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/*
* besm6_mmu.c: BESM-6 fast write cache and TLB registers
*(стойка БРУС)
*
* Copyright (c) 2009, Leonid Broukhis
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* SERGE VAKULENKO OR LEONID BROUKHIS BE LIABLE FOR ANY CLAIM, DAMAGES
* OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
* ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE
* OR OTHER DEALINGS IN THE SOFTWARE.
* Except as contained in this notice, the name of Leonid Broukhis or
* Serge Vakulenko shall not be used in advertising or otherwise to promote
* the sale, use or other dealings in this Software without prior written
* authorization from Leonid Broukhis and Serge Vakulenko.
*/
#include "besm6_defs.h"
/*
* MMU data structures
*
* mmu_dev MMU device descriptor
* mmu_unit MMU unit descriptor
* mmu_reg MMU register list
*/
UNIT mmu_unit = {
UDATA (NULL, UNIT_FIX, 8)
};
t_value BRZ[8];
uint32 BAZ[8], TABST, RZ, OLDEST, FLUSH;
t_value BRS[4];
uint32 BAS[4];
uint32 BRSLRU;
/*
* 64-битные регистры RP0-RP7 - для отображения регистров приписки,
* группами по 4 ради компактности, 12 бит на страницу.
* TLB0-TLB31 - постраничные регистры приписки, копии RPi.
* Обращение к памяти должно вестись через TLBi.
*/
t_value RP[8];
uint32 TLB[32];
uint32 iintr_data; /* protected page number or parity check location */
/* There were several hardwired configurations of registers
* corresponding to up to 7 first words of the memory space, selected by
* a packet switch. Here selection 0 corresponds to settable switch registers,
* the others are hardwired.
* The configuration is selected with "SET CPU PULT=N" where 0 <= N <= 10
* is the configuration number.
*/
unsigned pult_packet_switch;
/* Location 0 of each configuration is the bitset of its hardwired locations */
t_value pult[11][8] = {
/* Switch registers */
{ 0 },
/* Hardwired program 1, a simple CU test */
{ 0376,
SET_PARITY(01240000007100002LL, PARITY_INSN), /* 1: vtm (2), vjm 2(1) */
SET_PARITY(00657777712577777LL, PARITY_INSN), /* 2: utm -1(1), utm -1(2) */
SET_PARITY(00444000317400007LL, PARITY_INSN), /* 3: mtj 3(1), vzm 7(3) */
SET_PARITY(01045000317500007LL, PARITY_INSN), /* 4: j+m 3(2), v1m 7(3)*/
SET_PARITY(00650000107700002LL, PARITY_INSN), /* 5: utm 1(1), vlm 2(1) */
SET_PARITY(01257777713400001LL, PARITY_INSN), /* 6: utm -1(2), vzm 1(2) */
SET_PARITY(00330000003000001LL, PARITY_INSN) /* 7: stop, uj 1 */
},
/* Hardwired program 2, RAM write test. The "arx" insn (cyclic add)
* in word 3 could be changed to "atx" insn (load) to use a constant
* bit pattern with a "constant/variable code" front panel switch (TODO).
* The bit pattern to use is taken from switch register 7.
*/
{ 0176,
SET_PARITY(00770000306400012LL, PARITY_INSN), /* 1: vlm 3(1), vtm 12(1) */
SET_PARITY(00010000000000010LL, PARITY_INSN), /* 2: xta 0, atx 10 */
SET_PARITY(00010001000130007LL, PARITY_INSN), /* 3: xta 10, arx 7 */
SET_PARITY(00500777700000010LL, PARITY_INSN), /* 4: atx -1(1), atx 10 */
SET_PARITY(00512777702600001LL, PARITY_INSN), /* 5: aex -1(1), uza 1 */
SET_PARITY(00737777703000001LL, PARITY_INSN) /* 6: stop -1(1), uj 1 */
},
/* Hardwired program 3, RAM read test to use after program 2, arx/atx applies */
{ 0176,
SET_PARITY(00770000306400012LL, PARITY_INSN), /* 1: vlm 3(1), vtm 12(1) */
SET_PARITY(00010000000000010LL, PARITY_INSN), /* 2: xta 0, atx 10 */
SET_PARITY(00010001000130007LL, PARITY_INSN), /* 3: xta 10, arx 7 */
SET_PARITY(00000000000000010LL, PARITY_INSN), /* 4: atx 0, atx 10 */
SET_PARITY(00512777702600001LL, PARITY_INSN), /* 5: aex -1(1), uza 1 */
SET_PARITY(00737777703000001LL, PARITY_INSN) /* 6: stop -1(1), uj 1 */
},
/* Hardwired program 4, RAM write-read test to use after program 2, arx/atx applies */
{ 0176,
SET_PARITY(00640001200100011LL, PARITY_INSN), /* 1: vtm 12(1), xta 11 */
SET_PARITY(00000001005127777LL, PARITY_INSN), /* 2: atx 10, aex -1(1) */
SET_PARITY(00260000407377777LL, PARITY_INSN), /* 3: uza 4, stop -1(1) */
SET_PARITY(00010001000130007LL, PARITY_INSN), /* 4: xta 10, arx 7 */
SET_PARITY(00500777707700002LL, PARITY_INSN), /* 5: atx -1(1), vlm 2(1) */
SET_PARITY(00300000100000000LL, PARITY_INSN) /* 6: uj 1 */
},
/* Hardwired program 5, ALU test; switch reg 7 should contain a
normalized f. p. value, e.g. 1.0 = 4050 0000 0000 0000 */
{ 0176,
SET_PARITY(00004000700000011LL, PARITY_INSN), /* 1: a+x 7, atx 11 */
SET_PARITY(00025001100000010LL, PARITY_INSN), /* 2: e-x 11, atx 10 */
SET_PARITY(00017001000160010LL, PARITY_INSN), /* 3: a*x 10, a/x 10 */
SET_PARITY(00005001000340145LL, PARITY_INSN), /* 4: a-x 10, e+n 145 */
SET_PARITY(00270000603300000LL, PARITY_INSN), /* 5: u1a 6, stop */
SET_PARITY(00010001103000001LL, PARITY_INSN) /* 6: xta 11, uj 1*/
},
/* Hardwired program 6, reading from punch tape (originally) or a disk (rework);
* various bit groups not hardwired, marked [] (TODO). Disk operation is encoded.
*/
{ 0376,
SET_PARITY(00640000300100006LL, PARITY_INSN), /* 1: vtm [3](1), xta 6 */
SET_PARITY(00433002004330020LL, PARITY_INSN), /* 2: ext 20(1), ext 20(1) */
SET_PARITY(00036015204330020LL, PARITY_INSN), /* 3: asn 152, ext 20(1) */
SET_PARITY(00010000704330000LL, PARITY_INSN), /* 4: xta 7, ext (1) */
SET_PARITY(00036014404330020LL, PARITY_INSN), /* 5: asn 144, ext 20(1) */
SET_PARITY(00330000000002401LL, PARITY_INSN), /* 6: stop, =24[01] */
SET_PARITY(04000000001400000LL, PARITY_NUMBER) /* 7: bits 37-47 not hardwired */
},
/* Hardwired program 7, RAM peek/poke, bits 1-15 of word 1 not hardwired (TODO) */
{ 0176,
},
/* Hardwired program 8, reading the test program from a fixed drum location */
{ 0036,
},
/* Hardwired program 9, drum I/O */
{ 0176,
SET_PARITY(00647774100100007LL, PARITY_INSN), /* 1: vtm -31(1), xta 7 */
SET_PARITY(00033000212460000LL, PARITY_INSN), /* 2: ext 2, vtm 60000(2) */
SET_PARITY(00040000013700003LL, PARITY_INSN), /* 3: ati, vlm 3(2) */
SET_PARITY(00013000607700002LL, PARITY_INSN), /* 4: arx 6, vlm 2(1) */
SET_PARITY(00330000103000005LL, PARITY_INSN), /* 5: stop 1, uj 5 */
SET_PARITY(00000000000010001LL, PARITY_NUMBER) /* 6: =10001 */
},
/* Hardwired program 10, magtape read */
{ 0176,
},
};
#define ORDATAVM(nm,loc,wd) REGDATA(nm,(loc),8,wd,0,1,NULL,NULL,REG_VMIO,0,0)
#define ORDATAH(nm,loc,wd) REGDATA(nm,(loc),8,wd,0,1,NULL,NULL,REG_HIDDEN,0,0)
REG mmu_reg[] = {
{ ORDATAVM ( "БРЗ0", BRZ[0], 50) }, /* Буферные регистры записи */
{ ORDATAVM ( "БРЗ1", BRZ[1], 50) },
{ ORDATAVM ( "БРЗ2", BRZ[2], 50) },
{ ORDATAVM ( "БРЗ3", BRZ[3], 50) },
{ ORDATAVM ( "БРЗ4", BRZ[4], 50) },
{ ORDATAVM ( "БРЗ5", BRZ[5], 50) },
{ ORDATAVM ( "БРЗ6", BRZ[6], 50) },
{ ORDATAVM ( "БРЗ7", BRZ[7], 50) },
{ ORDATA ( "БАЗ0", BAZ[0], 16) }, /* Буферные адреса записи */
{ ORDATA ( "БАЗ1", BAZ[1], 16) },
{ ORDATA ( "БАЗ2", BAZ[2], 16) },
{ ORDATA ( "БАЗ3", BAZ[3], 16) },
{ ORDATA ( "БАЗ4", BAZ[4], 16) },
{ ORDATA ( "БАЗ5", BAZ[5], 16) },
{ ORDATA ( "БАЗ6", BAZ[6], 16) },
{ ORDATA ( "БАЗ7", BAZ[7], 16) },
{ ORDATAH ( "ТАБСТ", TABST, 28) }, /* Таблица старшинства БРЗ */
{ ORDATAH ( "ЗпТР", FLUSH, 4) }, /* Признак выталкивания БРЗ */
{ ORDATA ( "Старш", OLDEST, 3) }, /* Номер вытолкнутого БРЗ */
{ ORDATAVM ( "РП0", RP[0], 48) }, /* Регистры приписки, по 12 бит */
{ ORDATAVM ( "РП1", RP[1], 48) },
{ ORDATAVM ( "РП2", RP[2], 48) },
{ ORDATAVM ( "РП3", RP[3], 48) },
{ ORDATAVM ( "РП4", RP[4], 48) },
{ ORDATAVM ( "РП5", RP[5], 48) },
{ ORDATAVM ( "РП6", RP[6], 48) },
{ ORDATAVM ( "РП7", RP[7], 48) },
{ ORDATA ( "РЗ", RZ, 32) }, /* Регистр защиты */
{ ORDATAVM ( "ТР1", pult[0][1], 50) }, /* Тумблерные регистры */
{ ORDATAVM ( "ТР2", pult[0][2], 50) },
{ ORDATAVM ( "ТР3", pult[0][3], 50) },
{ ORDATAVM ( "ТР4", pult[0][4], 50) },
{ ORDATAVM ( "ТР5", pult[0][5], 50) },
{ ORDATAVM ( "ТР6", pult[0][6], 50) },
{ ORDATAVM ( "ТР7", pult[0][7], 50) },
{ ORDATAVM ( "БРС0", BRS[0], 50) }, /* Буферные регистры слов */
{ ORDATAVM ( "БРС1", BRS[1], 50) },
{ ORDATAVM ( "БРС2", BRS[2], 50) },
{ ORDATAVM ( "БРС3", BRS[3], 50) },
{ ORDATA ( "БАС0", BAS[0], 16) }, /* Буферные адреса слов */
{ ORDATA ( "БАС1", BAS[1], 16) },
{ ORDATA ( "БАС2", BAS[2], 16) },
{ ORDATA ( "БАС3", BAS[3], 16) },
{ ORDATA ( "БРСст", BRSLRU, 6) },
{ 0 }
};
#define CACHE_ENB 1
MTAB mmu_mod[] = {
{ 1, 0, "NOCACHE", "NOCACHE" },
{ 1, 1, "CACHE", "CACHE" },
{ 0 }
};
t_stat mmu_reset (DEVICE *dptr);
t_stat mmu_examine (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw)
{
mmu_print_brz();
return SCPE_NOFNC;
}
DEVICE mmu_dev = {
"MMU", &mmu_unit, mmu_reg, mmu_mod,
1, 8, 3, 1, 8, 50,
&mmu_examine, NULL, &mmu_reset,
NULL, NULL, NULL, NULL,
DEV_DEBUG
};
/*
* Reset routine
*/
t_stat mmu_reset (DEVICE *dptr)
{
int i;
for (i = 0; i < 8; ++i) {
BRZ[i] = RP[i] = BAZ[i] = 0;
}
TABST = 0;
OLDEST = 0;
FLUSH = 0;
RZ = 0;
/*
* Front panel switches survive the reset
*/
sim_cancel (&mmu_unit);
return SCPE_OK;
}
#define loses_to_all(i) ((TABST & win_mask[i]) == 0 && \
(TABST & lose_mask[i]) == lose_mask[i])
/*
* N wins over M if the bit is set
* M=1 2 3 4 5 6 7
* N -------------------------
* 0| 0 1 2 3 4 5 6
* 1| 7 8 9 10 11 12
* 2| 13 14 15 16 17
* 3| 18 19 20 21
* 4| 22 23 24
* 5| 25 26
* 6| 27
*/
static unsigned win_mask[8] = {
0177,
0077 << 7,
0037 << 13,
0017 << 18,
0007 << 22,
0003 << 25,
0001 << 27,
0
};
static unsigned lose_mask[8] = {
0,
1<<0,
1<<1|1<<7,
1<<2|1<<8|1<<13,
1<<3|1<<9|1<<14|1<<18,
1<<4|1<<10|1<<15|1<<19|1<<22,
1<<5|1<<11|1<<16|1<<20|1<<23|1<<25,
1<<6|1<<12|1<<17|1<<21|1<<24|1<<26|1<<27
};
#define set_wins(i) TABST = (TABST & ~lose_mask[i]) | win_mask[i]
void mmu_protection_check (int addr)
{
/* Защита блокируется в режиме супервизора для физических (!) адресов 1-7 (ТО-8) - WTF? */
int tmp_prot_disabled = (M[PSW] & PSW_PROT_DISABLE) ||
(IS_SUPERVISOR (RUU) && (M[PSW] & PSW_MMAP_DISABLE) && addr < 010);
/* Защита не заблокирована, а лист закрыт */
if (! tmp_prot_disabled && (RZ & (1 << (addr >> 10)))) {
iintr_data = addr >> 10;
if (mmu_dev.dctrl)
besm6_debug ("--- (%05o) защита числа", addr);
longjmp (cpu_halt, STOP_OPERAND_PROT);
}
}
void mmu_flush (int idx)
{
int waddr = BAZ[idx];
if (! BAZ[idx]) {
/* Был пуст после сброса или выталкивания */
return;
}
/* Вычисляем физический адрес выталкиваемого БРЗ */
waddr = (waddr > 0100000) ? (waddr - 0100000) :
(waddr & 01777) | (TLB[waddr >> 10] << 10);
memory[waddr] = BRZ[idx];
BAZ[idx] = 0;
if (sim_log && mmu_dev.dctrl) {
fprintf (sim_log, "--- (%05o) запись ", waddr);
fprint_sym (sim_log, 0, &BRZ[idx], 0, 0);
fprintf (sim_log, " из БРЗ[%d]\n", idx);
}
}
void mmu_update_oldest ()
{
int i;
for (i = 0; i < 8; ++i) {
if (loses_to_all(i)) {
OLDEST = i;
// fprintf(stderr, "Oldest = %d\r\n", i);
return;
}
}
}
int mmu_match (int addr, int fail)
{
int i;
for (i = 0; i < 8; ++i) {
if (addr == BAZ[i]) {
return i;
}
}
return fail;
}
/*
* Разнообразные алгоритмы выталкивания БРЗ путем записи
* по адресам пультовых регистров. Тест УУ проходит дальше всего
* с mmu_flush_by_age().
*/
void mmu_flush_by_age()
{
switch (FLUSH) {
case 0:
break;
case 1: case 2: case 3: case 4: case 5: case 6: case 7: case 8:
set_wins (OLDEST);
mmu_update_oldest ();
mmu_flush (OLDEST);
if (FLUSH == 7) {
TABST = 0;
OLDEST = 0;
}
break;
}
++FLUSH;
}
void mmu_flush_by_number()
{
switch (FLUSH) {
case 0:
break;
case 1: case 2: case 3: case 4: case 5: case 6: case 7: case 8:
mmu_flush (FLUSH-1);
set_wins (FLUSH-1);
if (FLUSH-1 == OLDEST)
mmu_update_oldest ();
if (FLUSH == 7) {
TABST = 0;
OLDEST = 0;
}
break;
}
++FLUSH;
}
/*
* Запись слова в память
*/
void mmu_store (int addr, t_value val)
{
int matching;
addr &= BITS(15);
if (addr == 0)
return;
if (sim_log && mmu_dev.dctrl) {
fprintf (sim_log, "--- (%05o) запись ", addr);
fprint_sym (sim_log, 0, &val, 0, 0);
fprintf (sim_log, "\n");
}
mmu_protection_check (addr);
/* Различаем адреса с припиской и без */
if (M[PSW] & PSW_MMAP_DISABLE)
addr |= 0100000;
/* ЗПСЧ: ЗП */
if (M[DWP] == addr && (M[PSW] & PSW_WRITE_WATCH))
longjmp(cpu_halt, STOP_STORE_ADDR_MATCH);
if (sim_brk_summ & SWMASK('W') &&
sim_brk_test (addr, SWMASK('W')))
longjmp(cpu_halt, STOP_WWATCH);
if (!(mmu_unit.flags & CACHE_ENB)) {
static int roundrobin;
int faked = (++roundrobin ^ addr ^ val) & 7;
if (addr > 0100000 && addr < 0100010)
return;
BRZ[faked] = SET_PARITY (val, RUU ^ PARITY_INSN);
BAZ[faked] = addr;
mmu_flush (faked);
return;
}
/* Запись в тумблерные регистры - выталкивание БРЗ */
if (addr > 0100000 && addr < 0100010) {
mmu_flush_by_age();
return;
} else
FLUSH = 0;
matching = mmu_match(addr, OLDEST);
BRZ[matching] = SET_PARITY (val, RUU ^ PARITY_INSN);
BAZ[matching] = addr;
set_wins (matching);
if (matching == OLDEST) {
mmu_update_oldest ();
mmu_flush (OLDEST);
}
}
t_value mmu_memaccess (int addr)
{
t_value val;
/* Вычисляем физический адрес слова */
addr = (addr > 0100000) ? (addr - 0100000) :
(addr & 01777) | (TLB[addr >> 10] << 10);
if (addr >= 010) {
/* Из памяти */
val = memory[addr];
} else {
/* С тумблерных регистров */
if (mmu_dev.dctrl)
besm6_debug("--- (%05o) чтение ТР%o", PC, addr);
if ((pult[pult_packet_switch][0] >> addr) & 1) {
/* hardwired */
val = pult[pult_packet_switch][addr];
} else {
/* from switch regs */
val = pult[0][addr];
}
}
if (sim_log && (mmu_dev.dctrl || (cpu_dev.dctrl && sim_deb))) {
fprintf (sim_log, "--- (%05o) чтение ", addr & BITS(15));
fprint_sym (sim_log, 0, &val, 0, 0);
fprintf (sim_log, "\n");
}
/* На тумблерных регистрах контроля числа не бывает */
if (addr >= 010 && ! IS_NUMBER (val)) {
iintr_data = addr & 7;
besm6_debug ("--- (%05o) контроль числа", addr);
longjmp (cpu_halt, STOP_RAM_CHECK);
}
return val;
}
/*
* Чтение операнда
*/
t_value mmu_load (int addr)
{
int matching = -1;
t_value val;
addr &= BITS(15);
if (addr == 0)
return 0;
mmu_protection_check (addr);
/* Различаем адреса с припиской и без */
if (M[PSW] & PSW_MMAP_DISABLE)
addr |= 0100000;
/* ЗПСЧ: СЧ */
if (M[DWP] == addr && !(M[PSW] & PSW_WRITE_WATCH))
longjmp(cpu_halt, STOP_LOAD_ADDR_MATCH);
if (sim_brk_summ & SWMASK('R') &&
sim_brk_test (addr, SWMASK('R')))
longjmp(cpu_halt, STOP_RWATCH);
if (!(mmu_unit.flags & CACHE_ENB)) {
return mmu_memaccess (addr) & BITS48;
}
matching = mmu_match(addr, -1);
if (matching == -1) {
val = mmu_memaccess (addr);
} else {
/* старшинство обновляется, только если оно не затрагивает
* старший БРЗ (ТО-2).
*/
if (matching != OLDEST)
set_wins (matching);
val = BRZ[matching];
if (sim_log && (mmu_dev.dctrl || (cpu_dev.dctrl && sim_deb))) {
fprintf (sim_log, "--- (%05o) чтение ", addr & BITS(15));
fprint_sym (sim_log, 0, &val, 0, 0);
fprintf (sim_log, " из БРЗ\n");
}
if (! IS_NUMBER (val)) {
iintr_data = matching;
besm6_debug ("--- (%05o) контроль числа БРЗ", addr);
longjmp (cpu_halt, STOP_CACHE_CHECK);
}
}
return val & BITS48;
}
/* A little BRS LRU table */
#define brs_loses_to_all(i) ((BRSLRU & brs_win_mask[i]) == 0 && \
(BRSLRU & brs_lose_mask[i]) == brs_lose_mask[i])
/*
* N wins over M if the bit is set
* M=1 2 3
* N ---------
* 0| 0 1 2
* 1| 3 4
* 2| 5
*/
static unsigned brs_win_mask[4] = {
07,
03 << 3,
01 << 5,
0
};
static unsigned brs_lose_mask[8] = {
0,
1<<0,
1<<1|1<<3,
1<<2|1<<4|1<<5
};
#define brs_set_wins(i) BRSLRU = (BRSLRU & ~brs_lose_mask[i]) | brs_win_mask[i]
void mmu_fetch_check (int addr)
{
/* В режиме супервизора защиты нет */
if (! IS_SUPERVISOR(RUU)) {
int page = TLB[addr >> 10];
/*
* Для команд в режиме пользователя признак защиты -
* 0 в регистре приписки.
*/
if (page == 0) {
iintr_data = addr >> 10;
if (mmu_dev.dctrl)
besm6_debug ("--- (%05o) защита команды", addr);
longjmp (cpu_halt, STOP_INSN_PROT);
}
}
}
/*
* Предвыборка команды на БРС
*/
t_value mmu_prefetch (int addr, int actual)
{
t_value val;
int i;
if (mmu_unit.flags & CACHE_ENB) {
for (i = 0; i < 4; ++i) {
if (BAS[i] == addr) {
if (actual) {
brs_set_wins (i);
}
return BRS[i];
}
}
for (i = 0; i < 4; ++i) {
if (brs_loses_to_all (i)) {
BAS[i] = addr;
if (actual) {
brs_set_wins (i);
}
break;
}
}
} else if (!actual) {
return 0;
} else {
/* Чтобы лампочки мигали */
i = addr & 3;
}
if (addr < 0100000) {
int page = TLB[addr >> 10];
/* Вычисляем физический адрес слова */
addr = (addr & 01777) | (page << 10);
} else {
addr = addr & BITS(15);
}
if (addr < 010) {
if ((pult[pult_packet_switch][0] >> addr) & 1) {
/* hardwired */
val = pult[pult_packet_switch][addr];
} else {
/* from switch regs */
val = pult[0][addr];
}
} else
val = memory[addr];
BRS[i] = val;
return val;
}
/*
* Выборка команды
*/
t_value mmu_fetch (int addr)
{
t_value val;
if (addr == 0) {
if (mmu_dev.dctrl)
besm6_debug ("--- передача управления на 0");
longjmp (cpu_halt, STOP_INSN_CHECK);
}
mmu_fetch_check(addr);
/* Различаем адреса с припиской и без */
if (IS_SUPERVISOR (RUU))
addr |= 0100000;
/* КРА */
if (M[IBP] == addr)
longjmp(cpu_halt, STOP_INSN_ADDR_MATCH);
val = mmu_prefetch(addr, 1);
if (sim_log && mmu_dev.dctrl) {
fprintf (sim_log, "--- (%05o) выборка ", addr);
fprint_sym (sim_log, 0, &val, 0, SWMASK ('I'));
fprintf (sim_log, "\n");
}
/* Тумблерные регистры пока только с командной сверткой */
if (addr >= 010 && ! IS_INSN (val)) {
besm6_debug ("--- (%05o) контроль команды", addr);
longjmp (cpu_halt, STOP_INSN_CHECK);
}
return val & BITS48;
}
void mmu_setrp (int idx, t_value val)
{
uint32 p0, p1, p2, p3;
const uint32 mask = (MEMSIZE >> 10) - 1;
/* Младшие 5 разрядов 4-х регистров приписки упакованы
* по 5 в 1-20 рр, 6-е разряды - в 29-32 рр, 7-е разряды - в 33-36 рр и т.п.
*/
p0 = (val & 037) | (((val>>28) & 1) << 5) | (((val>>32) & 1) << 6) |
(((val>>36) & 1) << 7) | (((val>>40) & 1) << 8) | (((val>>44) & 1) << 9);
p1 = ((val>>5) & 037) | (((val>>29) & 1) << 5) | (((val>>33) & 1) << 6) |
(((val>>37) & 1) << 7) | (((val>>41) & 1) << 8) | (((val>>45) & 1) << 9);
p2 = ((val>>10) & 037) | (((val>>30) & 1) << 5) | (((val>>34) & 1) << 6) |
(((val>>38) & 1) << 7) | (((val>>42) & 1) << 8) | (((val>>46) & 1) << 9);
p3 = ((val>>15) & 037) | (((val>>31) & 1) << 5) | (((val>>35) & 1) << 6) |
(((val>>39) & 1) << 7) | (((val>>43) & 1) << 8) | (((val>>47) & 1) << 9);
p0 &= mask;
p1 &= mask;
p2 &= mask;
p3 &= mask;
RP[idx] = p0 | p1 << 12 | p2 << 24 | (t_value) p3 << 36;
TLB[idx*4] = p0;
TLB[idx*4+1] = p1;
TLB[idx*4+2] = p2;
TLB[idx*4+3] = p3;
}
void mmu_setup ()
{
const uint32 mask = (MEMSIZE >> 10) - 1;
int i;
/* Перепись РПi в TLBj. */
for (i=0; i<8; ++i) {
TLB[i*4] = RP[i] & mask;
TLB[i*4+1] = RP[i] >> 12 & mask;
TLB[i*4+2] = RP[i] >> 24 & mask;
TLB[i*4+3] = RP[i] >> 36 & mask;
}
}
void mmu_setprotection (int idx, t_value val)
{
/* Разряды сумматора, записываемые в регистр защиты - 21-28 */
int mask = 0xff << (idx * 8);
val = ((val >> 20) & 0xff) << (idx * 8);
RZ = (uint32)((RZ & ~mask) | val);
}
void mmu_setcache (int idx, t_value val)
{
BRZ[idx] = SET_PARITY (val, RUU ^ PARITY_INSN);
}
t_value mmu_getcache (int idx)
{
return BRZ[idx] & BITS48;
}
void mmu_print_brz ()
{
int i, k;
for (i=7; i>=0; --i) {
besm6_log_cont ("БРЗ [%d] = '", i);
for (k=47; k>=0; --k)
besm6_log_cont ("%c", (BRZ[i] >> k & 1) ? '*' : ' ');
besm6_log ("'");
}
}