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binutils-gdb/sim/bfin/dv-bfin_mmu.c
Mike Frysinger 6df01ab8ab sim: switch config.h usage to defs.h 
The defs.h header will take care of including the various config.h
headers.  For now, it's just config.h, but we'll add more when we
integrate gnulib in.

This header should be used instead of config.h, and should be the
first include in every .c file.  We won't rely on the old behavior
where we expected files to include the port's sim-main.h which then
includes the common sim-basics.h which then includes config.h.  We
have a ton of code that includes things before sim-main.h, and it
sometimes needs to be that way.  Creating a dedicated header avoids
the ordering mess and implicit inclusion that shows up otherwise.
2021-05-16 22:38:41 -04:00

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/* Blackfin Memory Management Unit (MMU) model.
Copyright (C) 2010-2021 Free Software Foundation, Inc.
Contributed by Analog Devices, Inc.
This file is part of simulators.
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 3 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, see <http://www.gnu.org/licenses/>. */
/* This must come before any other includes. */
#include "defs.h"
#include "sim-main.h"
#include "sim-options.h"
#include "devices.h"
#include "dv-bfin_mmu.h"
#include "dv-bfin_cec.h"
/* XXX: Should this really be two blocks of registers ? PRM describes
these as two Content Addressable Memory (CAM) blocks. */
struct bfin_mmu
{
bu32 base;
/* Order after here is important -- matches hardware MMR layout. */
bu32 sram_base_address;
bu32 dmem_control, dcplb_fault_status, dcplb_fault_addr;
char _dpad0[0x100 - 0x0 - (4 * 4)];
bu32 dcplb_addr[16];
char _dpad1[0x200 - 0x100 - (4 * 16)];
bu32 dcplb_data[16];
char _dpad2[0x300 - 0x200 - (4 * 16)];
bu32 dtest_command;
char _dpad3[0x400 - 0x300 - (4 * 1)];
bu32 dtest_data[2];
char _dpad4[0x1000 - 0x400 - (4 * 2)];
bu32 idk; /* Filler MMR; hardware simply ignores. */
bu32 imem_control, icplb_fault_status, icplb_fault_addr;
char _ipad0[0x100 - 0x0 - (4 * 4)];
bu32 icplb_addr[16];
char _ipad1[0x200 - 0x100 - (4 * 16)];
bu32 icplb_data[16];
char _ipad2[0x300 - 0x200 - (4 * 16)];
bu32 itest_command;
char _ipad3[0x400 - 0x300 - (4 * 1)];
bu32 itest_data[2];
};
#define mmr_base() offsetof(struct bfin_mmu, sram_base_address)
#define mmr_offset(mmr) (offsetof(struct bfin_mmu, mmr) - mmr_base())
#define mmr_idx(mmr) (mmr_offset (mmr) / 4)
static const char * const mmr_names[BFIN_COREMMR_MMU_SIZE / 4] =
{
"SRAM_BASE_ADDRESS", "DMEM_CONTROL", "DCPLB_FAULT_STATUS", "DCPLB_FAULT_ADDR",
[mmr_idx (dcplb_addr[0])] = "DCPLB_ADDR0",
"DCPLB_ADDR1", "DCPLB_ADDR2", "DCPLB_ADDR3", "DCPLB_ADDR4", "DCPLB_ADDR5",
"DCPLB_ADDR6", "DCPLB_ADDR7", "DCPLB_ADDR8", "DCPLB_ADDR9", "DCPLB_ADDR10",
"DCPLB_ADDR11", "DCPLB_ADDR12", "DCPLB_ADDR13", "DCPLB_ADDR14", "DCPLB_ADDR15",
[mmr_idx (dcplb_data[0])] = "DCPLB_DATA0",
"DCPLB_DATA1", "DCPLB_DATA2", "DCPLB_DATA3", "DCPLB_DATA4", "DCPLB_DATA5",
"DCPLB_DATA6", "DCPLB_DATA7", "DCPLB_DATA8", "DCPLB_DATA9", "DCPLB_DATA10",
"DCPLB_DATA11", "DCPLB_DATA12", "DCPLB_DATA13", "DCPLB_DATA14", "DCPLB_DATA15",
[mmr_idx (dtest_command)] = "DTEST_COMMAND",
[mmr_idx (dtest_data[0])] = "DTEST_DATA0", "DTEST_DATA1",
[mmr_idx (imem_control)] = "IMEM_CONTROL", "ICPLB_FAULT_STATUS", "ICPLB_FAULT_ADDR",
[mmr_idx (icplb_addr[0])] = "ICPLB_ADDR0",
"ICPLB_ADDR1", "ICPLB_ADDR2", "ICPLB_ADDR3", "ICPLB_ADDR4", "ICPLB_ADDR5",
"ICPLB_ADDR6", "ICPLB_ADDR7", "ICPLB_ADDR8", "ICPLB_ADDR9", "ICPLB_ADDR10",
"ICPLB_ADDR11", "ICPLB_ADDR12", "ICPLB_ADDR13", "ICPLB_ADDR14", "ICPLB_ADDR15",
[mmr_idx (icplb_data[0])] = "ICPLB_DATA0",
"ICPLB_DATA1", "ICPLB_DATA2", "ICPLB_DATA3", "ICPLB_DATA4", "ICPLB_DATA5",
"ICPLB_DATA6", "ICPLB_DATA7", "ICPLB_DATA8", "ICPLB_DATA9", "ICPLB_DATA10",
"ICPLB_DATA11", "ICPLB_DATA12", "ICPLB_DATA13", "ICPLB_DATA14", "ICPLB_DATA15",
[mmr_idx (itest_command)] = "ITEST_COMMAND",
[mmr_idx (itest_data[0])] = "ITEST_DATA0", "ITEST_DATA1",
};
#define mmr_name(off) (mmr_names[(off) / 4] ? : "<INV>")
static bool bfin_mmu_skip_cplbs = false;
static unsigned
bfin_mmu_io_write_buffer (struct hw *me, const void *source,
int space, address_word addr, unsigned nr_bytes)
{
struct bfin_mmu *mmu = hw_data (me);
bu32 mmr_off;
bu32 value;
bu32 *valuep;
/* Invalid access mode is higher priority than missing register. */
if (!dv_bfin_mmr_require_32 (me, addr, nr_bytes, true))
return 0;
value = dv_load_4 (source);
mmr_off = addr - mmu->base;
valuep = (void *)((unsigned long)mmu + mmr_base() + mmr_off);
HW_TRACE_WRITE ();
switch (mmr_off)
{
case mmr_offset(dmem_control):
case mmr_offset(imem_control):
/* XXX: IMC/DMC bit should add/remove L1 cache regions ... */
case mmr_offset(dtest_data[0]) ... mmr_offset(dtest_data[1]):
case mmr_offset(itest_data[0]) ... mmr_offset(itest_data[1]):
case mmr_offset(dcplb_addr[0]) ... mmr_offset(dcplb_addr[15]):
case mmr_offset(dcplb_data[0]) ... mmr_offset(dcplb_data[15]):
case mmr_offset(icplb_addr[0]) ... mmr_offset(icplb_addr[15]):
case mmr_offset(icplb_data[0]) ... mmr_offset(icplb_data[15]):
*valuep = value;
break;
case mmr_offset(sram_base_address):
case mmr_offset(dcplb_fault_status):
case mmr_offset(dcplb_fault_addr):
case mmr_offset(idk):
case mmr_offset(icplb_fault_status):
case mmr_offset(icplb_fault_addr):
/* Discard writes to these. */
break;
case mmr_offset(itest_command):
/* XXX: Not supported atm. */
if (value)
hw_abort (me, "ITEST_COMMAND unimplemented");
break;
case mmr_offset(dtest_command):
/* Access L1 memory indirectly. */
*valuep = value;
if (value)
{
bu32 addr = mmu->sram_base_address |
((value >> (26 - 11)) & (1 << 11)) | /* addr bit 11 (Way0/Way1) */
((value >> (24 - 21)) & (1 << 21)) | /* addr bit 21 (Data/Inst) */
((value >> (23 - 15)) & (1 << 15)) | /* addr bit 15 (Data Bank) */
((value >> (16 - 12)) & (3 << 12)) | /* addr bits 13:12 (Subbank) */
(value & 0x47F8); /* addr bits 14 & 10:3 */
if (!(value & TEST_DATA_ARRAY))
hw_abort (me, "DTEST_COMMAND tag array unimplemented");
if (value & 0xfa7cb801)
hw_abort (me, "DTEST_COMMAND bits undefined");
if (value & TEST_WRITE)
sim_write (hw_system (me), addr, (void *)mmu->dtest_data, 8);
else
sim_read (hw_system (me), addr, (void *)mmu->dtest_data, 8);
}
break;
default:
dv_bfin_mmr_invalid (me, addr, nr_bytes, true);
return 0;
}
return nr_bytes;
}
static unsigned
bfin_mmu_io_read_buffer (struct hw *me, void *dest,
int space, address_word addr, unsigned nr_bytes)
{
struct bfin_mmu *mmu = hw_data (me);
bu32 mmr_off;
bu32 *valuep;
/* Invalid access mode is higher priority than missing register. */
if (!dv_bfin_mmr_require_32 (me, addr, nr_bytes, false))
return 0;
mmr_off = addr - mmu->base;
valuep = (void *)((unsigned long)mmu + mmr_base() + mmr_off);
HW_TRACE_READ ();
switch (mmr_off)
{
case mmr_offset(dmem_control):
case mmr_offset(imem_control):
case mmr_offset(dtest_command):
case mmr_offset(dtest_data[0]) ... mmr_offset(dtest_data[2]):
case mmr_offset(itest_command):
case mmr_offset(itest_data[0]) ... mmr_offset(itest_data[2]):
/* XXX: should do something here. */
case mmr_offset(dcplb_addr[0]) ... mmr_offset(dcplb_addr[15]):
case mmr_offset(dcplb_data[0]) ... mmr_offset(dcplb_data[15]):
case mmr_offset(icplb_addr[0]) ... mmr_offset(icplb_addr[15]):
case mmr_offset(icplb_data[0]) ... mmr_offset(icplb_data[15]):
case mmr_offset(sram_base_address):
case mmr_offset(dcplb_fault_status):
case mmr_offset(dcplb_fault_addr):
case mmr_offset(idk):
case mmr_offset(icplb_fault_status):
case mmr_offset(icplb_fault_addr):
dv_store_4 (dest, *valuep);
break;
default:
dv_bfin_mmr_invalid (me, addr, nr_bytes, false);
return 0;
}
return nr_bytes;
}
static void
attach_bfin_mmu_regs (struct hw *me, struct bfin_mmu *mmu)
{
address_word attach_address;
int attach_space;
unsigned attach_size;
reg_property_spec reg;
if (hw_find_property (me, "reg") == NULL)
hw_abort (me, "Missing \"reg\" property");
if (!hw_find_reg_array_property (me, "reg", 0, &reg))
hw_abort (me, "\"reg\" property must contain three addr/size entries");
hw_unit_address_to_attach_address (hw_parent (me),
&reg.address,
&attach_space, &attach_address, me);
hw_unit_size_to_attach_size (hw_parent (me), &reg.size, &attach_size, me);
if (attach_size != BFIN_COREMMR_MMU_SIZE)
hw_abort (me, "\"reg\" size must be %#x", BFIN_COREMMR_MMU_SIZE);
hw_attach_address (hw_parent (me),
0, attach_space, attach_address, attach_size, me);
mmu->base = attach_address;
}
static void
bfin_mmu_finish (struct hw *me)
{
struct bfin_mmu *mmu;
mmu = HW_ZALLOC (me, struct bfin_mmu);
set_hw_data (me, mmu);
set_hw_io_read_buffer (me, bfin_mmu_io_read_buffer);
set_hw_io_write_buffer (me, bfin_mmu_io_write_buffer);
attach_bfin_mmu_regs (me, mmu);
/* Initialize the MMU. */
mmu->sram_base_address = 0xff800000 - 0;
/*(4 * 1024 * 1024 * CPU_INDEX (hw_system_cpu (me)));*/
mmu->dmem_control = 0x00000001;
mmu->imem_control = 0x00000001;
}
const struct hw_descriptor dv_bfin_mmu_descriptor[] =
{
{"bfin_mmu", bfin_mmu_finish,},
{NULL, NULL},
};
/* Device option parsing. */
static DECLARE_OPTION_HANDLER (bfin_mmu_option_handler);
enum {
OPTION_MMU_SKIP_TABLES = OPTION_START,
};
static const OPTION bfin_mmu_options[] =
{
{ {"mmu-skip-cplbs", no_argument, NULL, OPTION_MMU_SKIP_TABLES },
'\0', NULL, "Skip parsing of CPLB tables (big speed increase)",
bfin_mmu_option_handler, NULL },
{ {NULL, no_argument, NULL, 0}, '\0', NULL, NULL, NULL, NULL }
};
static SIM_RC
bfin_mmu_option_handler (SIM_DESC sd, sim_cpu *current_cpu, int opt,
char *arg, int is_command)
{
switch (opt)
{
case OPTION_MMU_SKIP_TABLES:
bfin_mmu_skip_cplbs = true;
return SIM_RC_OK;
default:
sim_io_eprintf (sd, "Unknown Blackfin MMU option %d\n", opt);
return SIM_RC_FAIL;
}
}
/* Provide a prototype to silence -Wmissing-prototypes. */
extern MODULE_INIT_FN sim_install_bfin_mmu;
SIM_RC
sim_install_bfin_mmu (SIM_DESC sd)
{
SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER);
return sim_add_option_table (sd, NULL, bfin_mmu_options);
}
#define MMU_STATE(cpu) DV_STATE_CACHED (cpu, mmu)
static void
_mmu_log_ifault (SIM_CPU *cpu, struct bfin_mmu *mmu, bu32 pc, bool supv)
{
mmu->icplb_fault_addr = pc;
mmu->icplb_fault_status = supv << 17;
}
void
mmu_log_ifault (SIM_CPU *cpu)
{
_mmu_log_ifault (cpu, MMU_STATE (cpu), PCREG, cec_get_ivg (cpu) >= 0);
}
static void
_mmu_log_fault (SIM_CPU *cpu, struct bfin_mmu *mmu, bu32 addr, bool write,
bool inst, bool miss, bool supv, bool dag1, bu32 faults)
{
bu32 *fault_status, *fault_addr;
/* No logging in non-OS mode. */
if (!mmu)
return;
fault_status = inst ? &mmu->icplb_fault_status : &mmu->dcplb_fault_status;
fault_addr = inst ? &mmu->icplb_fault_addr : &mmu->dcplb_fault_addr;
/* ICPLB regs always get updated. */
if (!inst)
_mmu_log_ifault (cpu, mmu, PCREG, supv);
*fault_addr = addr;
*fault_status =
(miss << 19) |
(dag1 << 18) |
(supv << 17) |
(write << 16) |
faults;
}
static void
_mmu_process_fault (SIM_CPU *cpu, struct bfin_mmu *mmu, bu32 addr, bool write,
bool inst, bool unaligned, bool miss, bool supv, bool dag1)
{
int excp;
/* See order in mmu_check_addr() */
if (unaligned)
excp = inst ? VEC_MISALI_I : VEC_MISALI_D;
else if (addr >= BFIN_SYSTEM_MMR_BASE)
excp = VEC_ILL_RES;
else if (!mmu)
excp = inst ? VEC_CPLB_I_M : VEC_CPLB_M;
else
{
/* Misses are hardware errors. */
cec_hwerr (cpu, HWERR_EXTERN_ADDR);
return;
}
_mmu_log_fault (cpu, mmu, addr, write, inst, miss, supv, dag1, 0);
cec_exception (cpu, excp);
}
void
mmu_process_fault (SIM_CPU *cpu, bu32 addr, bool write, bool inst,
bool unaligned, bool miss)
{
SIM_DESC sd = CPU_STATE (cpu);
struct bfin_mmu *mmu;
if (STATE_ENVIRONMENT (sd) != OPERATING_ENVIRONMENT)
mmu = NULL;
else
mmu = MMU_STATE (cpu);
_mmu_process_fault (cpu, mmu, addr, write, inst, unaligned, miss,
cec_is_supervisor_mode (cpu),
BFIN_CPU_STATE.multi_pc == PCREG + 6);
}
/* Return values:
-2: no known problems
-1: valid
0: miss
1: protection violation
2: multiple hits
3: unaligned
4: miss; hwerr */
static int
mmu_check_implicit_addr (SIM_CPU *cpu, bu32 addr, bool inst, int size,
bool supv, bool dag1)
{
bool l1 = ((addr & 0xFF000000) == 0xFF000000);
bu32 amask = (addr & 0xFFF00000);
if (addr & (size - 1))
return 3;
/* MMRs may never be executable or accessed from usermode. */
if (addr >= BFIN_SYSTEM_MMR_BASE)
{
if (inst)
return 0;
else if (!supv || dag1)
return 1;
else
return -1;
}
else if (inst)
{
/* Some regions are not executable. */
/* XXX: Should this be in the model data ? Core B 561 ? */
if (l1)
return (amask == 0xFFA00000) ? -1 : 1;
}
else
{
/* Some regions are not readable. */
/* XXX: Should this be in the model data ? Core B 561 ? */
if (l1)
return (amask != 0xFFA00000) ? -1 : 4;
}
return -2;
}
/* Exception order per the PRM (first has highest):
Inst Multiple CPLB Hits
Inst Misaligned Access
Inst Protection Violation
Inst CPLB Miss
Only the alignment matters in non-OS mode though. */
static int
_mmu_check_addr (SIM_CPU *cpu, bu32 addr, bool write, bool inst, int size)
{
SIM_DESC sd = CPU_STATE (cpu);
struct bfin_mmu *mmu;
bu32 *fault_status, *fault_addr, *mem_control, *cplb_addr, *cplb_data;
bu32 faults;
bool supv, do_excp, dag1;
int i, hits;
supv = cec_is_supervisor_mode (cpu);
dag1 = (BFIN_CPU_STATE.multi_pc == PCREG + 6);
if (STATE_ENVIRONMENT (sd) != OPERATING_ENVIRONMENT || bfin_mmu_skip_cplbs)
{
int ret = mmu_check_implicit_addr (cpu, addr, inst, size, supv, dag1);
/* Valid hits and misses are OK in non-OS envs. */
if (ret < 0)
return 0;
_mmu_process_fault (cpu, NULL, addr, write, inst, (ret == 3), false, supv, dag1);
}
mmu = MMU_STATE (cpu);
fault_status = inst ? &mmu->icplb_fault_status : &mmu->dcplb_fault_status;
fault_addr = inst ? &mmu->icplb_fault_addr : &mmu->dcplb_fault_addr;
mem_control = inst ? &mmu->imem_control : &mmu->dmem_control;
cplb_addr = inst ? &mmu->icplb_addr[0] : &mmu->dcplb_addr[0];
cplb_data = inst ? &mmu->icplb_data[0] : &mmu->dcplb_data[0];
faults = 0;
hits = 0;
do_excp = false;
/* CPLBs disabled -> little to do. */
if (!(*mem_control & ENCPLB))
{
hits = 1;
goto implicit_check;
}
/* Check all the CPLBs first. */
for (i = 0; i < 16; ++i)
{
const bu32 pages[4] = { 0x400, 0x1000, 0x100000, 0x400000 };
bu32 addr_lo, addr_hi;
/* Skip invalid entries. */
if (!(cplb_data[i] & CPLB_VALID))
continue;
/* See if this entry covers this address. */
addr_lo = cplb_addr[i];
addr_hi = cplb_addr[i] + pages[(cplb_data[i] & PAGE_SIZE) >> 16];
if (addr < addr_lo || addr >= addr_hi)
continue;
++hits;
faults |= (1 << i);
if (write)
{
if (!supv && !(cplb_data[i] & CPLB_USER_WR))
do_excp = true;
if (supv && !(cplb_data[i] & CPLB_SUPV_WR))
do_excp = true;
if ((cplb_data[i] & (CPLB_WT | CPLB_L1_CHBL | CPLB_DIRTY)) == CPLB_L1_CHBL)
do_excp = true;
}
else
{
if (!supv && !(cplb_data[i] & CPLB_USER_RD))
do_excp = true;
}
}
/* Handle default/implicit CPLBs. */
if (!do_excp && hits < 2)
{
int ihits;
implicit_check:
ihits = mmu_check_implicit_addr (cpu, addr, inst, size, supv, dag1);
switch (ihits)
{
/* No faults and one match -> good to go. */
case -1: return 0;
case -2:
if (hits == 1)
return 0;
break;
case 4:
cec_hwerr (cpu, HWERR_EXTERN_ADDR);
return 0;
default:
hits = ihits;
}
}
else
/* Normalize hit count so hits==2 is always multiple hit exception. */
hits = min (2, hits);
_mmu_log_fault (cpu, mmu, addr, write, inst, hits == 0, supv, dag1, faults);
if (inst)
{
int iexcps[] = { VEC_CPLB_I_M, VEC_CPLB_I_VL, VEC_CPLB_I_MHIT, VEC_MISALI_I };
return iexcps[hits];
}
else
{
int dexcps[] = { VEC_CPLB_M, VEC_CPLB_VL, VEC_CPLB_MHIT, VEC_MISALI_D };
return dexcps[hits];
}
}
void
mmu_check_addr (SIM_CPU *cpu, bu32 addr, bool write, bool inst, int size)
{
int excp = _mmu_check_addr (cpu, addr, write, inst, size);
if (excp)
cec_exception (cpu, excp);
}
void
mmu_check_cache_addr (SIM_CPU *cpu, bu32 addr, bool write, bool inst)
{
bu32 cacheaddr;
int excp;
cacheaddr = addr & ~(BFIN_L1_CACHE_BYTES - 1);
excp = _mmu_check_addr (cpu, cacheaddr, write, inst, BFIN_L1_CACHE_BYTES);
if (excp == 0)
return;
/* Most exceptions are ignored with cache funcs. */
/* XXX: Not sure if we should be ignoring CPLB misses. */
if (inst)
{
if (excp == VEC_CPLB_I_VL)
return;
}
else
{
if (excp == VEC_CPLB_VL)
return;
}
cec_exception (cpu, excp);
}
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