/* pdp11_cpu.c: PDP-11 CPU simulator | |
Copyright (c) 1993-2001, Robert M Supnik | |
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 | |
ROBERT M SUPNIK 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 Robert M Supnik shall not | |
be used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from Robert M Supnik. | |
cpu PDP-11 CPU (J-11 microprocessor) | |
10-Aug-01 RMS Removed register from declarations | |
17-Jul-01 RMS Fixed warning from VC++ 6.0 | |
01-Jun-01 RMS Added DZ11 support | |
23-Apr-01 RMS Added RK611 support | |
05-Apr-01 RMS Added TS11/TSV05 support | |
05-Mar-01 RMS Added clock calibration support | |
11-Feb-01 RMS Added DECtape support | |
25-Jan-01 RMS Fixed 4M memory definition (found by Eric Smith) | |
14-Apr-99 RMS Changed t_addr to unsigned | |
18-Aug-98 RMS Added CIS support | |
09-May-98 RMS Fixed bug in DIV overflow test | |
19-Jan-97 RMS Added RP/RM support | |
06-Apr-96 RMS Added dynamic memory sizing | |
29-Feb-96 RMS Added TM11 support | |
17-Jul-94 RMS Corrected updating of MMR1 if MMR0 locked | |
The register state for the PDP-11 is: | |
REGFILE[0:5][0] general register set | |
REGFILE[0:5][1] alternate general register set | |
STACKFILE[4] stack pointers for kernel, supervisor, unused, user | |
PC program counter | |
PSW processor status word | |
<15:14> = CM current processor mode | |
<13:12> = PM previous processor mode | |
<11> = RS register set select | |
<7:5> = IPL interrupt priority level | |
<4> = TBIT trace trap enable | |
<3:0> = NZVC condition codes | |
FR[0:5] floating point accumulators | |
FPS floating point status register | |
FEC floating exception code | |
FEA floating exception address | |
MMR0,1,2,3 memory management control registers | |
APRFILE[0:63] memory management relocation registers for | |
kernel, supervisor, unused, user | |
<31:16> = PAR processor address registers | |
<15:0> = PDR processor data registers | |
PIRQ processor interrupt request register | |
CPUERR CPU error register | |
MEMERR memory system error register | |
CCR cache control register | |
MAINT maintenance register | |
HITMISS cache status register | |
SR switch register | |
DR display register | |
*/ | |
/* The PDP-11 has many instruction formats: | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ double operand | |
| opcode | source spec | dest spec | 010000:067777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ 110000:167777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ register + operand | |
| opcode | src reg| dest spec | 004000:004777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ 070000:077777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ single operand | |
| opcode | dest spec | 000100:000177 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ 000300:000377 | |
005000:007777 | |
105000:107777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ single register | |
| opcode |dest reg| 000200:000207 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ 000230:000237 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ no operand | |
| opcode | 000000:000007 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ branch | |
| opcode | branch displacement | 000400:003477 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ 100000:103477 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ EMT/TRAP | |
| opcode | trap code | 104000:104777 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ cond code operator | |
| opcode | immediate | 000240:000277 | |
+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+ | |
An operand specifier consists of an addressing mode and a register. | |
The addressing modes are: | |
0 register direct R op = R | |
1 register deferred (R) op = M[R] | |
2 autoincrement (R)+ op = M[R]; R = R + length | |
3 autoincrement deferred @(R)+ op = M[M[R]]; R = R + 2 | |
4 autodecrement -(R) R = R - length; op = M[R] | |
5 autodecrement deferred @-(R) R = R - 2; op = M[M[R]] | |
6 displacement d(R) op = M[R + disp] | |
7 displacement deferred @d(R) op = M[M[R + disp]] | |
There are eight general registers, R0-R7. R6 is the stack pointer, | |
R7 the PC. The combination of addressing modes with R7 yields: | |
27 immediate #n op = M[PC]; PC = PC + 2 | |
37 absolute @#n op = M[M[PC]]; PC = PC + 2 | |
67 relative d(PC) op = M[PC + disp] | |
77 relative deferred @d(PC) op = M[M[PC + disp]] | |
*/ | |
/* This routine is the instruction decode routine for the PDP-11. It | |
is called from the simulator control program to execute instructions | |
in simulated memory, starting at the simulated PC. It runs until an | |
enabled exception is encountered. | |
General notes: | |
1. Virtual address format. PDP-11 memory management uses the 16b | |
virtual address, the type of reference (instruction or data), and | |
the current mode, to construct the 22b physical address. To | |
package this conveniently, the simulator uses a 19b pseudo virtual | |
address, consisting of the 16b virtual address prefixed with the | |
current mode and ispace/dspace indicator. These are precalculated | |
as isenable and dsenable for ispace and dspace, respectively, and | |
must be recalculated whenever MMR0, MMR3, or PSW<cm> changes. | |
2. Traps and interrupts. Variable trap_req bit-encodes all possible | |
traps. In addition, an interrupt pending bit is encoded as the | |
lowest priority trap. Traps are processed by trap_vec and trap_clear, | |
which provide the vector and subordinate traps to clear, respectively. | |
Variable int_req bit encodes all possible interrupts. It is masked | |
under the interrupt masks, int_mask[ipl]. If any interrupt request | |
is not masked, the interrupt bit is set in trap_req. While most | |
interrupts are handled centrally, a device can supply an interrupt | |
acknowledge routine. | |
3. PSW handling. The PSW is kept as components, for easier access. | |
Because the PSW can be explicitly written as address 17777776, | |
all instructions must update PSW before executing their last write. | |
4. Adding I/O devices. This requires modifications to three modules: | |
pdp11_defs.h add interrupt request definitions | |
pdp11_cpu.c add I/O page linkages | |
pdp11_sys.c add to sim_devices | |
*/ | |
/* Definitions */ | |
#include "pdp11_defs.h" | |
#include <setjmp.h> | |
#define calc_is(md) ((md) << VA_V_MODE) | |
#define calc_ds(md) (calc_is((md)) | ((MMR3 & dsmask[(md)])? VA_DS: 0)) | |
#define calc_MMR1(val) (MMR1 = MMR1? ((val) << 8) | MMR1: (val)) | |
#define calc_ints(lv,rq,tr) (((rq) & int_mask[(lv)])? \ | |
((tr) | TRAP_INT) : ((tr) & ~TRAP_INT)) | |
#define GET_SIGN_W(v) ((v) >> 15) | |
#define GET_SIGN_B(v) ((v) >> 7) | |
#define GET_Z(v) ((v) == 0) | |
#define JMP_PC(x) old_PC = PC; PC = (x) | |
#define BRANCH_F(x) old_PC = PC; PC = (PC + (((x) + (x)) & 0377)) & 0177777 | |
#define BRANCH_B(x) old_PC = PC; PC = (PC + (((x) + (x)) | 0177400)) & 0177777 | |
#define ILL_ADR_FLAG 0200000 | |
#define save_ibkpt (cpu_unit.u3) /* will be SAVEd */ | |
#define last_pa (cpu_unit.u4) /* and RESTOREd */ | |
#define UNIT_V_18B (UNIT_V_UF) /* force 18b addr */ | |
#define UNIT_18B (1u << UNIT_V_18B) | |
#define UNIT_V_CIS (UNIT_V_UF + 1) /* CIS present */ | |
#define UNIT_CIS (1u << UNIT_V_CIS) | |
#define UNIT_V_MSIZE (UNIT_V_UF + 2) /* dummy */ | |
#define UNIT_MSIZE (1u << UNIT_V_MSIZE) | |
/* Global state */ | |
uint16 *M = NULL; /* address of memory */ | |
int32 REGFILE[6][2] = { 0 }; /* R0-R5, two sets */ | |
int32 STACKFILE[4] = { 0 }; /* SP, four modes */ | |
int32 saved_PC = 0; /* program counter */ | |
int32 R[8] = { 0 }; /* working registers */ | |
int32 PSW = 0; /* PSW */ | |
int32 cm = 0; /* current mode */ | |
int32 pm = 0; /* previous mode */ | |
int32 rs = 0; /* register set */ | |
int32 ipl = 0; /* int pri level */ | |
int32 tbit = 0; /* trace flag */ | |
int32 N = 0, Z = 0, V = 0, C = 0; /* condition codes */ | |
int32 wait_state = 0; /* wait state */ | |
int32 trap_req = 0; /* trap requests */ | |
int32 int_req = 0; /* interrupt requests */ | |
int32 PIRQ = 0; /* programmed int req */ | |
int32 SR = 0; /* switch register */ | |
int32 DR = 0; /* display register */ | |
fpac_t FR[6] = { 0 }; /* fp accumulators */ | |
int32 FPS = 0; /* fp status */ | |
int32 FEC = 0; /* fp exception code */ | |
int32 FEA = 0; /* fp exception addr */ | |
int32 APRFILE[64] = { 0 }; /* PARs/PDRs */ | |
int32 MMR0 = 0; /* MMR0 - status */ | |
int32 MMR1 = 0; /* MMR1 - R+/-R */ | |
int32 MMR2 = 0; /* MMR2 - saved PC */ | |
int32 MMR3 = 0; /* MMR3 - 22b status */ | |
int32 isenable = 0, dsenable = 0; /* i, d space flags */ | |
int32 CPUERR = 0; /* CPU error reg */ | |
int32 MEMERR = 0; /* memory error reg */ | |
int32 CCR = 0; /* cache control reg */ | |
int32 HITMISS = 0; /* hit/miss reg */ | |
int32 MAINT = (0 << 9) + (0 << 8) + (4 << 4); /* maint bit<9> = Q/U */ | |
/* <8> = hwre FP */ | |
/* <6:4> = sys type */ | |
int32 stop_trap = 1; /* stop on trap */ | |
int32 stop_vecabort = 1; /* stop on vec abort */ | |
int32 stop_spabort = 1; /* stop on SP abort */ | |
int32 wait_enable = 0; /* wait state enable */ | |
int32 ibkpt_addr = ILL_ADR_FLAG | VAMASK; /* breakpoint addr */ | |
int32 old_PC = 0; /* previous PC */ | |
int32 dev_enb = (-1) & ~INT_TS; /* dev enables */ | |
jmp_buf save_env; /* abort handler */ | |
int32 dsmask[4] = { MMR3_KDS, MMR3_SDS, 0, MMR3_UDS }; /* dspace enables */ | |
uint32 int_mask[8] = { INT_IPL0, INT_IPL1, INT_IPL2, /* interrupt masks */ | |
INT_IPL3, INT_IPL4, INT_IPL5, INT_IPL6, INT_IPL7 }; | |
extern int32 sim_int_char; | |
/* Function declarations */ | |
t_stat cpu_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat cpu_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat cpu_reset (DEVICE *dptr); | |
t_stat cpu_svc (UNIT *uptr); | |
t_stat cpu_set_size (UNIT *uptr, int32 value); | |
int32 GeteaB (int32 spec); | |
int32 GeteaW (int32 spec); | |
int32 relocR (int32 addr); | |
int32 relocW (int32 addr); | |
int32 ReadW (int32 addr); | |
int32 ReadB (int32 addr); | |
int32 ReadMW (int32 addr); | |
int32 ReadMB (int32 addr); | |
void WriteW (int32 data, int32 addr); | |
void WriteB (int32 data, int32 addr); | |
void PWriteW (int32 data, int32 addr); | |
void PWriteB (int32 data, int32 addr); | |
t_stat iopageR (int32 *data, int32 addr, int32 access); | |
t_stat iopageW (int32 data, int32 addr, int32 access); | |
t_stat CPU_rd (int32 *data, int32 addr, int32 access); | |
t_stat CPU_wr (int32 data, int32 addr, int32 access); | |
t_stat APR_rd (int32 *data, int32 addr, int32 access); | |
t_stat APR_wr (int32 data, int32 addr, int32 access); | |
t_stat SR_MMR012_rd (int32 *data, int32 addr, int32 access); | |
t_stat SR_MMR012_wr (int32 data, int32 addr, int32 access); | |
t_stat MMR3_rd (int32 *data, int32 addr, int32 access); | |
t_stat MMR3_wr (int32 data, int32 addr, int32 access); | |
extern t_stat std_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat std_wr (int32 data, int32 addr, int32 access); | |
extern t_stat lpt_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat lpt_wr (int32 data, int32 addr, int32 access); | |
extern t_stat rk_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat rk_wr (int32 data, int32 addr, int32 access); | |
extern int32 rk_inta (void); | |
/* extern t_stat hk_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat hk_wr (int32 data, int32 addr, int32 access); | |
extern int32 hk_inta (void); */ | |
extern t_stat rl_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat rl_wr (int32 data, int32 addr, int32 access); | |
extern t_stat rp_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat rp_wr (int32 data, int32 addr, int32 access); | |
extern int32 rp_inta (void); | |
extern t_stat rx_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat rx_wr (int32 data, int32 addr, int32 access); | |
extern t_stat dt_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat dt_wr (int32 data, int32 addr, int32 access); | |
extern t_stat tm_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat tm_wr (int32 data, int32 addr, int32 access); | |
extern t_stat ts_rd (int32 *data, int32 addr, int32 access); | |
extern t_stat ts_wr (int32 data, int32 addr, int32 access); | |
/* Auxiliary data structures */ | |
struct iolink { /* I/O page linkage */ | |
int32 low; /* low I/O addr */ | |
int32 high; /* high I/O addr */ | |
int32 enb; /* enable mask */ | |
t_stat (*read)(); /* read routine */ | |
t_stat (*write)(); }; /* write routine */ | |
struct iolink iotable[] = { | |
{ 017777740, 017777777, 0, &CPU_rd, &CPU_wr }, | |
{ 017777546, 017777567, 0, &std_rd, &std_wr }, | |
{ 017777514, 017777517, 0, &lpt_rd, &lpt_wr }, | |
{ 017777400, 017777417, INT_RK, &rk_rd, &rk_wr }, | |
/* { 017777440, 017777477, INT_HK, &hk_rd, &hk_wr }, */ | |
{ 017774400, 017774411, INT_RL, &rl_rd, &rl_wr }, | |
{ 017776700, 017776753, INT_RP, &rp_rd, &rp_wr }, | |
{ 017777170, 017777173, INT_RX, &rx_rd, &rx_wr }, | |
{ 017777340, 017777351, INT_DTA, &dt_rd, &dt_wr }, | |
{ 017772520, 017772533, INT_TM, &tm_rd, &tm_wr }, | |
{ 017772520, 017772523, INT_TS, &ts_rd, &ts_wr }, | |
{ 017777600, 017777677, 0, &APR_rd, &APR_wr }, | |
{ 017772200, 017772377, 0, &APR_rd, &APR_wr }, | |
{ 017777570, 017777577, 0, &SR_MMR012_rd, &SR_MMR012_wr }, | |
{ 017772516, 017772517, 0, &MMR3_rd, &MMR3_wr }, | |
{ 0, 0, 0, NULL, NULL } }; | |
int32 int_vec[32] = { /* int req to vector */ | |
0, 0, 0, VEC_PIRQ, VEC_CLK, VEC_DTA, 0, VEC_PIRQ, | |
VEC_RK, VEC_RL, VEC_RX, VEC_TM, VEC_RP, VEC_TS, VEC_HK, 0, | |
VEC_DZ0RX, VEC_DZ0TX, 0, VEC_PIRQ, VEC_TTI, VEC_TTO, VEC_PTR, VEC_PTP, | |
VEC_LPT, 0, 0, 0, VEC_PIRQ, VEC_PIRQ, VEC_PIRQ, VEC_PIRQ }; | |
int32 (*int_ack[32])() = { /* int ack routines */ | |
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, | |
&rk_inta, NULL, NULL, NULL, &rp_inta, NULL, NULL, NULL, | |
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, | |
NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL }; | |
int32 trap_vec[TRAP_V_MAX] = { /* trap req to vector */ | |
VEC_RED, VEC_ODD, VEC_MME, VEC_NXM, | |
VEC_PAR, VEC_PRV, VEC_ILL, VEC_BPT, | |
VEC_IOT, VEC_EMT, VEC_TRAP, VEC_TRC, | |
VEC_YEL, VEC_PWRFL, VEC_FPE }; | |
int32 trap_clear[TRAP_V_MAX] = { /* trap clears */ | |
TRAP_RED+TRAP_PAR+TRAP_YEL+TRAP_TRC, | |
TRAP_ODD+TRAP_PAR+TRAP_YEL+TRAP_TRC, | |
TRAP_MME+TRAP_PAR+TRAP_YEL+TRAP_TRC, | |
TRAP_NXM+TRAP_PAR+TRAP_YEL+TRAP_TRC, | |
TRAP_PAR+TRAP_TRC, TRAP_PRV+TRAP_TRC, | |
TRAP_ILL+TRAP_TRC, TRAP_BPT+TRAP_TRC, | |
TRAP_IOT+TRAP_TRC, TRAP_EMT+TRAP_TRC, | |
TRAP_TRAP+TRAP_TRC, TRAP_TRC, | |
TRAP_YEL, TRAP_PWRFL, TRAP_FPE }; | |
/* CPU data structures | |
cpu_dev CPU device descriptor | |
cpu_unit CPU unit descriptor | |
cpu_reg CPU register list | |
cpu_mod CPU modifier list | |
*/ | |
UNIT cpu_unit = { UDATA (&cpu_svc, UNIT_FIX + UNIT_BINK, INIMEMSIZE) }; | |
REG cpu_reg[] = { | |
{ ORDATA (PC, saved_PC, 16) }, | |
{ ORDATA (R0, REGFILE[0][0], 16) }, | |
{ ORDATA (R1, REGFILE[1][0], 16) }, | |
{ ORDATA (R2, REGFILE[2][0], 16) }, | |
{ ORDATA (R3, REGFILE[3][0], 16) }, | |
{ ORDATA (R4, REGFILE[4][0], 16) }, | |
{ ORDATA (R5, REGFILE[5][0], 16) }, | |
{ ORDATA (R10, REGFILE[0][1], 16) }, | |
{ ORDATA (R11, REGFILE[1][1], 16) }, | |
{ ORDATA (R12, REGFILE[2][1], 16) }, | |
{ ORDATA (R13, REGFILE[3][1], 16) }, | |
{ ORDATA (R14, REGFILE[4][1], 16) }, | |
{ ORDATA (R15, REGFILE[5][1], 16) }, | |
{ ORDATA (KSP, STACKFILE[KERNEL], 16) }, | |
{ ORDATA (SSP, STACKFILE[SUPER], 16) }, | |
{ ORDATA (USP, STACKFILE[USER], 16) }, | |
{ ORDATA (PSW, PSW, 16) }, | |
{ GRDATA (CM, PSW, 8, 2, PSW_V_CM) }, | |
{ GRDATA (PM, PSW, 8, 2, PSW_V_PM) }, | |
{ FLDATA (RS, PSW, PSW_V_RS) }, | |
{ GRDATA (IPL, PSW, 8, 3, PSW_V_IPL) }, | |
{ FLDATA (T, PSW, PSW_V_TBIT) }, | |
{ FLDATA (N, PSW, PSW_V_N) }, | |
{ FLDATA (Z, PSW, PSW_V_Z) }, | |
{ FLDATA (V, PSW, PSW_V_V) }, | |
{ FLDATA (C, PSW, PSW_V_C) }, | |
{ ORDATA (SR, SR, 16) }, | |
{ ORDATA (DR, DR, 16) }, | |
{ ORDATA (MEMERR, MEMERR, 16) }, | |
{ ORDATA (CCR, CCR, 16) }, | |
{ ORDATA (MAINT, MAINT, 16) }, | |
{ ORDATA (HITMISS, HITMISS, 16) }, | |
{ ORDATA (CPUERR, CPUERR, 16) }, | |
{ ORDATA (INT, int_req, 32), REG_RO }, | |
{ ORDATA (TRAPS, trap_req, TRAP_V_MAX) }, | |
{ ORDATA (PIRQ, PIRQ, 16) }, | |
{ FLDATA (WAIT, wait_state, 0) }, | |
{ FLDATA (WAIT_ENABLE, wait_enable, 0) }, | |
{ ORDATA (STOP_TRAPS, stop_trap, TRAP_V_MAX) }, | |
{ FLDATA (STOP_VECA, stop_vecabort, 0) }, | |
{ FLDATA (STOP_SPA, stop_spabort, 0) }, | |
{ ORDATA (FAC0H, FR[0].h, 32) }, | |
{ ORDATA (FAC0L, FR[0].l, 32) }, | |
{ ORDATA (FAC1H, FR[1].h, 32) }, | |
{ ORDATA (FAC1L, FR[1].l, 32) }, | |
{ ORDATA (FAC2H, FR[2].h, 32) }, | |
{ ORDATA (FAC2L, FR[2].l, 32) }, | |
{ ORDATA (FAC3H, FR[3].h, 32) }, | |
{ ORDATA (FAC3L, FR[3].l, 32) }, | |
{ ORDATA (FAC4H, FR[4].h, 32) }, | |
{ ORDATA (FAC4L, FR[4].l, 32) }, | |
{ ORDATA (FAC5H, FR[5].h, 32) }, | |
{ ORDATA (FAC5L, FR[5].l, 32) }, | |
{ ORDATA (FPS, FPS, 16) }, | |
{ ORDATA (FEA, FEA, 16) }, | |
{ ORDATA (FEC, FEC, 4) }, | |
{ ORDATA (MMR0, MMR0, 16) }, | |
{ ORDATA (MMR1, MMR1, 16) }, | |
{ ORDATA (MMR2, MMR2, 16) }, | |
{ ORDATA (MMR3, MMR3, 16) }, | |
{ GRDATA (KIPAR0, APRFILE[000], 8, 16, 16) }, | |
{ GRDATA (KIPDR0, APRFILE[000], 8, 16, 0) }, | |
{ GRDATA (KIPAR1, APRFILE[001], 8, 16, 16) }, | |
{ GRDATA (KIPDR1, APRFILE[001], 8, 16, 0) }, | |
{ GRDATA (KIPAR2, APRFILE[002], 8, 16, 16) }, | |
{ GRDATA (KIPDR2, APRFILE[002], 8, 16, 0) }, | |
{ GRDATA (KIPAR3, APRFILE[003], 8, 16, 16) }, | |
{ GRDATA (KIPDR3, APRFILE[003], 8, 16, 0) }, | |
{ GRDATA (KIPAR4, APRFILE[004], 8, 16, 16) }, | |
{ GRDATA (KIPDR4, APRFILE[004], 8, 16, 0) }, | |
{ GRDATA (KIPAR5, APRFILE[005], 8, 16, 16) }, | |
{ GRDATA (KIPDR5, APRFILE[005], 8, 16, 0) }, | |
{ GRDATA (KIPAR6, APRFILE[006], 8, 16, 16) }, | |
{ GRDATA (KIPDR6, APRFILE[006], 8, 16, 0) }, | |
{ GRDATA (KIPAR7, APRFILE[007], 8, 16, 16) }, | |
{ GRDATA (KIPDR7, APRFILE[007], 8, 16, 0) }, | |
{ GRDATA (KDPAR0, APRFILE[010], 8, 16, 16) }, | |
{ GRDATA (KDPDR0, APRFILE[010], 8, 16, 0) }, | |
{ GRDATA (KDPAR1, APRFILE[011], 8, 16, 16) }, | |
{ GRDATA (KDPDR1, APRFILE[011], 8, 16, 0) }, | |
{ GRDATA (KDPAR2, APRFILE[012], 8, 16, 16) }, | |
{ GRDATA (KDPDR2, APRFILE[012], 8, 16, 0) }, | |
{ GRDATA (KDPAR3, APRFILE[013], 8, 16, 16) }, | |
{ GRDATA (KDPDR3, APRFILE[013], 8, 16, 0) }, | |
{ GRDATA (KDPAR4, APRFILE[014], 8, 16, 16) }, | |
{ GRDATA (KDPDR4, APRFILE[014], 8, 16, 0) }, | |
{ GRDATA (KDPAR5, APRFILE[015], 8, 16, 16) }, | |
{ GRDATA (KDPDR5, APRFILE[015], 8, 16, 0) }, | |
{ GRDATA (KDPAR6, APRFILE[016], 8, 16, 16) }, | |
{ GRDATA (KDPDR6, APRFILE[016], 8, 16, 0) }, | |
{ GRDATA (KDPAR7, APRFILE[017], 8, 16, 16) }, | |
{ GRDATA (KDPDR7, APRFILE[017], 8, 16, 0) }, | |
{ GRDATA (SIPAR0, APRFILE[020], 8, 16, 16) }, | |
{ GRDATA (SIPDR0, APRFILE[020], 8, 16, 0) }, | |
{ GRDATA (SIPAR1, APRFILE[021], 8, 16, 16) }, | |
{ GRDATA (SIPDR1, APRFILE[021], 8, 16, 0) }, | |
{ GRDATA (SIPAR2, APRFILE[022], 8, 16, 16) }, | |
{ GRDATA (SIPDR2, APRFILE[022], 8, 16, 0) }, | |
{ GRDATA (SIPAR3, APRFILE[023], 8, 16, 16) }, | |
{ GRDATA (SIPDR3, APRFILE[023], 8, 16, 0) }, | |
{ GRDATA (SIPAR4, APRFILE[024], 8, 16, 16) }, | |
{ GRDATA (SIPDR4, APRFILE[024], 8, 16, 0) }, | |
{ GRDATA (SIPAR5, APRFILE[025], 8, 16, 16) }, | |
{ GRDATA (SIPDR5, APRFILE[025], 8, 16, 0) }, | |
{ GRDATA (SIPAR6, APRFILE[026], 8, 16, 16) }, | |
{ GRDATA (SIPDR6, APRFILE[026], 8, 16, 0) }, | |
{ GRDATA (SIPAR7, APRFILE[027], 8, 16, 16) }, | |
{ GRDATA (SIPDR7, APRFILE[027], 8, 16, 0) }, | |
{ GRDATA (SDPAR0, APRFILE[030], 8, 16, 16) }, | |
{ GRDATA (SDPDR0, APRFILE[030], 8, 16, 0) }, | |
{ GRDATA (SDPAR1, APRFILE[031], 8, 16, 16) }, | |
{ GRDATA (SDPDR1, APRFILE[031], 8, 16, 0) }, | |
{ GRDATA (SDPAR2, APRFILE[032], 8, 16, 16) }, | |
{ GRDATA (SDPDR2, APRFILE[032], 8, 16, 0) }, | |
{ GRDATA (SDPAR3, APRFILE[033], 8, 16, 16) }, | |
{ GRDATA (SDPDR3, APRFILE[033], 8, 16, 0) }, | |
{ GRDATA (SDPAR4, APRFILE[034], 8, 16, 16) }, | |
{ GRDATA (SDPDR4, APRFILE[034], 8, 16, 0) }, | |
{ GRDATA (SDPAR5, APRFILE[035], 8, 16, 16) }, | |
{ GRDATA (SDPDR5, APRFILE[035], 8, 16, 0) }, | |
{ GRDATA (SDPAR6, APRFILE[036], 8, 16, 16) }, | |
{ GRDATA (SDPDR6, APRFILE[036], 8, 16, 0) }, | |
{ GRDATA (SDPAR7, APRFILE[037], 8, 16, 16) }, | |
{ GRDATA (SDPDR7, APRFILE[037], 8, 16, 0) }, | |
{ GRDATA (UIPAR0, APRFILE[060], 8, 16, 16) }, | |
{ GRDATA (UIPDR0, APRFILE[060], 8, 16, 0) }, | |
{ GRDATA (UIPAR1, APRFILE[061], 8, 16, 16) }, | |
{ GRDATA (UIPDR1, APRFILE[061], 8, 16, 0) }, | |
{ GRDATA (UIPAR2, APRFILE[062], 8, 16, 16) }, | |
{ GRDATA (UIPDR2, APRFILE[062], 8, 16, 0) }, | |
{ GRDATA (UIPAR3, APRFILE[063], 8, 16, 16) }, | |
{ GRDATA (UIPDR3, APRFILE[063], 8, 16, 0) }, | |
{ GRDATA (UIPAR4, APRFILE[064], 8, 16, 16) }, | |
{ GRDATA (UIPDR4, APRFILE[064], 8, 16, 0) }, | |
{ GRDATA (UIPAR5, APRFILE[065], 8, 16, 16) }, | |
{ GRDATA (UIPDR5, APRFILE[065], 8, 16, 0) }, | |
{ GRDATA (UIPAR6, APRFILE[066], 8, 16, 16) }, | |
{ GRDATA (UIPDR6, APRFILE[066], 8, 16, 0) }, | |
{ GRDATA (UIPAR7, APRFILE[067], 8, 16, 16) }, | |
{ GRDATA (UIPDR7, APRFILE[067], 8, 16, 0) }, | |
{ GRDATA (UDPAR0, APRFILE[070], 8, 16, 16) }, | |
{ GRDATA (UDPDR0, APRFILE[070], 8, 16, 0) }, | |
{ GRDATA (UDPAR1, APRFILE[071], 8, 16, 16) }, | |
{ GRDATA (UDPDR1, APRFILE[071], 8, 16, 0) }, | |
{ GRDATA (UDPAR2, APRFILE[072], 8, 16, 16) }, | |
{ GRDATA (UDPDR2, APRFILE[072], 8, 16, 0) }, | |
{ GRDATA (UDPAR3, APRFILE[073], 8, 16, 16) }, | |
{ GRDATA (UDPDR3, APRFILE[073], 8, 16, 0) }, | |
{ GRDATA (UDPAR4, APRFILE[074], 8, 16, 16) }, | |
{ GRDATA (UDPDR4, APRFILE[074], 8, 16, 0) }, | |
{ GRDATA (UDPAR5, APRFILE[075], 8, 16, 16) }, | |
{ GRDATA (UDPDR5, APRFILE[075], 8, 16, 0) }, | |
{ GRDATA (UDPAR6, APRFILE[076], 8, 16, 16) }, | |
{ GRDATA (UDPDR6, APRFILE[076], 8, 16, 0) }, | |
{ GRDATA (UDPAR7, APRFILE[077], 8, 16, 16) }, | |
{ GRDATA (UDPDR7, APRFILE[077], 8, 16, 0) }, | |
{ FLDATA (18B_ADDR, cpu_unit.flags, UNIT_V_18B), REG_HRO }, | |
{ FLDATA (CIS, cpu_unit.flags, UNIT_V_CIS), REG_HRO }, | |
{ ORDATA (OLDPC, old_PC, 16), REG_RO }, | |
{ ORDATA (BREAK, ibkpt_addr, 17) }, | |
{ ORDATA (WRU, sim_int_char, 8) }, | |
{ ORDATA (DEVENB, dev_enb, 32), REG_HRO }, | |
{ NULL} }; | |
MTAB cpu_mod[] = { | |
{ UNIT_18B, UNIT_18B, "18b addressing", "18B", NULL }, | |
{ UNIT_18B, 0, NULL, "22B", NULL }, | |
{ UNIT_CIS, UNIT_CIS, "CIS", "CIS", NULL }, | |
{ UNIT_CIS, 0, "No CIS", "NOCIS", NULL }, | |
{ UNIT_MSIZE, 16384, NULL, "16K", &cpu_set_size}, | |
{ UNIT_MSIZE, 32768, NULL, "32K", &cpu_set_size}, | |
{ UNIT_MSIZE, 49152, NULL, "48K", &cpu_set_size}, | |
{ UNIT_MSIZE, 65536, NULL, "64K", &cpu_set_size}, | |
{ UNIT_MSIZE, 98304, NULL, "96K", &cpu_set_size}, | |
{ UNIT_MSIZE, 131072, NULL, "128K", &cpu_set_size}, | |
{ UNIT_MSIZE, 229376, NULL, "192K", &cpu_set_size}, | |
{ UNIT_MSIZE, 262144, NULL, "256K", &cpu_set_size}, | |
{ UNIT_MSIZE, 393216, NULL, "384K", &cpu_set_size}, | |
{ UNIT_MSIZE, 524288, NULL, "512K", &cpu_set_size}, | |
{ UNIT_MSIZE, 786432, NULL, "768K", &cpu_set_size}, | |
{ UNIT_MSIZE, 1048576, NULL, "1024K", &cpu_set_size}, | |
{ UNIT_MSIZE, 2097152, NULL, "2048K", &cpu_set_size}, | |
{ UNIT_MSIZE, 3145728, NULL, "3072K", &cpu_set_size}, | |
{ UNIT_MSIZE, 4194304, NULL, "4096K", &cpu_set_size}, | |
{ UNIT_MSIZE, 1048576, NULL, "1M", &cpu_set_size}, | |
{ UNIT_MSIZE, 2097152, NULL, "2M", &cpu_set_size}, | |
{ UNIT_MSIZE, 3145728, NULL, "3M", &cpu_set_size}, | |
{ UNIT_MSIZE, 4186112, NULL, "4M", &cpu_set_size}, | |
{ 0 } }; | |
DEVICE cpu_dev = { | |
"CPU", &cpu_unit, cpu_reg, cpu_mod, | |
1, 8, 22, 2, 8, 16, | |
&cpu_ex, &cpu_dep, &cpu_reset, | |
NULL, NULL, NULL }; | |
t_stat sim_instr (void) | |
{ | |
extern int32 sim_interval; | |
extern UNIT *sim_clock_queue; | |
extern UNIT clk_unit; | |
int32 IR, srcspec, srcreg, dstspec, dstreg; | |
int32 src, src2, dst; | |
int32 i, t, sign, oldrs, trapnum; | |
int32 abortval; | |
volatile int32 trapea; | |
t_stat reason; | |
void fp11 (int32 IR); | |
void cis11 (int32 IR); | |
/* Restore register state | |
1. PSW components | |
2. Active register file based on PSW<rs> | |
3. Active stack pointer based on PSW<cm> | |
4. Memory management control flags | |
5. Interrupt system | |
*/ | |
cm = (PSW >> PSW_V_CM) & 03; /* call calc_is,ds */ | |
pm = (PSW >> PSW_V_PM) & 03; | |
rs = (PSW >> PSW_V_RS) & 01; | |
ipl = (PSW >> PSW_V_IPL) & 07; /* call calc_ints */ | |
tbit = (PSW >> PSW_V_TBIT) & 01; | |
N = (PSW >> PSW_V_N) & 01; | |
Z = (PSW >> PSW_V_Z) & 01; | |
V = (PSW >> PSW_V_V) & 01; | |
C = (PSW >> PSW_V_C) & 01; | |
for (i = 0; i < 6; i++) R[i] = REGFILE[i][rs]; | |
SP = STACKFILE[cm]; | |
PC = saved_PC; | |
isenable = calc_is (cm); | |
dsenable = calc_ds (cm); | |
CPU_wr (PIRQ, 017777772, WRITE); /* rewrite PIRQ */ | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
trapea = 0; | |
reason = 0; | |
sim_rtc_init (clk_unit.wait); /* init clock */ | |
/* Abort handling | |
If an abort occurs in memory management or memory access, the lower | |
level routine executes a longjmp to this area OUTSIDE the main | |
simulation loop. The longjmp specifies a trap mask which is OR'd | |
into the trap_req register. Simulation then resumes at the fetch | |
phase, and the trap is sprung. | |
Aborts which occur within a trap sequence (trapea != 0) require | |
special handling. If the abort occured on the stack pushes, and | |
the mode (encoded in trapea) is kernel, an "emergency" kernel | |
stack is created at 4, and a red zone stack trap taken. | |
*/ | |
abortval = setjmp (save_env); /* set abort hdlr */ | |
if (abortval != 0) { | |
trap_req = trap_req | abortval; /* or in trap flag */ | |
if ((trapea > 0) && (stop_vecabort)) reason = STOP_VECABORT; | |
if ((trapea < 0) && (stop_spabort)) reason = STOP_SPABORT; | |
if (trapea == ~KERNEL) { /* kernel stk abort? */ | |
setTRAP (TRAP_RED); | |
setCPUERR (CPUE_RED); | |
STACKFILE[KERNEL] = 4; | |
if (cm == KERNEL) SP = 4; } } | |
/* Main instruction fetch/decode loop | |
Check for traps or interrupts. If trap, locate the vector and check | |
for stop condition. If interrupt, locate the vector. | |
*/ | |
while (reason == 0) { | |
if (sim_interval <= 0) { /* check clock queue */ | |
reason = sim_process_event (); | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
continue; } | |
if (trap_req) { /* check traps, ints */ | |
trapea = 0; /* assume srch fails */ | |
if (t = trap_req & TRAP_ALL) { /* if a trap */ | |
for (trapnum = 0; trapnum < TRAP_V_MAX; trapnum++) { | |
if ((t >> trapnum) & 1) { | |
trapea = trap_vec[trapnum]; | |
trap_req = trap_req & ~trap_clear[trapnum]; | |
if ((stop_trap >> trapnum) & 1) | |
reason = trapnum + 1; | |
break; } } } | |
else if (t = int_req & int_mask[ipl]) { /* if an interrupt */ | |
for (i = 0; i < 32; i++) { | |
if ((t >> i) & 1) { | |
int_req = int_req & ~(1u << i); | |
if (int_ack[i]) trapea = int_ack[i](); | |
else trapea = int_vec[i]; | |
trapnum = TRAP_V_MAX; | |
break; } } } | |
if (trapea == 0) { /* nothing to do? */ | |
trap_req = calc_ints (ipl, int_req, 0); /* recalculate */ | |
continue; } /* back to fetch */ | |
/* Process a trap or interrupt | |
1. Exit wait state | |
2. Save the current SP and PSW | |
3. Read the new PC, new PSW from trapea, kernel data space | |
4. Get the mode and stack selected by the new PSW | |
5. Push the old PC and PSW on the new stack | |
6. Update SP, PSW, and PC | |
7. If not stack overflow, check for stack overflow | |
*/ | |
wait_state = 0; /* exit wait state */ | |
STACKFILE[cm] = SP; | |
PSW = (cm << PSW_V_CM) | (pm << PSW_V_PM) | (rs << PSW_V_RS) | | |
(ipl << PSW_V_IPL) | (tbit << PSW_V_TBIT) | | |
(N << PSW_V_N) | (Z << PSW_V_Z) | | |
(V << PSW_V_V) | (C << PSW_V_C); | |
oldrs = rs; | |
src = ReadW (trapea | calc_ds (KERNEL)); | |
src2 = ReadW ((trapea + 2) | calc_ds (KERNEL)); | |
t = (src2 >> PSW_V_CM) & 03; | |
trapea = ~t; /* flag pushes */ | |
WriteW (PSW, ((STACKFILE[t] - 2) & 0177777) | calc_ds (t)); | |
WriteW (PC, ((STACKFILE[t] - 4) & 0177777) | calc_ds (t)); | |
trapea = 0; /* clear trap flag */ | |
pm = cm; | |
cm = t; /* call calc_is,ds */ | |
rs = (src2 >> PSW_V_RS) & 01; | |
ipl = (src2 >> PSW_V_IPL) & 07; /* call calc_ints */ | |
tbit = (src2 >> PSW_V_TBIT) & 01; | |
N = (src2 >> PSW_V_N) & 01; | |
Z = (src2 >> PSW_V_Z) & 01; | |
V = (src2 >> PSW_V_V) & 01; | |
C = (src2 >> PSW_V_C) & 01; | |
if (rs != oldrs) { /* if rs chg, swap */ | |
for (i = 0; i < 6; i++) { | |
REGFILE[i][oldrs] = R[i]; | |
R[i] = REGFILE[i][rs]; } } | |
SP = (STACKFILE[cm] - 4) & 0177777; /* update SP, PC */ | |
JMP_PC (src); | |
isenable = calc_is (cm); | |
dsenable = calc_ds (cm); | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
if ((SP < STKLIM) && (cm == KERNEL) && | |
(trapnum != TRAP_V_RED) && (trapnum != TRAP_V_YEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
continue; } /* end if traps */ | |
/* Fetch and decode next instruction */ | |
if (tbit) setTRAP (TRAP_TRC); | |
if (wait_state) { /* wait state? */ | |
if (sim_clock_queue != NULL) sim_interval = 0; /* force check */ | |
else reason = STOP_WAIT; | |
continue; } | |
if (PC == ibkpt_addr) { /* breakpoint? */ | |
save_ibkpt = ibkpt_addr; /* save bkpt */ | |
ibkpt_addr = ibkpt_addr | ILL_ADR_FLAG; /* disable */ | |
sim_activate (&cpu_unit, 1); /* sched re-enable */ | |
reason = STOP_IBKPT; /* stop simulation */ | |
continue; } | |
if (update_MM) { /* if mm not frozen */ | |
MMR1 = 0; | |
MMR2 = PC; } | |
IR = ReadW (PC | isenable); /* fetch instruction */ | |
PC = (PC + 2) & 0177777; /* incr PC, mod 65k */ | |
sim_interval = sim_interval - 1; | |
srcspec = (IR >> 6) & 077; /* src, dst specs */ | |
dstspec = IR & 077; | |
srcreg = (srcspec <= 07); /* src, dst = rmode? */ | |
dstreg = (dstspec <= 07); | |
switch ((IR >> 12) & 017) { /* decode IR<15:12> */ | |
/* Opcode 0: no operands, specials, branches, JSR, SOPs */ | |
case 000: | |
switch ((IR >> 6) & 077) { /* decode IR<11:6> */ | |
case 000: /* no operand */ | |
if (IR > 000010) { /* 000010 - 000077 */ | |
setTRAP (TRAP_ILL); /* illegal */ | |
break; } | |
switch (IR) { /* decode IR<2:0> */ | |
case 0: /* HALT */ | |
if (cm == KERNEL) reason = STOP_HALT; | |
else { setTRAP (TRAP_PRV); | |
setCPUERR (CPUE_HALT); } | |
break; | |
case 1: /* WAIT */ | |
if (cm == KERNEL && wait_enable) wait_state = 1; | |
break; | |
case 3: /* BPT */ | |
setTRAP (TRAP_BPT); | |
break; | |
case 4: /* IOT */ | |
setTRAP (TRAP_IOT); | |
break; | |
case 5: /* RESET */ | |
if (cm == KERNEL) { | |
reset_all (1); | |
PIRQ = 0; | |
int_req = 0; | |
MMR0 = MMR0 & ~(MMR0_MME | MMR0_FREEZE); | |
MMR3 = 0; | |
trap_req = trap_req & ~TRAP_INT; | |
dsenable = calc_ds (cm); } | |
break; | |
/* Opcode 0: specials, continued */ | |
case 2: /* RTI */ | |
case 6: /* RTT */ | |
src = ReadW (SP | dsenable); | |
src2 = ReadW (((SP + 2) & 0177777) | dsenable); | |
STACKFILE[cm] = SP = (SP + 4) & 0177777; | |
oldrs = rs; | |
if (cm == KERNEL) { | |
cm = (src2 >> PSW_V_CM) & 03; | |
pm = (src2 >> PSW_V_PM) & 03; | |
rs = (src2 >> PSW_V_RS) & 01; | |
ipl = (src2 >> PSW_V_IPL) & 07; } | |
else { cm = cm | ((src2 >> PSW_V_CM) & 03); | |
pm = pm | ((src2 >> PSW_V_PM) & 03); | |
rs = rs | ((src2 >> PSW_V_RS) & 01); } | |
tbit = (src2 >> PSW_V_TBIT) & 01; | |
N = (src2 >> PSW_V_N) & 01; | |
Z = (src2 >> PSW_V_Z) & 01; | |
V = (src2 >> PSW_V_V) & 01; | |
C = (src2 >> PSW_V_C) & 01; | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
isenable = calc_is (cm); | |
dsenable = calc_ds (cm); | |
if (rs != oldrs) { | |
for (i = 0; i < 6; i++) { | |
REGFILE[i][oldrs] = R[i]; | |
R[i] = REGFILE[i][rs]; } } | |
SP = STACKFILE[cm]; | |
JMP_PC (src); | |
if ((IR == 000002) && tbit) setTRAP (TRAP_TRC); | |
break; | |
case 7: /* MFPT */ | |
R[0] = 5; /* report J-11 */ | |
break; } /* end switch no ops */ | |
break; /* end case no ops */ | |
/* Opcode 0: specials, continued */ | |
case 001: /* JMP */ | |
if (dstreg) setTRAP (TRAP_ILL); | |
else { JMP_PC (GeteaW (dstspec) & 0177777); } | |
break; /* end JMP */ | |
case 002: /* RTS et al*/ | |
if (IR < 000210) { /* RTS */ | |
dstspec = dstspec & 07; | |
JMP_PC (R[dstspec]); | |
R[dstspec] = ReadW (SP | dsenable); | |
SP = (SP + 2) & 0177777; | |
break; } /* end if RTS */ | |
if (IR < 000230) { | |
setTRAP (TRAP_ILL); | |
break; } | |
if (IR < 000240) { /* SPL */ | |
if (cm == KERNEL) ipl = IR & 07; | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
break; } /* end if SPL */ | |
if (IR < 000260) { /* clear CC */ | |
if (IR & 010) N = 0; | |
if (IR & 004) Z = 0; | |
if (IR & 002) V = 0; | |
if (IR & 001) C = 0; | |
break; } /* end if clear CCs */ | |
if (IR & 010) N = 1; /* set CC */ | |
if (IR & 004) Z = 1; | |
if (IR & 002) V = 1; | |
if (IR & 001) C = 1; | |
break; /* end case RTS et al */ | |
case 003: /* SWAB */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = ((dst & 0377) << 8) | ((dst >> 8) & 0377); | |
N = GET_SIGN_B (dst & 0377); | |
Z = GET_Z (dst & 0377); | |
V = C = 0; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; /* end SWAB */ | |
/* Opcode 0: branches, JSR */ | |
case 004: case 005: /* BR */ | |
BRANCH_F (IR); | |
break; | |
case 006: case 007: /* BR */ | |
BRANCH_B (IR); | |
break; | |
case 010: case 011: /* BNE */ | |
if (Z == 0) { BRANCH_F (IR); } | |
break; | |
case 012: case 013: /* BNE */ | |
if (Z == 0) { BRANCH_B (IR); } | |
break; | |
case 014: case 015: /* BEQ */ | |
if (Z) { BRANCH_F (IR); } | |
break; | |
case 016: case 017: /* BEQ */ | |
if (Z) { BRANCH_B (IR); } | |
break; | |
case 020: case 021: /* BGE */ | |
if ((N ^ V) == 0) { BRANCH_F (IR); } | |
break; | |
case 022: case 023: /* BGE */ | |
if ((N ^ V) == 0) { BRANCH_B (IR); } | |
break; | |
case 024: case 025: /* BLT */ | |
if (N ^ V) { BRANCH_F (IR); } | |
break; | |
case 026: case 027: /* BLT */ | |
if (N ^ V) { BRANCH_B (IR); } | |
break; | |
case 030: case 031: /* BGT */ | |
if ((Z | (N ^ V)) == 0) { BRANCH_F (IR); } | |
break; | |
case 032: case 033: /* BGT */ | |
if ((Z | (N ^ V)) == 0) { BRANCH_B (IR); } | |
break; | |
case 034: case 035: /* BLE */ | |
if (Z | (N ^ V)) { BRANCH_F (IR); } | |
break; | |
case 036: case 037: /* BLE */ | |
if (Z | (N ^ V)) { BRANCH_B (IR); } | |
break; | |
case 040: case 041: case 042: case 043: /* JSR */ | |
case 044: case 045: case 046: case 047: | |
if (dstreg) setTRAP (TRAP_ILL); | |
else { srcspec = srcspec & 07; | |
dst = GeteaW (dstspec); | |
SP = (SP - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0366); | |
WriteW (R[srcspec], SP | dsenable); | |
if ((SP < STKLIM) && (cm == KERNEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
R[srcspec] = PC; | |
JMP_PC (dst & 0177777); } | |
break; /* end JSR */ | |
/* Opcode 0: SOPs */ | |
case 050: /* CLR */ | |
N = V = C = 0; | |
Z = 1; | |
if (dstreg) R[dstspec] = 0; | |
else WriteW (0, GeteaW (dstspec)); | |
break; | |
case 051: /* COM */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = dst ^ 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
C = 1; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 052: /* INC */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (dst + 1) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = (dst == 0100000); | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 053: /* DEC */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (dst - 1) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = (dst == 077777); | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 054: /* NEG */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (-dst) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = (dst == 0100000); | |
C = Z ^ 1; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 055: /* ADC */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (dst + C) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = (C && (dst == 0100000)); | |
C = C & Z; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
/* Opcode 0: SOPs, continued */ | |
case 056: /* SBC */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (dst - C) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = (C && (dst == 077777)); | |
C = (C && (dst == 0177777)); | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 057: /* TST */ | |
dst = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = C = 0; | |
break; | |
case 060: /* ROR */ | |
src = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (src >> 1) | (C << 15); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
C = (src & 1); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 061: /* ROL */ | |
src = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = ((src << 1) | C) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
C = GET_SIGN_W (src); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 062: /* ASR */ | |
src = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (src >> 1) | (src & 0100000); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
C = (src & 1); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 063: /* ASL */ | |
src = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (src << 1) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
C = GET_SIGN_W (src); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
/* Opcode 0: SOPS, continued | |
Notes: | |
- MxPI must mask GeteaW returned address to force ispace | |
- MxPI must set MMR1 for SP recovery in case of fault | |
*/ | |
case 064: /* MARK */ | |
i = (PC + dstspec + dstspec) & 0177777; | |
JMP_PC (R[5]); | |
R[5] = ReadW (i | dsenable); | |
SP = (i + 2) & 0177777; | |
break; | |
case 065: /* MFPI */ | |
if (dstreg) { | |
if ((dstspec == 6) && (cm != pm)) dst = STACKFILE[pm]; | |
else dst = R[dstspec]; } | |
else dst = ReadW ((GeteaW (dstspec) & 0177777) | calc_is (pm)); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
SP = (SP - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0366); | |
WriteW (dst, SP | dsenable); | |
if ((cm == KERNEL) && (SP < STKLIM)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
break; | |
case 066: /* MTPI */ | |
dst = ReadW (SP | dsenable); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
SP = (SP + 2) & 0177777; | |
if (update_MM) MMR1 = 026; | |
if (dstreg) { | |
if ((dstspec == 6) && (cm != pm)) STACKFILE[pm] = dst; | |
else R[dstspec] = dst; } | |
else { i = ((cm == pm) && (cm == USER))? | |
calc_ds (pm): calc_is (pm); | |
WriteW (dst, (GeteaW (dstspec) & 0177777) | i); } | |
break; | |
case 067: /* SXT */ | |
dst = N? 0177777: 0; | |
Z = N ^ 1; | |
V = 0; | |
if (dstreg) R[dstspec] = dst; | |
else WriteW (dst, GeteaW (dstspec)); | |
break; | |
/* Opcode 0: SOPs, continued */ | |
case 070: /* CSM */ | |
if (((MMR3 & MMR3_CSM) == 0) || (cm == KERNEL)) | |
setTRAP (TRAP_ILL); | |
else { dst = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
PSW = (cm << PSW_V_CM) | (pm << PSW_V_PM) | | |
(rs << PSW_V_RS) | (ipl << PSW_V_IPL) | | |
(tbit << PSW_V_TBIT); | |
STACKFILE[cm] = SP; | |
WriteW (PSW, ((SP - 2) & 0177777) | calc_ds (SUPER)); | |
WriteW (PC, ((SP - 4) & 0177777) | calc_ds (SUPER)); | |
WriteW (dst, ((SP - 6) & 0177777) | calc_ds (SUPER)); | |
SP = (SP - 6) & 0177777; | |
pm = cm; | |
cm = SUPER; | |
tbit = 0; | |
isenable = calc_is (cm); | |
dsenable = calc_ds (cm); | |
PC = ReadW (010 | isenable); } | |
break; | |
case 072: /* TSTSET */ | |
if (dstreg) setTRAP (TRAP_ILL); | |
else { dst = ReadMW (GeteaW (dstspec)); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
C = (dst & 1); | |
PWriteW (R[0] | 1, last_pa); | |
R[0] = dst; } | |
break; | |
case 073: /* WRTLCK */ | |
if (dstreg) setTRAP (TRAP_ILL); | |
else { N = GET_SIGN_W (R[0]); | |
Z = GET_Z (R[0]); | |
V = 0; | |
WriteW (R[0], GeteaW (dstspec)); } | |
break; | |
default: | |
setTRAP (TRAP_ILL); | |
break; } /* end switch SOPs */ | |
break; /* end case 000 */ | |
/* Opcodes 01 - 06: double operand word instructions | |
Add: v = [sign (src) = sign (src2)] and [sign (src) != sign (result)] | |
Cmp: v = [sign (src) != sign (src2)] and [sign (src2) = sign (result)] | |
*/ | |
case 001: /* MOV */ | |
dst = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = dst; | |
else WriteW (dst, GeteaW (dstspec)); | |
break; | |
case 002: /* CMP */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
dst = (src - src2) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = GET_SIGN_W ((src ^ src2) & (~src2 ^ dst)); | |
C = (src < src2); | |
break; | |
case 003: /* BIT */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
dst = src2 & src; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
break; | |
case 004: /* BIC */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = src2 & ~src; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 005: /* BIS */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = src2 | src; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 006: /* ADD */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (src2 + src) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = GET_SIGN_W ((~src ^ src2) & (src ^ dst)); | |
C = (dst < src); | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
/* Opcode 07: EIS, FIS (not implemented), CIS | |
Notes: | |
- The code assumes that the host int length is at least 32 bits. | |
- MUL carry: C is set if the (signed) result doesn't fit in 16 bits. | |
- Divide has three error cases: | |
1. Divide by zero. | |
2. Divide largest negative number by -1. | |
3. (Signed) quotient doesn't fit in 16 bits. | |
Cases 1 and 2 must be tested in advance, to avoid C runtime errors. | |
- ASHx left: overflow if the bits shifted out do not equal the sign | |
of the result (convert shift out to 1/0, xor against sign). | |
- ASHx right: if right shift sign extends, then the shift and | |
conditional or of shifted -1 is redundant. If right shift zero | |
extends, then the shift and conditional or does sign extension. | |
*/ | |
case 007: | |
srcspec = srcspec & 07; | |
switch ((IR >> 9) & 07) { /* decode IR<11:9> */ | |
case 0: /* MUL */ | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
src = R[srcspec]; | |
if (GET_SIGN_W (src2)) src2 = src2 | ~077777; | |
if (GET_SIGN_W (src)) src = src | ~077777; | |
dst = src * src2; | |
R[srcspec] = (dst >> 16) & 0177777; | |
R[srcspec | 1] = dst & 0177777; | |
N = (dst < 0); | |
Z = GET_Z (dst); | |
V = 0; | |
C = ((dst > 077777) || (dst < -0100000)); | |
break; | |
case 1: /* DIV */ | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
src = (R[srcspec] << 16) | R[srcspec | 1]; | |
if (src2 == 0) { | |
V = C = 1; | |
break; } | |
if ((src == 020000000000) && (src2 == 0177777)) { | |
V = 1; | |
C = 0; | |
break; } | |
if (GET_SIGN_W (src2)) src2 = src2 | ~077777; | |
if (GET_SIGN_W (R[srcspec])) src = src | ~017777777777; | |
dst = src / src2; | |
if ((dst > 077777) || (dst < -0100000)) { | |
V = 1; | |
C = 0; | |
break; } | |
R[srcspec] = dst & 0177777; | |
R[srcspec | 1] = (src - (src2 * dst)) & 0177777; | |
N = (dst < 0); | |
Z = GET_Z (dst); | |
V = C = 0; | |
break; | |
/* Opcode 7: EIS, continued */ | |
case 2: /* ASH */ | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
src2 = src2 & 077; | |
sign = GET_SIGN_W (R[srcspec]); | |
src = sign? R[srcspec] | ~077777: R[srcspec]; | |
if (src2 == 0) { /* [0] */ | |
dst = src; | |
V = C = 0; } | |
else if (src2 <= 15) { /* [1,15] */ | |
dst = src << src2; | |
i = (src >> (16 - src2)) & 0177777; | |
V = (i != ((dst & 0100000)? 0177777: 0)); | |
C = (i & 1); } | |
else if (src2 <= 31) { /* [16,31] */ | |
dst = 0; | |
V = (src != 0); | |
C = (src << (src2 - 16)) & 1; } | |
else { /* [-32,-1] */ | |
dst = (src >> (64 - src2)) | (-sign << (src2 - 32)); | |
V = 0; | |
C = ((src >> (63 - src2)) & 1); } | |
dst = R[srcspec] = dst & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
break; | |
case 3: /* ASHC */ | |
src2 = dstreg? R[dstspec]: ReadW (GeteaW (dstspec)); | |
src2 = src2 & 077; | |
sign = GET_SIGN_W (R[srcspec]); | |
src = (R[srcspec] << 16) | R[srcspec | 1]; | |
if (src2 == 0) { /* [0] */ | |
dst = src; | |
V = C = 0; } | |
else if (src2 <= 31) { /* [1,31] */ | |
dst = src << src2; | |
i = (src >> (32 - src2)) | (-sign << src2); | |
V = (i != ((dst & 020000000000)? -1: 0)); | |
C = (i & 1); } | |
else { /* [-32,-1] */ | |
dst = (src >> (64 - src2)) | (-sign << (src2 - 32)); | |
V = 0; | |
C = ((src >> (63 - src2)) & 1); } | |
i = R[srcspec] = (dst >> 16) & 0177777; | |
dst = R[srcspec | 1] = dst & 0177777; | |
N = GET_SIGN_W (i); | |
Z = GET_Z (dst | i); | |
break; | |
/* Opcode 7: EIS, continued */ | |
case 4: /* XOR */ | |
dst = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = dst ^ R[srcspec]; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
case 5: /* FIS - not impl */ | |
setTRAP (TRAP_ILL); | |
break; | |
case 6: /* CIS - not impl */ | |
if (cpu_unit.flags & UNIT_CIS) cis11 (IR); | |
else setTRAP (TRAP_ILL); | |
break; | |
case 7: /* SOB */ | |
R[srcspec] = (R[srcspec] - 1) & 0177777; | |
if (R[srcspec]) { | |
JMP_PC ((PC - dstspec - dstspec) & 0177777); } | |
break; } /* end switch EIS */ | |
break; /* end case 007 */ | |
/* Opcode 10: branches, traps, SOPs */ | |
case 010: | |
switch ((IR >> 6) & 077) { /* decode IR<11:6> */ | |
case 000: case 001: /* BPL */ | |
if (N == 0) { BRANCH_F (IR); } | |
break; | |
case 002: case 003: /* BPL */ | |
if (N == 0) { BRANCH_B (IR); } | |
break; | |
case 004: case 005: /* BMI */ | |
if (N) { BRANCH_F (IR); } | |
break; | |
case 006: case 007: /* BMI */ | |
if (N) { BRANCH_B (IR); } | |
break; | |
case 010: case 011: /* BHI */ | |
if ((C | Z) == 0) { BRANCH_F (IR); } | |
break; | |
case 012: case 013: /* BHI */ | |
if ((C | Z) == 0) { BRANCH_B (IR); } | |
break; | |
case 014: case 015: /* BLOS */ | |
if (C | Z) { BRANCH_F (IR); } | |
break; | |
case 016: case 017: /* BLOS */ | |
if (C | Z) { BRANCH_B (IR); } | |
break; | |
case 020: case 021: /* BVC */ | |
if (V == 0) { BRANCH_F (IR); } | |
break; | |
case 022: case 023: /* BVC */ | |
if (V == 0) { BRANCH_B (IR); } | |
break; | |
case 024: case 025: /* BVS */ | |
if (V) { BRANCH_F (IR); } | |
break; | |
case 026: case 027: /* BVS */ | |
if (V) { BRANCH_B (IR); } | |
break; | |
case 030: case 031: /* BCC */ | |
if (C == 0) { BRANCH_F (IR); } | |
break; | |
case 032: case 033: /* BCC */ | |
if (C == 0) { BRANCH_B (IR); } | |
break; | |
case 034: case 035: /* BCS */ | |
if (C) { BRANCH_F (IR); } | |
break; | |
case 036: case 037: /* BCS */ | |
if (C) { BRANCH_B (IR); } | |
break; | |
case 040: case 041: case 042: case 043: /* EMT */ | |
setTRAP (TRAP_EMT); | |
break; | |
case 044: case 045: case 046: case 047: /* TRAP */ | |
setTRAP (TRAP_TRAP); | |
break; | |
/* Opcode 10, continued: SOPs */ | |
case 050: /* CLRB */ | |
N = V = C = 0; | |
Z = 1; | |
if (dstreg) R[dstspec] = R[dstspec] & 0177400; | |
else WriteB (0, GeteaB (dstspec)); | |
break; | |
case 051: /* COMB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (dst ^ 0377) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
C = 1; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 052: /* INCB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (dst + 1) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = (dst == 0200); | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 053: /* DECB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (dst - 1) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = (dst == 0177); | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 054: /* NEGB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (-dst) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = (dst == 0200); | |
C = (Z ^ 1); | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 055: /* ADCB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (dst + C) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = (C && (dst == 0200)); | |
C = C & Z; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
/* Opcode 10: SOPs, continued */ | |
case 056: /* SBCB */ | |
dst = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (dst - C) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = (C && (dst == 0177)); | |
C = (C && (dst == 0377)); | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 057: /* TSTB */ | |
dst = dstreg? R[dstspec] & 0377: ReadB (GeteaB (dstspec)); | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = C = 0; | |
break; | |
case 060: /* RORB */ | |
src = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = ((src & 0377) >> 1) | (C << 7); | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
C = (src & 1); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 061: /* ROLB */ | |
src = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = ((src << 1) | C) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
C = GET_SIGN_B (src & 0377); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 062: /* ASRB */ | |
src = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = ((src & 0377) >> 1) | (src & 0200); | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
C = (src & 1); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 063: /* ASLB */ | |
src = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (src << 1) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
C = GET_SIGN_B (src & 0377); | |
V = N ^ C; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
/* Opcode 10: SOPs, continued | |
Notes: | |
- MTPS cannot alter the T bit | |
- MxPD must mask GeteaW returned address, dspace is from cm not pm | |
- MxPD must set MMR1 for SP recovery in case of fault | |
*/ | |
case 064: /* MTPS */ | |
dst = dstreg? R[dstspec]: ReadB (GeteaB (dstspec)); | |
if (cm == KERNEL) { | |
ipl = (dst >> PSW_V_IPL) & 07; | |
trap_req = calc_ints (ipl, int_req, trap_req); } | |
N = (dst >> PSW_V_N) & 01; | |
Z = (dst >> PSW_V_Z) & 01; | |
V = (dst >> PSW_V_V) & 01; | |
C = (dst >> PSW_V_C) & 01; | |
break; | |
case 065: /* MFPD */ | |
if (dstreg) { | |
if ((dstspec == 6) && (cm != pm)) dst = STACKFILE[pm]; | |
else dst = R[dstspec]; } | |
else dst = ReadW ((GeteaW (dstspec) & 0177777) | calc_ds (pm)); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
SP = (SP - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0366); | |
WriteW (dst, SP | dsenable); | |
if ((cm == KERNEL) && (SP < STKLIM)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
break; | |
case 066: /* MTPD */ | |
dst = ReadW (SP | dsenable); | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
SP = (SP + 2) & 0177777; | |
if (update_MM) MMR1 = 026; | |
if (dstreg) { | |
if ((dstspec == 6) && (cm != pm)) STACKFILE[pm] = dst; | |
else R[dstspec] = dst; } | |
else WriteW (dst, (GeteaW (dstspec) & 0177777) | calc_ds (pm)); | |
break; | |
case 067: /* MFPS */ | |
dst = (ipl << PSW_V_IPL) | (tbit << PSW_V_TBIT) | | |
(N << PSW_V_N) | (Z << PSW_V_Z) | | |
(V << PSW_V_V) | (C << PSW_V_C); | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = (dst & 0200)? 0177400 | dst: dst; | |
else WriteB (dst, GeteaB (dstspec)); | |
break; | |
default: | |
setTRAP (TRAP_ILL); | |
break; } /* end switch SOPs */ | |
break; /* end case 010 */ | |
/* Opcodes 11 - 16: double operand byte instructions | |
Cmp: v = [sign (src) != sign (src2)] and [sign (src2) = sign (result)] | |
Sub: v = [sign (src) != sign (src2)] and [sign (src) = sign (result)] | |
*/ | |
case 011: /* MOVB */ | |
dst = srcreg? R[srcspec] & 0377: ReadB (GeteaB (srcspec)); | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = (dst & 0200)? 0177400 | dst: dst; | |
else WriteB (dst, GeteaB (dstspec)); | |
break; | |
case 012: /* CMPB */ | |
src = srcreg? R[srcspec] & 0377: ReadB (GeteaB (srcspec)); | |
src2 = dstreg? R[dstspec] & 0377: ReadB (GeteaB (dstspec)); | |
dst = (src - src2) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = GET_SIGN_B ((src ^ src2) & (~src2 ^ dst)); | |
C = (src < src2); | |
break; | |
case 013: /* BITB */ | |
src = srcreg? R[srcspec]: ReadB (GeteaB (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadB (GeteaB (dstspec)); | |
dst = (src2 & src) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
break; | |
case 014: /* BICB */ | |
src = srcreg? R[srcspec]: ReadB (GeteaB (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (src2 & ~src) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 015: /* BISB */ | |
src = srcreg? R[srcspec]: ReadB (GeteaB (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMB (GeteaB (dstspec)); | |
dst = (src2 | src) & 0377; | |
N = GET_SIGN_B (dst); | |
Z = GET_Z (dst); | |
V = 0; | |
if (dstreg) R[dstspec] = (R[dstspec] & 0177400) | dst; | |
else PWriteB (dst, last_pa); | |
break; | |
case 016: /* SUB */ | |
src = srcreg? R[srcspec]: ReadW (GeteaW (srcspec)); | |
src2 = dstreg? R[dstspec]: ReadMW (GeteaW (dstspec)); | |
dst = (src2 - src) & 0177777; | |
N = GET_SIGN_W (dst); | |
Z = GET_Z (dst); | |
V = GET_SIGN_W ((src ^ src2) & (~src ^ dst)); | |
C = (src2 < src); | |
if (dstreg) R[dstspec] = dst; | |
else PWriteW (dst, last_pa); | |
break; | |
/* Opcode 17: floating point */ | |
case 017: | |
fp11 (IR); /* floating point */ | |
break; /* end case 017 */ | |
} /* end switch op */ | |
} /* end main loop */ | |
/* Simulation halted */ | |
PSW = (cm << PSW_V_CM) | (pm << PSW_V_PM) | (rs << PSW_V_RS) | | |
(ipl << PSW_V_IPL) | (tbit << PSW_V_TBIT) | | |
(N << PSW_V_N) | (Z << PSW_V_Z) | (V << PSW_V_V) | (C << PSW_V_C); | |
for (i = 0; i < 6; i++) REGFILE[i][rs] = R[i]; | |
STACKFILE[cm] = SP; | |
saved_PC = PC & 0177777; | |
return reason; | |
} | |
/* Effective address calculations | |
Inputs: | |
spec = specifier <5:0> | |
Outputs: | |
ea = effective address | |
<15:0> = virtual address | |
<16> = instruction/data data space | |
<18:17> = mode | |
Data space calculation: the PDP-11 features both instruction and data | |
spaces. Instruction space contains the instruction and any sequential | |
add ons (eg, immediates, absolute addresses). Data space contains all | |
data operands and indirect addresses. If data space is enabled, then | |
memory references are directed according to these rules: | |
Mode Index ref Indirect ref Direct ref | |
10..16 na na data | |
17 na na instruction | |
20..26 na na data | |
27 na na instruction | |
30..36 na data data | |
37 na instruction (absolute) data | |
40..46 na na data | |
47 na na instruction | |
50..56 na data data | |
57 na instruction data | |
60..67 instruction na data | |
70..77 instruction data data | |
According to the PDP-11 Architecture Handbook, MMR1 records all | |
autoincrement and autodecrement operations, including those which | |
explicitly reference the PC. For the J-11, this is only true for | |
autodecrement operands, autodecrement deferred operands, and | |
autoincrement destination operands that involve a write to memory. | |
The simulator follows the Handbook, for simplicity. | |
Notes: | |
- dsenable will direct a reference to data space if data space is enabled | |
- ds will direct a reference to data space if data space is enabled AND if | |
the specifier register is not PC; this is used for 17, 27, 37, 47, 57 | |
- Modes 2x, 3x, 4x, and 5x must update MMR1 if updating enabled | |
- Modes 46 and 56 must check for stack overflow if kernel mode | |
*/ | |
/* Effective address calculation for words */ | |
int32 GeteaW (int32 spec) | |
{ | |
int32 adr, reg, ds; | |
reg = spec & 07; /* register number */ | |
ds = (reg == 7)? isenable: dsenable; /* dspace if not PC */ | |
switch (spec >> 3) { /* decode spec<5:3> */ | |
default: /* can't get here */ | |
case 1: /* (R) */ | |
return (R[reg] | ds); | |
case 2: /* (R)+ */ | |
R[reg] = ((adr = R[reg]) + 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (020 | reg); | |
return (adr | ds); | |
case 3: /* @(R)+ */ | |
R[reg] = ((adr = R[reg]) + 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (020 | reg); | |
adr = ReadW (adr | ds); | |
return (adr | dsenable); | |
case 4: /* -(R) */ | |
adr = R[reg] = (R[reg] - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0360 | reg); | |
if ((adr < STKLIM) && (reg == 6) && (cm == KERNEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
return (adr | ds); | |
case 5: /* @-(R) */ | |
adr = R[reg] = (R[reg] - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0360 | reg); | |
if ((adr < STKLIM) && (reg == 6) && (cm == KERNEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
adr = ReadW (adr | ds); | |
return (adr | dsenable); | |
case 6: /* d(r) */ | |
adr = ReadW (PC | isenable); | |
PC = (PC + 2) & 0177777; | |
return (((R[reg] + adr) & 0177777) | dsenable); | |
case 7: /* @d(R) */ | |
adr = ReadW (PC | isenable); | |
PC = (PC + 2) & 0177777; | |
adr = ReadW (((R[reg] + adr) & 0177777) | dsenable); | |
return (adr | dsenable); | |
} /* end switch */ | |
} | |
/* Effective address calculation for bytes */ | |
int32 GeteaB (int32 spec) | |
{ | |
int32 adr, reg, ds, delta; | |
reg = spec & 07; /* reg number */ | |
ds = (reg == 7)? isenable: dsenable; /* dspace if not PC */ | |
switch (spec >> 3) { /* decode spec<5:3> */ | |
default: /* can't get here */ | |
case 1: /* (R) */ | |
return (R[reg] | ds); | |
case 2: /* (R)+ */ | |
delta = 1 + (reg >= 6); /* 2 if R6, PC */ | |
R[reg] = ((adr = R[reg]) + delta) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 ((delta << 3) | reg); | |
return (adr | ds); | |
case 3: /* @(R)+ */ | |
adr = R[reg]; | |
R[reg] = ((adr = R[reg]) + 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (020 | reg); | |
adr = ReadW (adr | ds); | |
return (adr | dsenable); | |
case 4: /* -(R) */ | |
delta = 1 + (reg >= 6); /* 2 if R6, PC */ | |
adr = R[reg] = (R[reg] - delta) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 ((((-delta) & 037) << 3) | reg); | |
if ((adr < STKLIM) && (reg == 6) && (cm == KERNEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
return (adr | ds); | |
case 5: /* @-(R) */ | |
adr = R[reg] = (R[reg] - 2) & 0177777; | |
if (update_MM) MMR1 = calc_MMR1 (0360 | reg); | |
if ((adr < STKLIM) && (reg == 6) && (cm == KERNEL)) { | |
setTRAP (TRAP_YEL); | |
setCPUERR (CPUE_YEL); } | |
adr = ReadW (adr | ds); | |
return (adr | dsenable); | |
case 6: /* d(r) */ | |
adr = ReadW (PC | isenable); | |
PC = (PC + 2) & 0177777; | |
return (((R[reg] + adr) & 0177777) | dsenable); | |
case 7: /* @d(R) */ | |
adr = ReadW (PC | isenable); | |
PC = (PC + 2) & 0177777; | |
adr = ReadW (((R[reg] + adr) & 0177777) | dsenable); | |
return (adr | dsenable); | |
} /* end switch */ | |
} | |
/* Read byte and word routines, read only and read-modify-write versions | |
Inputs: | |
va = virtual address, <18:16> = mode, I/D space | |
Outputs: | |
data = data read from memory or I/O space | |
*/ | |
int32 ReadW (int32 va) | |
{ | |
int32 pa, data; | |
if (va & 1) { /* odd address? */ | |
setCPUERR (CPUE_ODD); | |
ABORT (TRAP_ODD); } | |
pa = relocR (va); /* relocate */ | |
if (ADDR_IS_MEM (pa)) return (M[pa >> 1]); /* memory address? */ | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageR (&data, pa, READ) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return data; | |
} | |
int32 ReadB (int32 va) | |
{ | |
int32 pa, data; | |
pa = relocR (va); /* relocate */ | |
if (ADDR_IS_MEM (pa)) return (va & 1? M[pa >> 1] >> 8: M[pa >> 1]) & 0377; | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageR (&data, pa, READ) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return ((va & 1)? data >> 8: data) & 0377; | |
} | |
int32 ReadMW (int32 va) | |
{ | |
int32 data; | |
if (va & 1) { /* odd address? */ | |
setCPUERR (CPUE_ODD); | |
ABORT (TRAP_ODD); } | |
last_pa = relocW (va); /* reloc, wrt chk */ | |
if (ADDR_IS_MEM (last_pa)) return (M[last_pa >> 1]); /* memory address? */ | |
if (last_pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageR (&data, last_pa, READ) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return data; | |
} | |
int32 ReadMB (int32 va) | |
{ | |
int32 data; | |
last_pa = relocW (va); /* reloc, wrt chk */ | |
if (ADDR_IS_MEM (last_pa)) | |
return (va & 1? M[last_pa >> 1] >> 8: M[last_pa >> 1]) & 0377; | |
if (last_pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageR (&data, last_pa, READ) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return ((va & 1)? data >> 8: data) & 0377; | |
} | |
/* Write byte and word routines | |
Inputs: | |
data = data to be written | |
va = virtual address, <18:16> = mode, I/D space, or | |
pa = physical address | |
Outputs: none | |
*/ | |
void WriteW (int32 data, int32 va) | |
{ | |
int32 pa; | |
if (va & 1) { /* odd address? */ | |
setCPUERR (CPUE_ODD); | |
ABORT (TRAP_ODD); } | |
pa = relocW (va); /* relocate */ | |
if (ADDR_IS_MEM (pa)) { /* memory address? */ | |
M[pa >> 1] = data; | |
return; } | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageW (data, pa, WRITE) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return; | |
} | |
void WriteB (int32 data, int32 va) | |
{ | |
int32 pa; | |
pa = relocW (va); /* relocate */ | |
if (ADDR_IS_MEM (pa)) { /* memory address? */ | |
if (va & 1) M[pa >> 1] = (M[pa >> 1] & 0377) | (data << 8); | |
else M[pa >> 1] = (M[pa >> 1] & ~0377) | data; | |
return; } | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageW (data, pa, WRITEB) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return; | |
} | |
void PWriteW (int32 data, int32 pa) | |
{ | |
if (ADDR_IS_MEM (pa)) { /* memory address? */ | |
M[pa >> 1] = data; | |
return; } | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageW (data, pa, WRITE) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return; | |
} | |
void PWriteB (int32 data, int32 pa) | |
{ | |
if (ADDR_IS_MEM (pa)) { /* memory address? */ | |
if (pa & 1) M[pa >> 1] = (M[pa >> 1] & 0377) | (data << 8); | |
else M[pa >> 1] = (M[pa >> 1] & ~0377) | data; | |
return; } | |
if (pa < IOPAGEBASE) { /* I/O address? */ | |
setCPUERR (CPUE_NXM); | |
ABORT (TRAP_NXM); } | |
if (iopageW (data, pa, WRITEB) != SCPE_OK) { /* invalid I/O addr? */ | |
setCPUERR (CPUE_TMO); | |
ABORT (TRAP_NXM); } | |
return; | |
} | |
/* Relocate virtual address, read access | |
Inputs: | |
va = virtual address, <18:16> = mode, I/D space | |
Outputs: | |
pa = physical address | |
On aborts, this routine aborts back to the top level simulator | |
with an appropriate trap code. | |
Notes: | |
- APRFILE[UNUSED] is all zeroes, forcing non-resident abort | |
- Aborts must update MMR0<15:13,6:1> if updating is enabled | |
*/ | |
int32 relocR (int32 va) | |
{ | |
int32 dbn, plf, apridx, apr, pa; | |
if (MMR0 & MMR0_MME) { /* if mmgt */ | |
apridx = (va >> VA_V_APF) & 077; /* index into APR */ | |
apr = APRFILE[apridx]; /* with va<18:13> */ | |
dbn = va & VA_BN; /* extr block num */ | |
plf = (apr & PDR_PLF) >> 2; /* extr page length */ | |
if ((apr & PDR_NR) == 0) { /* if non-resident */ | |
if (update_MM) MMR0 = MMR0 | (apridx << MMR0_V_PAGE); | |
MMR0 = MMR0 | MMR0_NR; | |
ABORT (TRAP_MME); } /* abort ref */ | |
if ((apr & PDR_ED)? dbn < plf: dbn > plf) { /* if pg lnt error */ | |
if (update_MM) MMR0 = MMR0 | (apridx << MMR0_V_PAGE); | |
MMR0 = MMR0 | MMR0_PL; | |
ABORT (TRAP_MME); } /* abort ref */ | |
pa = (va & VA_DF) + ((apr >> 10) & 017777700); | |
if ((MMR3 & MMR3_M22E) == 0) { | |
pa = pa & 0777777; | |
if (pa >= 0760000) pa = 017000000 | pa; } } | |
else { pa = va & 0177777; /* mmgt off */ | |
if (pa >= 0160000) pa = 017600000 | pa; } | |
return pa; | |
} | |
/* Relocate virtual address, write access | |
Inputs: | |
va = virtual address, <18:16> = mode, I/D space | |
Outputs: | |
pa = physical address | |
On aborts, this routine aborts back to the top level simulator | |
with an appropriate trap code. | |
Notes: | |
- APRFILE[UNUSED] is all zeroes, forcing non-resident abort | |
- Aborts must update MMR0<15:13,6:1> if updating is enabled | |
*/ | |
int32 relocW (int32 va) | |
{ | |
int32 dbn, plf, apridx, apr, pa; | |
if (MMR0 & MMR0_MME) { /* if mmgt */ | |
apridx = (va >> VA_V_APF) & 077; /* index into APR */ | |
apr = APRFILE[apridx]; /* with va<18:13> */ | |
dbn = va & VA_BN; /* extr block num */ | |
plf = (apr & PDR_PLF) >> 2; /* extr page length */ | |
if ((apr & PDR_NR) == 0) { /* if non-resident */ | |
if (update_MM) MMR0 = MMR0 | (apridx << MMR0_V_PAGE); | |
MMR0 = MMR0 | MMR0_NR; | |
ABORT (TRAP_MME); } /* abort ref */ | |
if ((apr & PDR_ED)? dbn < plf: dbn > plf) { /* if pg lnt error */ | |
if (update_MM) MMR0 = MMR0 | (apridx << MMR0_V_PAGE); | |
MMR0 = MMR0 | MMR0_PL; | |
ABORT (TRAP_MME); } /* abort ref */ | |
if ((apr & PDR_RW) == 0) { /* if rd only error */ | |
if (update_MM) MMR0 = MMR0 | (apridx << MMR0_V_PAGE); | |
MMR0 = MMR0 | MMR0_RO; | |
ABORT (TRAP_MME); } /* abort ref */ | |
APRFILE[apridx] = apr | PDR_W; /* set W */ | |
pa = (va & VA_DF) + ((apr >> 10) & 017777700); | |
if ((MMR3 & MMR3_M22E) == 0) { | |
pa = pa & 0777777; | |
if (pa >= 0760000) pa = 017000000 | pa; } } | |
else { pa = va & 0177777; /* mmgt off */ | |
if (pa >= 0160000) pa = 017600000 | pa; } | |
return pa; | |
} | |
/* Relocate virtual address, console access | |
Inputs: | |
va = virtual address | |
sw = switches | |
Outputs: | |
pa = physical address | |
On aborts, this routine returns -1 | |
*/ | |
int32 relocC (int32 va, int32 sw) | |
{ | |
int32 mode, dbn, plf, apridx, apr, pa; | |
if (MMR0 & MMR0_MME) { /* if mmgt */ | |
if (sw & SWMASK ('K')) mode = KERNEL; | |
else if (sw & SWMASK ('S')) mode = SUPER; | |
else if (sw & SWMASK ('U')) mode = USER; | |
else if (sw & SWMASK ('P')) mode = (PSW >> PSW_V_PM) & 03; | |
else mode = (PSW >> PSW_V_CM) & 03; | |
va = va | ((sw & SWMASK ('D'))? calc_ds (mode): calc_is (mode)); | |
apridx = (va >> VA_V_APF) & 077; /* index into APR */ | |
apr = APRFILE[apridx]; /* with va<18:13> */ | |
dbn = va & VA_BN; /* extr block num */ | |
plf = (apr & PDR_PLF) >> 2; /* extr page length */ | |
if ((apr & PDR_NR) == 0) return -1; | |
if ((apr & PDR_ED)? dbn < plf: dbn > plf) return -1; | |
pa = (va & VA_DF) + ((apr >> 10) & 017777700); | |
if ((MMR3 & MMR3_M22E) == 0) { | |
pa = pa & 0777777; | |
if (pa >= 0760000) pa = 017000000 | pa; } } | |
else { pa = va & 0177777; /* mmgt off */ | |
if (pa >= 0160000) pa = 017600000 | pa; } | |
return pa; | |
} | |
/* I/O page lookup and linkage routines | |
Inputs: | |
*data = pointer to data to read, if READ | |
data = data to store, if WRITE or WRITEB | |
pa = address | |
access = READ, WRITE, or WRITEB | |
Outputs: | |
status = SCPE_OK or SCPE_NXM | |
*/ | |
t_stat iopageR (int32 *data, int32 pa, int32 access) | |
{ | |
t_stat stat; | |
struct iolink *p; | |
for (p = &iotable[0]; p -> low != 0; p++ ) { | |
if ((pa >= p -> low) && (pa <= p -> high) && | |
((p -> enb == 0) || (dev_enb & p -> enb))) { | |
stat = p -> read (data, pa, access); | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
return stat; } } | |
return SCPE_NXM; | |
} | |
t_stat iopageW (int32 data, int32 pa, int32 access) | |
{ | |
t_stat stat; | |
struct iolink *p; | |
for (p = &iotable[0]; p -> low != 0; p++ ) { | |
if ((pa >= p -> low) && (pa <= p -> high) && | |
((p -> enb == 0) || (dev_enb & p -> enb))) { | |
stat = p -> write (data, pa, access); | |
trap_req = calc_ints (ipl, int_req, trap_req); | |
return stat; } } | |
return SCPE_NXM; | |
} | |
/* I/O page routines for CPU registers | |
Switch register and memory management registers | |
SR 17777570 read only | |
MMR0 17777572 read/write, certain bits unimplemented or read only | |
MMR1 17777574 read only | |
MMR2 17777576 read only | |
MMR3 17777516 read/write, certain bits unimplemented | |
*/ | |
t_stat SR_MMR012_rd (int32 *data, int32 pa, int32 access) | |
{ | |
switch ((pa >> 1) & 3) { /* decode pa<2:1> */ | |
case 0: /* SR */ | |
*data = SR; | |
break; | |
case 1: /* MMR0 */ | |
*data = MMR0 & MMR0_IMP; | |
break; | |
case 2: /* MMR1 */ | |
*data = MMR1; | |
break; | |
case 3: /* MMR2 */ | |
*data = MMR2; | |
break; } /* end switch pa */ | |
return SCPE_OK; | |
} | |
t_stat SR_MMR012_wr (int32 data, int32 pa, int32 access) | |
{ | |
switch ((pa >> 1) & 3) { /* decode pa<2:1> */ | |
case 0: /* DR */ | |
DR = data; | |
return SCPE_OK; | |
case 1: /* MMR0 */ | |
if (access == WRITEB) data = (pa & 1)? | |
(MMR0 & 0377) | (data << 8): (MMR0 & ~0377) | data; | |
MMR0 = (MMR0 & ~MMR0_RW) | (data & MMR0_RW); | |
return SCPE_OK; | |
default: /* MMR1, MMR2 */ | |
return SCPE_OK; } /* end switch pa */ | |
} | |
t_stat MMR3_rd (int32 *data, int32 pa, int32 access) /* MMR3 */ | |
{ | |
*data = MMR3 & MMR3_IMP; | |
return SCPE_OK; | |
} | |
t_stat MMR3_wr (int32 data, int32 pa, int32 access) /* MMR3 */ | |
{ | |
if (pa & 1) return SCPE_OK; | |
MMR3 = data & MMR3_RW; | |
if (cpu_unit.flags & UNIT_18B) | |
MMR3 = MMR3 & ~(MMR3_BME + MMR3_M22E); /* for UNIX V6 */ | |
dsenable = calc_ds (cm); | |
return SCPE_OK; | |
} | |
/* PARs and PDRs. These are grouped in I/O space as follows: | |
17772200 - 17772276 supervisor block | |
17772300 - 17772376 kernel block | |
17777600 - 17777676 user block | |
Within each block, the subblocks are I PDR's, D PDR's, I PAR's, D PAR's | |
Thus, the algorithm for converting between I/O space addresses and | |
APRFILE indices is as follows: | |
idx<3:0> = dspace'page = pa<4:1> | |
par = PDR vs PAR = pa<5> | |
idx<5:4> = ker/sup/user = pa<8>'~pa<6> | |
Note that the W bit is read only; it is cleared by any write to an APR | |
*/ | |
t_stat APR_rd (int32 *data, int32 pa, int32 access) | |
{ | |
t_stat left, idx; | |
idx = (pa >> 1) & 017; /* dspace'page */ | |
left = (pa >> 5) & 1; /* PDR vs PAR */ | |
if ((pa & 0100) == 0) idx = idx | 020; /* 1 for super, user */ | |
if (pa & 0400) idx = idx | 040; /* 1 for user only */ | |
*data = left? (APRFILE[idx] >> 16) & 0177777: APRFILE[idx] & PDR_IMP; | |
return SCPE_OK; | |
} | |
t_stat APR_wr (int32 data, int32 pa, int32 access) | |
{ | |
int32 left, idx, curr; | |
idx = (pa >> 1) & 017; /* dspace'page */ | |
left = (pa >> 5) & 1; /* PDR vs PAR */ | |
if ((pa & 0100) == 0) idx = idx | 020; /* 1 for super, user */ | |
if (pa & 0400) idx = idx | 040; /* 1 for user only */ | |
curr = left? (APRFILE[idx] >> 16) & 0177777: APRFILE[idx] & PDR_IMP; | |
if (access == WRITEB) data = (pa & 1)? | |
(curr & 0377) | (data << 8): (curr & ~0377) | data; | |
if (left) APRFILE[idx] = | |
((APRFILE[idx] & 0177777) | (data << 16)) & ~PDR_W; | |
else APRFILE[idx] = | |
((APRFILE[idx] & ~PDR_RW) | (data & PDR_RW)) & ~PDR_W; | |
return SCPE_OK; | |
} | |
/* CPU control registers | |
MEMERR 17777744 read only, clear on write | |
CCR 17777746 read/write | |
MAINT 17777750 read only | |
HITMISS 17777752 read only | |
CPUERR 17777766 read only, clear on write | |
PIRQ 17777772 read/write, with side effects | |
PSW 17777776 read/write, with side effects | |
*/ | |
t_stat CPU_rd (int32 *data, int32 pa, int32 access) | |
{ | |
switch ((pa >> 1) & 017) { /* decode pa<4:1> */ | |
case 2: /* MEMERR */ | |
*data = MEMERR; | |
MEMERR = 0; | |
return SCPE_OK; | |
case 3: /* CCR */ | |
*data = CCR; | |
return SCPE_OK; | |
case 4: /* MAint */ | |
*data = MAINT; | |
return SCPE_OK; | |
case 5: /* Hit/miss */ | |
*data = HITMISS; | |
return SCPE_OK; | |
case 013: /* CPUERR */ | |
*data = CPUERR & CPUE_IMP; | |
CPUERR = 0; | |
return SCPE_OK; | |
case 015: /* PIRQ */ | |
*data = PIRQ; | |
return SCPE_OK; | |
case 017: /* PSW */ | |
if (access == READC) *data = PSW; | |
else *data = (cm << PSW_V_CM) | (pm << PSW_V_PM) | (rs << PSW_V_RS) | | |
(ipl << PSW_V_IPL) | (tbit << PSW_V_TBIT) | | |
(N << PSW_V_N) | (Z << PSW_V_Z) | | |
(V << PSW_V_V) | (C << PSW_V_C); | |
return SCPE_OK; } /* end switch PA */ | |
return SCPE_NXM; /* unimplemented */ | |
} | |
/* CPU control registers, continued */ | |
t_stat CPU_wr (int32 data, int32 pa, int32 access) | |
{ | |
int32 i, pl, curr, oldrs; | |
switch ((pa >> 1) & 017) { /* decode pa<4:1> */ | |
case 2: /* MEMERR */ | |
MEMERR = 0; | |
return SCPE_OK; | |
case 3: /* CCR */ | |
if (access == WRITEB) data = (pa & 1)? | |
(CCR & 0377) | (data << 8): (CCR & ~0377) | data; | |
CCR = data; | |
return SCPE_OK; | |
case 4: /* MAINT */ | |
return SCPE_OK; | |
case 5: /* Hit/miss */ | |
return SCPE_OK; | |
case 013: /* CPUERR */ | |
CPUERR = 0; | |
return SCPE_OK; | |
case 015: /* PIRQ */ | |
if (access == WRITEB) { | |
if (pa & 1) data = data << 8; | |
else return SCPE_OK; } | |
int_req = int_req & ~(INT_PIR7 + INT_PIR6 + INT_PIR5 + INT_PIR4 + | |
INT_PIR3 + INT_PIR2 + INT_PIR1); | |
PIRQ = data & PIRQ_RW; | |
pl = 0; | |
if (PIRQ & PIRQ_PIR1) { int_req = int_req | INT_PIR1; pl = 0042; } | |
if (PIRQ & PIRQ_PIR2) { int_req = int_req | INT_PIR2; pl = 0104; } | |
if (PIRQ & PIRQ_PIR3) { int_req = int_req | INT_PIR3; pl = 0146; } | |
if (PIRQ & PIRQ_PIR4) { int_req = int_req | INT_PIR4; pl = 0210; } | |
if (PIRQ & PIRQ_PIR5) { int_req = int_req | INT_PIR5; pl = 0252; } | |
if (PIRQ & PIRQ_PIR6) { int_req = int_req | INT_PIR6; pl = 0314; } | |
if (PIRQ & PIRQ_PIR7) { int_req = int_req | INT_PIR7; pl = 0356; } | |
PIRQ = PIRQ | pl; | |
return SCPE_OK; | |
/* CPU control registers, continued | |
Note: Explicit writes to the PSW do not modify the T bit | |
*/ | |
case 017: /* PSW */ | |
if (access == WRITEC) { /* console access? */ | |
PSW = data & PSW_RW; | |
return SCPE_OK; } | |
curr = (cm << PSW_V_CM) | (pm << PSW_V_PM) | (rs << PSW_V_RS) | | |
(ipl << PSW_V_IPL) | (tbit << PSW_V_TBIT) | | |
(N << PSW_V_N) | (Z << PSW_V_Z) | | |
(V << PSW_V_V) | (C << PSW_V_C); | |
STACKFILE[cm] = SP; | |
if (access == WRITEB) data = (pa & 1)? | |
(curr & 0377) | (data << 8): (curr & ~0377) | data; | |
curr = (curr & ~PSW_RW) | (data & PSW_RW); | |
oldrs = rs; | |
cm = (curr >> PSW_V_CM) & 03; /* call calc_is,ds */ | |
pm = (curr >> PSW_V_PM) & 03; | |
rs = (curr >> PSW_V_RS) & 01; | |
ipl = (curr >> PSW_V_IPL) & 07; | |
N = (curr >> PSW_V_N) & 01; | |
Z = (curr >> PSW_V_Z) & 01; | |
V = (curr >> PSW_V_V) & 01; | |
C = (curr >> PSW_V_C) & 01; | |
if (rs != oldrs) { | |
for (i = 0; i < 6; i++) { | |
REGFILE[i][oldrs] = R[i]; | |
R[i] = REGFILE[i][rs]; } } | |
SP = STACKFILE[cm]; | |
isenable = calc_is (cm); | |
dsenable = calc_ds (cm); | |
return SCPE_OK; } /* end switch pa */ | |
return SCPE_NXM; /* unimplemented */ | |
} | |
/* Reset routine */ | |
t_stat cpu_reset (DEVICE *dptr) | |
{ | |
PIRQ = MMR0 = MMR1 = MMR2 = MMR3 = 0; | |
DR = CPUERR = MEMERR = CCR = HITMISS = 0; | |
PSW = 000340; | |
trap_req = 0; | |
wait_state = 0; | |
if (M == NULL) M = calloc (MEMSIZE >> 1, sizeof (unsigned int16)); | |
if (M == NULL) return SCPE_MEM; | |
return cpu_svc (&cpu_unit); | |
} | |
/* Memory examine */ | |
t_stat cpu_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
int32 iodata; | |
t_stat stat; | |
if (vptr == NULL) return SCPE_ARG; | |
if (sw & SWMASK ('V')) { /* -v */ | |
if (addr >= VASIZE) return SCPE_NXM; | |
addr = relocC (addr, sw); /* relocate */ | |
if (addr < 0) return SCPE_REL; } | |
if (addr < MEMSIZE) { | |
*vptr = M[addr >> 1] & 0177777; | |
return SCPE_OK; } | |
if (addr < IOPAGEBASE) return SCPE_NXM; | |
stat = iopageR (&iodata, addr, READC); | |
*vptr = iodata; | |
return stat; | |
} | |
/* Memory deposit */ | |
t_stat cpu_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if (sw & SWMASK ('V')) { /* -v */ | |
if (addr >= VASIZE) return SCPE_NXM; | |
addr = relocC (addr, sw); /* relocate */ | |
if (addr < 0) return SCPE_REL; } | |
if (addr < MEMSIZE) { | |
M[addr >> 1] = val & 0177777; | |
return SCPE_OK; } | |
if (addr < IOPAGEBASE) return SCPE_NXM; | |
return iopageW ((int32) val, addr, WRITEC); | |
} | |
/* Breakpoint service */ | |
t_stat cpu_svc (UNIT *uptr) | |
{ | |
if ((ibkpt_addr & ~ILL_ADR_FLAG) == save_ibkpt) ibkpt_addr = save_ibkpt; | |
save_ibkpt = -1; | |
return SCPE_OK; | |
} | |
/* Memory allocation */ | |
t_stat cpu_set_size (UNIT *uptr, int32 value) | |
{ | |
int32 mc = 0; | |
t_addr i, clim; | |
unsigned int16 *nM = NULL; | |
if ((value <= 0) || (value > MAXMEMSIZE) || ((value & 07777) != 0)) | |
return SCPE_ARG; | |
for (i = value; i < MEMSIZE; i = i + 2) mc = mc | M[i >> 1]; | |
if ((mc != 0) && !get_yn ("Really truncate memory [N]?", FALSE)) | |
return SCPE_OK; | |
nM = calloc (value >> 1, sizeof (unsigned int16)); | |
if (nM == NULL) return SCPE_MEM; | |
clim = (((t_addr) value) < MEMSIZE)? value: MEMSIZE; | |
for (i = 0; i < clim; i = i + 2) nM[i >> 1] = M[i >> 1]; | |
free (M); | |
M = nM; | |
MEMSIZE = value; | |
return SCPE_OK; } |