rb;
tlb_entry_t *tlb;
cache_line_t *cache;
ARMword pa, real_va, temp, offset;
DEBUG_LOG(ARM11, "va = %x\n", va);
va = mmu_pid_va_map (va);
real_va = va;
/*if MMU disabled, memory_read */
if (MMU_Disabled) {
//*data = mem_read_word(state, va);
if (datatype == ARM_BYTE_TYPE)
//*data = mem_read_byte (state, va);
bus_read(8, va, data);
else if (datatype == ARM_HALFWORD_TYPE)
//*data = mem_read_halfword (state, va);
bus_read(16, va, data);
else if (datatype == ARM_WORD_TYPE)
//*data = mem_read_word (state, va);
bus_read(32, va, data);
else {
printf ("SKYEYE:1 sa_mmu_read error: unknown data type %d\n", datatype);
// skyeye_exit (-1);
}
return NO_FAULT;
}
/*align check */
if (((va & 3) && (datatype == ARM_WORD_TYPE) && MMU_Aligned) ||
((va & 1) && (datatype == ARM_HALFWORD_TYPE) && MMU_Aligned)) {
DEBUG_LOG(ARM11, "align\n");
return ALIGNMENT_FAULT;
} // else
va &= ~(WORD_SIZE - 1);
/*translate va to tlb */
fault = translate (state, va, D_TLB (), &tlb);
if (fault) {
DEBUG_LOG(ARM11, "translate\n");
return fault;
}
/*check access permission */
fault = check_access (state, va, tlb, 1);
if (fault)
return fault;
/*search in read buffer */
rb = mmu_rb_search (RB (), va);
if (rb) {
if (rb->fault)
return rb->fault;
*data = rb->data[(va & (rb_masks[rb->type] - 1)) >> WORD_SHT];
goto datatrans;
//return 0;
};
/*search main cache */
cache = mmu_cache_search (state, MAIN_D_CACHE (), va);
if (cache) {
*data = cache->data[va_cache_index (va, MAIN_D_CACHE ())];
goto datatrans;
//return 0;
}
/*search mini cache */
cache = mmu_cache_search (state, MINI_D_CACHE (), va);
if (cache) {
*data = cache->data[va_cache_index (va, MINI_D_CACHE ())];
goto datatrans;
//return 0;
}
/*get phy_addr */
pa = tlb_va_to_pa (tlb, va);
if ((pa >= 0xe0000000) && (pa < 0xe8000000)) {
if (tlb_c_flag (tlb)) {
if (tlb_b_flag (tlb)) {
mmu_cache_soft_flush (state, MAIN_D_CACHE (),
pa);
}
else {
mmu_cache_soft_flush (state, MINI_D_CACHE (),
pa);
}
}
return NO_FAULT;
}
/*if Buffer, drain Write Buffer first */
if (tlb_b_flag (tlb))
mmu_wb_drain_all (state, WB ());
/*alloc cache or mem_read */
if (tlb_c_flag (tlb) && MMU_DCacheEnabled) {
cache_s *cache_t;
if (tlb_b_flag (tlb))
cache_t = MAIN_D_CACHE ();
else
cache_t = MINI_D_CACHE ();
cache = mmu_cache_alloc (state, cache_t, va, pa);
*data = cache->data[va_cache_index (va, cache_t)];
}
else {
//*data = mem_read_word(state, pa);
if (datatype == ARM_BYTE_TYPE)
//*data = mem_read_byte (state, pa | (real_va & 3));
bus_read(8, pa | (real_va & 3), data);
else if (datatype == ARM_HALFWORD_TYPE)
//*data = mem_read_halfword (state, pa | (real_va & 2));
bus_read(16, pa | (real_va & 2), data);
else if (datatype == ARM_WORD_TYPE)
//*data = mem_read_word (state, pa);
bus_read(32, pa, data);
else {
printf ("SKYEYE:2 sa_mmu_read error: unknown data type %d\n", datatype);
// skyeye_exit (-1);
}
return NO_FAULT;
}
datatrans:
if (datatype == ARM_HALFWORD_TYPE) {
temp = *data;
offset = (((ARMword) state->bigendSig * 2) ^ (real_va & 2)) << 3; /* bit offset into the word */
*data = (temp >> offset) & 0xffff;
}
else if (datatype == ARM_BYTE_TYPE) {
temp = *data;
offset = (((ARMword) state->bigendSig * 3) ^ (real_va & 3)) << 3; /* bit offset into the word */
*data = (temp >> offset & 0xffL);
}
end:
return NO_FAULT;
}
static fault_t
sa_mmu_write_byte (ARMul_State * state, ARMword virt_addr, ARMword data)
{
return sa_mmu_write (state, virt_addr, data, ARM_BYTE_TYPE);
}
static fault_t
sa_mmu_write_halfword (ARMul_State * state, ARMword virt_addr, ARMword data)
{
return sa_mmu_write (state, virt_addr, data, ARM_HALFWORD_TYPE);
}
static fault_t
sa_mmu_write_word (ARMul_State * state, ARMword virt_addr, ARMword data)
{
return sa_mmu_write (state, virt_addr, data, ARM_WORD_TYPE);
}
static fault_t
sa_mmu_write (ARMul_State * state, ARMword va, ARMword data, ARMword datatype)
{
tlb_entry_t *tlb;
cache_line_t *cache;
int b;
ARMword pa, real_va;
fault_t fault;
DEBUG_LOG(ARM11, "va = %x, val = %x\n", va, data);
va = mmu_pid_va_map (va);
real_va = va;
/*search instruction cache */
cache = mmu_cache_search (state, I_CACHE (), va);
if (cache) {
update_cache (state, va, data, datatype, cache, I_CACHE (),
real_va);
}
if (MMU_Disabled) {
//mem_write_word(state, va, data);
if (datatype == ARM_BYTE_TYPE)
//mem_write_byte (state, va, data);
bus_write(8, va, data);
else if (datatype == ARM_HALFWORD_TYPE)
//mem_write_halfword (state, va, data);
bus_write(16, va, data);
else if (datatype == ARM_WORD_TYPE)
//mem_write_word (state, va, data);
bus_write(32, va, data);
else {
printf ("SKYEYE:1 sa_mmu_write error: unknown data type %d\n", datatype);
// skyeye_exit (-1);
}
return NO_FAULT;
}
/*align check */
//if ((va & (WORD_SIZE - 1)) && MMU_Aligned){
if (((va & 3) && (datatype == ARM_WORD_TYPE) && MMU_Aligned) ||
((va & 1) && (datatype == ARM_HALFWORD_TYPE) && MMU_Aligned)) {
DEBUG_LOG(ARM11, "align\n");
return ALIGNMENT_FAULT;
} //else
va &= ~(WORD_SIZE - 1);
/*tlb translate */
fault = translate (state, va, D_TLB (), &tlb);
if (fault) {
DEBUG_LOG(ARM11, "translate\n");
return fault;
}
/*tlb check access */
fault = check_access (state, va, tlb, 0);
if (fault) {
DEBUG_LOG(ARM11, "check_access\n");
return fault;
}
/*search main cache */
cache = mmu_cache_search (state, MAIN_D_CACHE (), va);
if (cache) {
update_cache (state, va, data, datatype, cache,
MAIN_D_CACHE (), real_va);
}
else {
/*search mini cache */
cache = mmu_cache_search (state, MINI_D_CACHE (), va);
if (cache) {
update_cache (state, va, data, datatype, cache,
MINI_D_CACHE (), real_va);
}
}
if (!cache) {
b = tlb_b_flag (tlb);
pa = tlb_va_to_pa (tlb, va);
if (b) {
if (MMU_WBEnabled) {
if (datatype == ARM_WORD_TYPE)
mmu_wb_write_bytes (state, WB (), pa,
(ARMbyte*)&data, 4);
else if (datatype == ARM_HALFWORD_TYPE)
mmu_wb_write_bytes (state, WB (),
(pa |
(real_va & 2)),
(ARMbyte*)&data, 2);
else if (datatype == ARM_BYTE_TYPE)
mmu_wb_write_bytes (state, WB (),
(pa |
(real_va & 3)),
(ARMbyte*)&data, 1);
}
else {
if (datatype == ARM_WORD_TYPE)
//mem_write_word (state, pa, data);
bus_write(32, pa, data);
else if (datatype == ARM_HALFWORD_TYPE)
/*
mem_write_halfword (state,
(pa |
(real_va & 2)),
data);
*/
bus_write(16, pa | (real_va & 2), data);
else if (datatype == ARM_BYTE_TYPE)
/*
mem_write_byte (state,
(pa | (real_va & 3)),
data);
*/
bus_write(8, pa | (real_va & 3), data);
}
}
else {
mmu_wb_drain_all (state, WB ());
if (datatype == ARM_WORD_TYPE)
//mem_write_word (state, pa, data);
bus_write(32, pa, data);
else if (datatype == ARM_HALFWORD_TYPE)
/*
mem_write_halfword (state,
(pa | (real_va & 2)),
data);
*/
bus_write(16, pa | (real_va & 2), data);
else if (datatype == ARM_BYTE_TYPE)
/*
mem_write_byte (state, (pa | (real_va & 3)),
data);
*/
bus_write(8, pa | (real_va & 3), data);
}
}
return NO_FAULT;
}
static fault_t
update_cache (ARMul_State * state, ARMword va, ARMword data, ARMword datatype,
cache_line_t * cache, cache_s * cache_t, ARMword real_va)
{
ARMword temp, offset;
ARMword index = va_cache_index (va, cache_t);
//cache->data[index] = data;
if (datatype == ARM_WORD_TYPE)
cache->data[index] = data;
else if (datatype == ARM_HALFWORD_TYPE) {
temp = cache->data[index];
offset = (((ARMword) state->bigendSig * 2) ^ (real_va & 2)) << 3; /* bit offset into the word */
cache->data[index] =
(temp & ~(0xffffL << offset)) | ((data & 0xffffL) <<
offset);
}
else if (datatype == ARM_BYTE_TYPE) {
temp = cache->data[index];
offset = (((ARMword) state->bigendSig * 3) ^ (real_va & 3)) << 3; /* bit offset into the word */
cache->data[index] =
(temp & ~(0xffL << offset)) | ((data & 0xffL) <<
offset);
}
if (index < (cache_t->width >> (WORD_SHT + 1)))
cache->tag |= TAG_FIRST_HALF_DIRTY;
else
cache->tag |= TAG_LAST_HALF_DIRTY;
return NO_FAULT;
}
ARMword
sa_mmu_mrc (ARMul_State * state, ARMword instr, ARMword * value)
{
mmu_regnum_t creg = (mmu_regnum_t)(BITS (16, 19) & 15);
ARMword data;
switch (creg) {
case MMU_ID:
// printf("mmu_mrc read ID ");
data = 0x41007100; /* v3 */
data = state->cpu->cpu_val;
break;
case MMU_CONTROL:
// printf("mmu_mrc read CONTROL");
data = state->mmu.control;
break;
case MMU_TRANSLATION_TABLE_BASE:
// printf("mmu_mrc read TTB ");
data = state->mmu.translation_table_base;
break;
case MMU_DOMAIN_ACCESS_CONTROL:
// printf("mmu_mrc read DACR ");
data = state->mmu.domain_access_control;
break;
case MMU_FAULT_STATUS:
// printf("mmu_mrc read FSR ");
data = state->mmu.fault_status;
break;
case MMU_FAULT_ADDRESS:
// printf("mmu_mrc read FAR ");
data = state->mmu.fault_address;
break;
case MMU_PID:
data = state->mmu.process_id;
default:
printf ("mmu_mrc read UNKNOWN - reg %d\n", creg);
data = 0;
break;
}
// printf("\t\t\t\t\tpc = 0x%08x\n", state->Reg[15]);
*value = data;
return data;
}
void
sa_mmu_cache_ops (ARMul_State * state, ARMword instr, ARMword value)
{
int CRm, OPC_2;
CRm = BITS (0, 3);
OPC_2 = BITS (5, 7);
if (OPC_2 == 0 && CRm == 7) {
mmu_cache_invalidate_all (state, I_CACHE ());
mmu_cache_invalidate_all (state, MAIN_D_CACHE ());
mmu_cache_invalidate_all (state, MINI_D_CACHE ());
return;
}
if (OPC_2 == 0 && CRm == 5) {
mmu_cache_invalidate_all (state, I_CACHE ());
return;
}
if (OPC_2 == 0 && CRm == 6) {
mmu_cache_invalidate_all (state, MAIN_D_CACHE ());
mmu_cache_invalidate_all (state, MINI_D_CACHE ());
return;
}
if (OPC_2 == 1 && CRm == 6) {
mmu_cache_invalidate (state, MAIN_D_CACHE (), value);
mmu_cache_invalidate (state, MINI_D_CACHE (), value);
return;
}
if (OPC_2 == 1 && CRm == 0xa) {
mmu_cache_clean (state, MAIN_D_CACHE (), value);
mmu_cache_clean (state, MINI_D_CACHE (), value);
return;
}
if (OPC_2 == 4 && CRm == 0xa) {
mmu_wb_drain_all (state, WB ());
return;
}
ERROR_LOG(ARM11, "Unknow OPC_2 = %x CRm = %x\n", OPC_2, CRm);
}
static void
sa_mmu_tlb_ops (ARMul_State * state, ARMword instr, ARMword value)
{
int CRm, OPC_2;
CRm = BITS (0, 3);
OPC_2 = BITS (5, 7);
if (OPC_2 == 0 && CRm == 0x7) {
mmu_tlb_invalidate_all (state, I_TLB ());
mmu_tlb_invalidate_all (state, D_TLB ());
return;
}
if (OPC_2 == 0 && CRm == 0x5) {
mmu_tlb_invalidate_all (state, I_TLB ());
return;
}
if (OPC_2 == 0 && CRm == 0x6) {
mmu_tlb_invalidate_all (state, D_TLB ());
return;
}
if (OPC_2 == 1 && CRm == 0x6) {
mmu_tlb_invalidate_entry (state, D_TLB (), value);
return;
}
ERROR_LOG(ARM11, "Unknow OPC_2 = %x CRm = %x\n", OPC_2, CRm);
}
static void
sa_mmu_rb_ops (ARMul_State * state, ARMword instr, ARMword value)
{
int CRm, OPC_2;
CRm = BITS (0, 3);
OPC_2 = BITS (5, 7);
if (OPC_2 == 0x0 && CRm == 0x0) {
mmu_rb_invalidate_all (RB ());
return;
}
if (OPC_2 == 0x2) {
int idx = CRm & 0x3;
int type = ((CRm >> 2) & 0x3) + 1;
if ((idx < 4) && (type < 4))
mmu_rb_load (state, RB (), idx, type, value);
return;
}
if ((OPC_2 == 1) && (CRm < 4)) {
mmu_rb_invalidate_entry (RB (), CRm);
return;
}
ERROR_LOG(ARM11, "Unknow OPC_2 = %x CRm = %x\n", OPC_2, CRm);
}
static ARMword
sa_mmu_mcr (ARMul_State * state, ARMword instr, ARMword value)
{
mmu_regnum_t creg = (mmu_regnum_t)(BITS (16, 19) & 15);
if (!strncmp (state->cpu->cpu_arch_name, "armv4", 5)) {
switch (creg) {
case MMU_CONTROL:
// printf("mmu_mcr wrote CONTROL ");
state->mmu.control = (value | 0x70) & 0xFFFD;
break;
case MMU_TRANSLATION_TABLE_BASE:
// printf("mmu_mcr wrote TTB ");
state->mmu.translation_table_base =
value & 0xFFFFC000;
break;
case MMU_DOMAIN_ACCESS_CONTROL:
// printf("mmu_mcr wrote DACR ");
state->mmu.domain_access_control = value;
break;
case MMU_FAULT_STATUS:
state->mmu.fault_status = value & 0xFF;
break;
case MMU_FAULT_ADDRESS:
state->mmu.fault_address = value;
break;
case MMU_CACHE_OPS:
sa_mmu_cache_ops (state, instr, value);
break;
case MMU_TLB_OPS:
sa_mmu_tlb_ops (state, instr, value);
break;
case MMU_SA_RB_OPS:
sa_mmu_rb_ops (state, instr, value);
break;
case MMU_SA_DEBUG:
break;
case MMU_SA_CP15_R15:
break;
case MMU_PID:
//2004-06-06 lyh, bug provided by wen ye wenye@cs.ucsb.edu
state->mmu.process_id = value & 0x7e000000;
break;
default:
printf ("mmu_mcr wrote UNKNOWN - reg %d\n", creg);
break;
}
}
return 0;
}
//teawater add for arm2x86 2005.06.24-------------------------------------------
static int
sa_mmu_v2p_dbct (ARMul_State * state, ARMword virt_addr, ARMword * phys_addr)
{
fault_t fault;
tlb_entry_t *tlb;
virt_addr = mmu_pid_va_map (virt_addr);
if (MMU_Enabled) {
/*align check */
if ((virt_addr & (WORD_SIZE - 1)) && MMU_Aligned) {
DEBUG_LOG(ARM11, "align\n");
return ALIGNMENT_FAULT;
}
else
virt_addr &= ~(WORD_SIZE - 1);
/*translate tlb */
fault = translate (state, virt_addr, I_TLB (), &tlb);
if (fault) {
DEBUG_LOG(ARM11, "translate\n");
return fault;
}
/*check access */
fault = check_access (state, virt_addr, tlb, 1);
if (fault) {
DEBUG_LOG(ARM11, "check_fault\n");
return fault;
}
}
if (MMU_Disabled) {
*phys_addr = virt_addr;
}
else {
*phys_addr = tlb_va_to_pa (tlb, virt_addr);
}
return (0);
}
//AJ2D--------------------------------------------------------------------------
/*sa mmu_ops_t*/
mmu_ops_t sa_mmu_ops = {
sa_mmu_init,
sa_mmu_exit,
sa_mmu_read_byte,
sa_mmu_write_byte,
sa_mmu_read_halfword,
sa_mmu_write_halfword,
sa_mmu_read_word,
sa_mmu_write_word,
sa_mmu_load_instr,
sa_mmu_mcr,
sa_mmu_mrc,
//teawater add for arm2x86 2005.06.24-------------------------------------------
sa_mmu_v2p_dbct,
//AJ2D--------------------------------------------------------------------------
};

View File

@ -1,58 +0,0 @@
/*
sa_mmu.h - StrongARM Memory Management Unit emulation.
ARMulator extensions for SkyEye.
<lyhost@263.net>
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 _SA_MMU_H_
#define _SA_MMU_H_
/**
* The interface of read data from bus
*/
int bus_read(short size, int addr, uint32_t * value);
/**
* The interface of write data from bus
*/
int bus_write(short size, int addr, uint32_t value);
typedef struct sa_mmu_s
{
tlb_s i_tlb;
cache_s i_cache;
tlb_s d_tlb;
cache_s main_d_cache;
cache_s mini_d_cache;
rb_s rb_t;
wb_s wb_t;
} sa_mmu_t;
#define I_TLB() (&state->mmu.u.sa_mmu.i_tlb)
#define I_CACHE() (&state->mmu.u.sa_mmu.i_cache)
#define D_TLB() (&state->mmu.u.sa_mmu.d_tlb)
#define MAIN_D_CACHE() (&state->mmu.u.sa_mmu.main_d_cache)
#define MINI_D_CACHE() (&state->mmu.u.sa_mmu.mini_d_cache)
#define WB() (&state->mmu.u.sa_mmu.wb_t)
#define RB() (&state->mmu.u.sa_mmu.rb_t)
extern mmu_ops_t sa_mmu_ops;
#endif /*_SA_MMU_H_*/

View File

@ -1,307 +0,0 @@
#include <assert.h>
#include "core/arm/skyeye_common/armdefs.h"
ARMword tlb_masks[] = {
0x00000000, /* TLB_INVALID */
0xFFFFF000, /* TLB_SMALLPAGE */
0xFFFF0000, /* TLB_LARGEPAGE */
0xFFF00000, /* TLB_SECTION */
0xFFFFF000, /*TLB_ESMALLPAGE, have TEX attirbute, only for XScale */
0xFFFFFC00 /* TLB_TINYPAGE */
};
/* This function encodes table 8-2 Interpreting AP bits,
returning non-zero if access is allowed. */
static int
check_perms (ARMul_State * state, int ap, int read)
{
int s, r, user;
s = state->mmu.control & CONTROL_SYSTEM;
r = state->mmu.control & CONTROL_ROM;
//chy 2006-02-15 , should consider system mode, don't conside 26bit mode
user = (state->Mode == USER32MODE) || (state->Mode == USER26MODE) || (state->Mode == SYSTEM32MODE);
switch (ap) {
case 0:
return read && ((s && !user) || r);
case 1:
return !user;
case 2:
return read || !user;
case 3:
return 1;
}
return 0;
}
fault_t
check_access (ARMul_State * state, ARMword virt_addr, tlb_entry_t * tlb,
int read)
{
int access;
state->mmu.last_domain = tlb->domain;
access = (state->mmu.domain_access_control >> (tlb->domain * 2)) & 3;
if ((access == 0) || (access == 2)) {
/* It's unclear from the documentation whether this
should always raise a section domain fault, or if
it should be a page domain fault in the case of an
L1 that describes a page table. In the ARM710T
datasheets, "Figure 8-9: Sequence for checking faults"
seems to indicate the former, while "Table 8-4: Priority
encoding of fault status" gives a value for FS[3210] in
the event of a domain fault for a page. Hmm. */
return SECTION_DOMAIN_FAULT;
}
if (access == 1) {
/* client access - check perms */
int subpage, ap;
switch (tlb->mapping) {
/*ks 2004-05-09
* only for XScale
* Extend Small Page(ESP) Format
* 31-12 bits the base addr of ESP
* 11-10 bits SBZ
* 9-6 bits TEX
* 5-4 bits AP
* 3 bit C
* 2 bit B
* 1-0 bits 11
* */
case TLB_ESMALLPAGE: //xj
subpage = 0;
//printf("TLB_ESMALLPAGE virt_addr=0x%x \n",virt_addr );
break;
case TLB_TINYPAGE:
subpage = 0;
//printf("TLB_TINYPAGE virt_addr=0x%x \n",virt_addr );
break;
case TLB_SMALLPAGE:
subpage = (virt_addr >> 10) & 3;
break;
case TLB_LARGEPAGE:
subpage = (virt_addr >> 14) & 3;
break;
case TLB_SECTION:
subpage = 3;
break;
default:
assert (0);
subpage = 0; /* cleans a warning */
}
ap = (tlb->perms >> (subpage * 2 + 4)) & 3;
if (!check_perms (state, ap, read)) {
if (tlb->mapping == TLB_SECTION) {
return SECTION_PERMISSION_FAULT;
}
else {
return SUBPAGE_PERMISSION_FAULT;
}
}
}
else { /* access == 3 */
/* manager access - don't check perms */
}
return NO_FAULT;
}
fault_t
translate (ARMul_State * state, ARMword virt_addr, tlb_s * tlb_t,
tlb_entry_t ** tlb)
{
*tlb = mmu_tlb_search (state, tlb_t, virt_addr);
if (!*tlb) {
/* walk the translation tables */
ARMword l1addr, l1desc;
tlb_entry_t entry;
l1addr = state->mmu.translation_table_base & 0xFFFFC000;
l1addr = (l1addr | (virt_addr >> 18)) & ~3;
//l1desc = mem_read_word (state, l1addr);
bus_read(32, l1addr, &l1desc);
switch (l1desc & 3) {
case 0:
/*
* according to Figure 3-9 Sequence for checking faults in arm manual,
* section translation fault should be returned here.
*/
{
return SECTION_TRANSLATION_FAULT;
}
case 3:
/* fine page table */
// dcl 2006-01-08
{
ARMword l2addr, l2desc;
l2addr = l1desc & 0xFFFFF000;
l2addr = (l2addr |
((virt_addr & 0x000FFC00) >> 8)) &
~3;
//l2desc = mem_read_word (state, l2addr);
bus_read(32, l2addr, &l2desc);
entry.virt_addr = virt_addr;
entry.phys_addr = l2desc;
entry.perms = l2desc & 0x00000FFC;
entry.domain = (l1desc >> 5) & 0x0000000F;
switch (l2desc & 3) {
case 0:
state->mmu.last_domain = entry.domain;
return PAGE_TRANSLATION_FAULT;
case 3:
entry.mapping = TLB_TINYPAGE;
break;
case 1:
// this is untested
entry.mapping = TLB_LARGEPAGE;
break;
case 2:
// this is untested
entry.mapping = TLB_SMALLPAGE;
break;
}
}
break;
case 1:
/* coarse page table */
{
ARMword l2addr, l2desc;
l2addr = l1desc & 0xFFFFFC00;
l2addr = (l2addr |
((virt_addr & 0x000FF000) >> 10)) &
~3;
//l2desc = mem_read_word (state, l2addr);
bus_read(32, l2addr, &l2desc);
entry.virt_addr = virt_addr;
entry.phys_addr = l2desc;
entry.perms = l2desc & 0x00000FFC;
entry.domain = (l1desc >> 5) & 0x0000000F;
//printf("SKYEYE:PAGE virt_addr = %x,l1desc=%x,phys_addr=%x\n",virt_addr,l1desc,entry.phys_addr);
//chy 2003-09-02 for xscale
switch (l2desc & 3) {
case 0:
state->mmu.last_domain = entry.domain;
return PAGE_TRANSLATION_FAULT;
case 3:
if (!state->is_XScale) {
state->mmu.last_domain =
entry.domain;
return PAGE_TRANSLATION_FAULT;
};
//ks 2004-05-09 xscale shold use Extend Small Page
//entry.mapping = TLB_SMALLPAGE;
entry.mapping = TLB_ESMALLPAGE; //xj
break;
case 1:
entry.mapping = TLB_LARGEPAGE;
break;
case 2:
entry.mapping = TLB_SMALLPAGE;
break;
}
}
break;
case 2:
/* section */
//printf("SKYEYE:WARNING: not implement section mapping incompletely\n");
//printf("SKYEYE:SECTION virt_addr = %x,l1desc=%x\n",virt_addr,l1desc);
//return SECTION_DOMAIN_FAULT;
//#if 0
entry.virt_addr = virt_addr;
entry.phys_addr = l1desc;
entry.perms = l1desc & 0x00000C0C;
entry.domain = (l1desc >> 5) & 0x0000000F;
entry.mapping = TLB_SECTION;
break;
//#endif
}
entry.virt_addr &= tlb_masks[entry.mapping];
entry.phys_addr &= tlb_masks[entry.mapping];
/* place entry in the tlb */
*tlb = &tlb_t->entrys[tlb_t->cycle];
tlb_t->cycle = (tlb_t->cycle + 1) % tlb_t->num;
**tlb = entry;
}
state->mmu.last_domain = (*tlb)->domain;
return NO_FAULT;
}
int
mmu_tlb_init (tlb_s * tlb_t, int num)
{
tlb_entry_t *e;
int i;
e = (tlb_entry_t *) malloc (sizeof (*e) * num);
if (e == NULL) {
ERROR_LOG(ARM11, "malloc size %d\n", sizeof (*e) * num);
goto tlb_malloc_error;
}
tlb_t->entrys = e;
for (i = 0; i < num; i++, e++)
e->mapping = TLB_INVALID;
tlb_t->cycle = 0;
tlb_t->num = num;
return 0;
tlb_malloc_error:
return -1;
}
void
mmu_tlb_exit (tlb_s * tlb_t)
{
free (tlb_t->entrys);
};
void
mmu_tlb_invalidate_all (ARMul_State * state, tlb_s * tlb_t)
{
int entry;
for (entry = 0; entry < tlb_t->num; entry++) {
tlb_t->entrys[entry].mapping = TLB_INVALID;
}
tlb_t->cycle = 0;
}
void
mmu_tlb_invalidate_entry (ARMul_State * state, tlb_s * tlb_t, ARMword addr)
{
tlb_entry_t *tlb;
tlb = mmu_tlb_search (state, tlb_t, addr);
if (tlb) {
tlb->mapping = TLB_INVALID;
}
}
tlb_entry_t *
mmu_tlb_search (ARMul_State * state, tlb_s * tlb_t, ARMword virt_addr)
{
int entry;
for (entry = 0; entry < tlb_t->num; entry++) {
tlb_entry_t *tlb;
ARMword mask;
tlb = &(tlb_t->entrys[entry]);
if (tlb->mapping == TLB_INVALID) {
continue;
}
mask = tlb_masks[tlb->mapping];
if ((virt_addr & mask) == (tlb->virt_addr & mask)) {
return tlb;
}
}
return NULL;
}

View File

@ -1,87 +0,0 @@
#ifndef _MMU_TLB_H_
#define _MMU_TLB_H_
typedef enum tlb_mapping_t
{
TLB_INVALID = 0,
TLB_SMALLPAGE = 1,
TLB_LARGEPAGE = 2,
TLB_SECTION = 3,
TLB_ESMALLPAGE = 4,
TLB_TINYPAGE = 5
} tlb_mapping_t;
extern ARMword tlb_masks[];
/* Permissions bits in a TLB entry:
*
* 31 12 11 10 9 8 7 6 5 4 3 2 1 0
* +-------------+-----+-----+-----+-----+---+---+-------+
* Page:| | ap3 | ap2 | ap1 | ap0 | C | B | |
* +-------------+-----+-----+-----+-----+---+---+-------+
*
* 31 12 11 10 9 4 3 2 1 0
* +-------------+-----+-----------------+---+---+-------+
* Section: | | AP | | C | B | |
* +-------------+-----+-----------------+---+---+-------+
*/
/*
section:
section base address [31:20]
AP - table 8-2, page 8-8
domain
C,B
page:
page base address [31:16] or [31:12]
ap[3:0]
domain (from L1)
C,B
*/
typedef struct tlb_entry_t
{
ARMword virt_addr;
ARMword phys_addr;
ARMword perms;
ARMword domain;
tlb_mapping_t mapping;
} tlb_entry_t;
typedef struct tlb_s
{
int num; /*num of tlb entry */
int cycle; /*current tlb cycle */
tlb_entry_t *entrys;
} tlb_s;
#define tlb_c_flag(tlb) \
((tlb)->perms & 0x8)
#define tlb_b_flag(tlb) \
((tlb)->perms & 0x4)
#define tlb_va_to_pa(tlb, va) ((tlb->phys_addr & tlb_masks[tlb->mapping]) | (va & ~tlb_masks[tlb->mapping]))
fault_t
check_access (ARMul_State * state, ARMword virt_addr, tlb_entry_t * tlb,
int read);
fault_t
translate (ARMul_State * state, ARMword virt_addr, tlb_s * tlb_t,
tlb_entry_t ** tlb);
int mmu_tlb_init (tlb_s * tlb_t, int num);
void mmu_tlb_exit (tlb_s * tlb_t);
void mmu_tlb_invalidate_all (ARMul_State * state, tlb_s * tlb_t);
void
mmu_tlb_invalidate_entry (ARMul_State * state, tlb_s * tlb_t, ARMword addr);
tlb_entry_t *mmu_tlb_search (ARMul_State * state, tlb_s * tlb_t,
ARMword virt_addr);
#endif /*_MMU_TLB_H_*/

View File

@ -1,149 +0,0 @@
#include "core/arm/skyeye_common/armdefs.h"
/* wb_init
* @wb_t :wb_t to init
* @num :num of entrys
* @nb :num of byte of each entry
*
* $ -1:error
* 0:ok
* */
int
mmu_wb_init (wb_s * wb_t, int num, int nb)
{
int i;
wb_entry_t *entrys, *wb;
entrys = (wb_entry_t *) malloc (sizeof (*entrys) * num);
if (entrys == NULL) {
ERROR_LOG(ARM11, "malloc size %d\n", sizeof (*entrys) * num);
goto entrys_malloc_error;
}
for (wb = entrys, i = 0; i < num; i++, wb++) {
/*chy 2004-06-06, fix bug found by wenye@cs.ucsb.edu */
//wb->data = (ARMword *)malloc(sizeof(ARMword) * nb);
wb->data = (ARMbyte *) malloc (nb);
if (wb->data == NULL) {
ERROR_LOG(ARM11, "malloc size of %d\n", nb);
goto data_malloc_error;
}
};
wb_t->first = wb_t->last = wb_t->used = 0;
wb_t->num = num;
wb_t->nb = nb;
wb_t->entrys = entrys;
return 0;
data_malloc_error:
while (--i >= 0)
free (entrys[i].data);
free (entrys);
entrys_malloc_error:
return -1;
};
/* wb_exit
* @wb_t :wb_t to exit
* */
void
mmu_wb_exit (wb_s * wb_t)
{
int i;
wb_entry_t *wb;
wb = wb_t->entrys;
for (i = 0; i < wb_t->num; i++, wb++) {
free (wb->data);
}
free (wb_t->entrys);
};
/* wb_write_words :put words in Write Buffer
* @state: ARMul_State
* @wb_t: write buffer
* @pa: physical address
* @data: data ptr
* @n number of word to write
*
* Note: write buffer merge is not implemented, can be done late
* */
void
mmu_wb_write_bytes (ARMul_State * state, wb_s * wb_t, ARMword pa,
ARMbyte * data, int n)
{
int i;
wb_entry_t *wb;
while (n) {
if (wb_t->num == wb_t->used) {
/*clean the last wb entry */
ARMword t;
wb = &wb_t->entrys[wb_t->last];
t = wb->pa;
for (i = 0; i < wb->nb; i++) {
//mem_write_byte (state, t, wb->data[i]);
bus_write(8, t, wb->data[i]);
//t += WORD_SIZE;
t++;
}
wb_t->last++;
if (wb_t->last == wb_t->num)
wb_t->last = 0;
wb_t->used--;
}
wb = &wb_t->entrys[wb_t->first];
i = (n < wb_t->nb) ? n : wb_t->nb;
wb->pa = pa;
//pa += i << WORD_SHT;
pa += i;
wb->nb = i;
//memcpy(wb->data, data, i << WORD_SHT);
memcpy (wb->data, data, i);
data += i;
n -= i;
wb_t->first++;
if (wb_t->first == wb_t->num)
wb_t->first = 0;
wb_t->used++;
};
//teawater add for set_dirty fflash cache function 2005.07.18-------------------
#ifdef DBCT
if (!skyeye_config.no_dbct) {
tb_setdirty (state, pa, NULL);
}
#endif
//AJ2D--------------------------------------------------------------------------
}
/* wb_drain_all
* @wb_t wb_t to drain
* */
void
mmu_wb_drain_all (ARMul_State * state, wb_s * wb_t)
{
ARMword pa;
wb_entry_t *wb;
int i;
while (wb_t->used) {
wb = &wb_t->entrys[wb_t->last];
pa = wb->pa;
for (i = 0; i < wb->nb; i++) {
//mem_write_byte (state, pa, wb->data[i]);
bus_write(8, pa, wb->data[i]);
//pa += WORD_SIZE;
pa++;
}
wb_t->last++;
if (wb_t->last == wb_t->num)
wb_t->last = 0;
wb_t->used--;
};
}

View File

@ -1,63 +0,0 @@
#ifndef _MMU_WB_H_
#define _MMU_WB_H_
typedef struct wb_entry_s
{
ARMword pa; //phy_addr
ARMbyte *data; //data
int nb; //number byte to write
} wb_entry_t;
typedef struct wb_s
{
int num; //number of wb_entry
int nb; //number of byte of each entry
int first; //
int last; //
int used; //
wb_entry_t *entrys;
} wb_s;
typedef struct wb_desc_s
{
int num;
int nb;
} wb_desc_t;
/* wb_init
* @wb_t :wb_t to init
* @num :num of entrys
* @nw :num of word of each entry
*
* $ -1:error
* 0:ok
* */
int mmu_wb_init (wb_s * wb_t, int num, int nb);
/* wb_exit
* @wb_t :wb_t to exit
* */
void mmu_wb_exit (wb_s * wb);
/* wb_write_bytes :put bytess in Write Buffer
* @state: ARMul_State
* @wb_t: write buffer
* @pa: physical address
* @data: data ptr
* @n number of byte to write
*
* Note: write buffer merge is not implemented, can be done late
* */
void
mmu_wb_write_bytess (ARMul_State * state, wb_s * wb_t, ARMword pa,
ARMbyte * data, int n);
/* wb_drain_all
* @wb_t wb_t to drain
* */
void mmu_wb_drain_all (ARMul_State * state, wb_s * wb_t);
#endif /*_MMU_WB_H_*/

File diff suppressed because it is too large Load Diff

View File

@ -367,7 +367,6 @@ So, if lateabtSig=1, then it means Late Abort Model(Base Updated Abort Model)
int verbose; /* non-zero means print various messages like the banner */ int verbose; /* non-zero means print various messages like the banner */
mmu_state_t mmu;
int mmu_inited; int mmu_inited;
//mem_state_t mem; //mem_state_t mem;
/*remove io_state to skyeye_mach_*.c files */ /*remove io_state to skyeye_mach_*.c files */

View File

@ -134,121 +134,4 @@ typedef enum fault_t
} fault_t; } fault_t;
typedef struct mmu_ops_s
{
/*initilization */
int (*init) (ARMul_State * state);
/*free on exit */
void (*exit) (ARMul_State * state);
/*read byte data */
fault_t (*read_byte) (ARMul_State * state, ARMword va,
ARMword * data);
/*write byte data */
fault_t (*write_byte) (ARMul_State * state, ARMword va,
ARMword data);
/*read halfword data */
fault_t (*read_halfword) (ARMul_State * state, ARMword va,
ARMword * data);
/*write halfword data */
fault_t (*write_halfword) (ARMul_State * state, ARMword va,
ARMword data);
/*read word data */
fault_t (*read_word) (ARMul_State * state, ARMword va,
ARMword * data);
/*write word data */
fault_t (*write_word) (ARMul_State * state, ARMword va,
ARMword data);
/*load instr */
fault_t (*load_instr) (ARMul_State * state, ARMword va,
ARMword * instr);
/*mcr */
ARMword (*mcr) (ARMul_State * state, ARMword instr, ARMword val);
/*mrc */
ARMword (*mrc) (ARMul_State * state, ARMword instr, ARMword * val);
/*ywc 2005-04-16 convert virtual address to physics address */
int (*v2p_dbct) (ARMul_State * state, ARMword virt_addr,
ARMword * phys_addr);
} mmu_ops_t;
#include "core/arm/interpreter/mmu/tlb.h"
#include "core/arm/interpreter/mmu/rb.h"
#include "core/arm/interpreter/mmu/wb.h"
#include "core/arm/interpreter/mmu/cache.h"
/*special process mmu.h*/
#include "core/arm/interpreter/mmu/sa_mmu.h"
//#include "core/arm/interpreter/mmu/arm7100_mmu.h"
//#include "core/arm/interpreter/mmu/arm920t_mmu.h"
//#include "core/arm/interpreter/mmu/arm926ejs_mmu.h"
#include "core/arm/interpreter/mmu/arm1176jzf_s_mmu.h"
//#include "core/arm/interpreter/mmu/cortex_a9_mmu.h"
typedef struct mmu_state_t
{
ARMword control;
ARMword translation_table_base;
/* dyf 201-08-11 for arm1176 */
ARMword auxiliary_control;
ARMword coprocessor_access_control;
ARMword translation_table_base0;
ARMword translation_table_base1;
ARMword translation_table_ctrl;
/* arm1176 end */
ARMword domain_access_control;
ARMword fault_status;
ARMword fault_statusi; /* prefetch fault status */
ARMword fault_address;
ARMword last_domain;
ARMword process_id;
ARMword context_id;
ARMword thread_uro_id;
ARMword cache_locked_down;
ARMword tlb_locked_down;
//chy 2003-08-24 for xscale
ARMword cache_type; // 0
ARMword aux_control; // 1
ARMword copro_access; // 15
mmu_ops_t ops;
union
{
sa_mmu_t sa_mmu;
//arm7100_mmu_t arm7100_mmu;
//arm920t_mmu_t arm920t_mmu;
//arm926ejs_mmu_t arm926ejs_mmu;
} u;
} mmu_state_t;
int mmu_init (ARMul_State * state);
int mmu_reset (ARMul_State * state);
void mmu_exit (ARMul_State * state);
fault_t mmu_read_word (ARMul_State * state, ARMword virt_addr,
ARMword * data);
fault_t mmu_write_word (ARMul_State * state, ARMword virt_addr, ARMword data);
fault_t mmu_load_instr (ARMul_State * state, ARMword virt_addr,
ARMword * instr);
ARMword mmu_mrc (ARMul_State * state, ARMword instr, ARMword * value);
void mmu_mcr (ARMul_State * state, ARMword instr, ARMword value);
/*ywc 20050416*/
int mmu_v2p_dbct (ARMul_State * state, ARMword virt_addr,
ARMword * phys_addr);
fault_t
mmu_read_byte (ARMul_State * state, ARMword virt_addr, ARMword * data);
fault_t
mmu_read_halfword (ARMul_State * state, ARMword virt_addr, ARMword * data);
fault_t
mmu_read_word (ARMul_State * state, ARMword virt_addr, ARMword * data);
fault_t
mmu_write_byte (ARMul_State * state, ARMword virt_addr, ARMword data);
fault_t
mmu_write_halfword (ARMul_State * state, ARMword virt_addr, ARMword data);
fault_t
mmu_write_word (ARMul_State * state, ARMword virt_addr, ARMword data);
#endif /* _ARMMMU_H_ */ #endif /* _ARMMMU_H_ */