| 1 | /* h316_cpu.c: Honeywell 316/516 CPU simulator\r |
| 2 | \r |
| 3 | Copyright (c) 1999-2007, Robert M. Supnik\r |
| 4 | \r |
| 5 | Permission is hereby granted, free of charge, to any person obtaining a\r |
| 6 | copy of this software and associated documentation files (the "Software"),\r |
| 7 | to deal in the Software without restriction, including without limitation\r |
| 8 | the rights to use, copy, modify, merge, publish, distribute, sublicense,\r |
| 9 | and/or sell copies of the Software, and to permit persons to whom the\r |
| 10 | Software is furnished to do so, subject to the following conditions:\r |
| 11 | \r |
| 12 | The above copyright notice and this permission notice shall be included in\r |
| 13 | all copies or substantial portions of the Software.\r |
| 14 | \r |
| 15 | THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR\r |
| 16 | IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,\r |
| 17 | FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL\r |
| 18 | ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER\r |
| 19 | IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN\r |
| 20 | CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.\r |
| 21 | \r |
| 22 | Except as contained in this notice, the name of Robert M Supnik shall not be\r |
| 23 | used in advertising or otherwise to promote the sale, use or other dealings\r |
| 24 | in this Software without prior written authorization from Robert M Supnik.\r |
| 25 | \r |
| 26 | cpu H316/H516 CPU\r |
| 27 | \r |
| 28 | 28-Apr-07 RMS Removed clock initialization\r |
| 29 | 03-Apr-06 RMS Fixed bugs in LLL, LRL (from Theo Engel)\r |
| 30 | 22-Sep-05 RMS Fixed declarations (from Sterling Garwood)\r |
| 31 | 16-Aug-05 RMS Fixed C++ declaration and cast problems\r |
| 32 | 15-Feb-05 RMS Added start button interrupt\r |
| 33 | 01-Dec-04 RMS Fixed bug in DIV\r |
| 34 | 06-Nov-04 RMS Added =n to SHOW HISTORY\r |
| 35 | 04-Jan-04 RMS Removed unnecessary compare\r |
| 36 | 31-Dec-03 RMS Fixed bug in cpu_set_hist\r |
| 37 | 24-Oct-03 RMS Added DMA/DMC support, instruction history\r |
| 38 | 30-Dec-01 RMS Added old PC queue\r |
| 39 | 03-Nov-01 RMS Fixed NOHSA modifier\r |
| 40 | 30-Nov-01 RMS Added extended SET/SHOW support\r |
| 41 | \r |
| 42 | The register state for the Honeywell 316/516 CPU is:\r |
| 43 | \r |
| 44 | AR<1:16> A register\r |
| 45 | BR<1:16> B register\r |
| 46 | XR<1:16> X register\r |
| 47 | PC<1:16> P register (program counter)\r |
| 48 | Y<1:16> memory address register\r |
| 49 | MB<1:16> memory data register\r |
| 50 | C overflow flag\r |
| 51 | EXT extend mode flag\r |
| 52 | DP double precision mode flag\r |
| 53 | SC<1:5> shift count\r |
| 54 | SR[1:4]<0> sense switches 1-4\r |
| 55 | \r |
| 56 | The Honeywell 316/516 has six instruction formats: memory reference,\r |
| 57 | I/O, control, shift, skip, and operate.\r |
| 58 | \r |
| 59 | The memory reference format is:\r |
| 60 | \r |
| 61 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 62 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 63 | |in|xr| op |sc| offset | memory reference\r |
| 64 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 65 | \r |
| 66 | <13:10> mnemonic action\r |
| 67 | \r |
| 68 | 0000 (other) see control, shift, skip, operate instructions\r |
| 69 | 0001 JMP P = MA\r |
| 70 | 0010 LDA A = M[MA]\r |
| 71 | 0011 ANA A = A & M[MA]\r |
| 72 | 0100 STA M[MA] = A\r |
| 73 | 0101 ERA A = A ^ M[MA]\r |
| 74 | 0110 ADD A = A + M[MA]\r |
| 75 | 0111 SUB A = A - M[MA]\r |
| 76 | 1000 JST M[MA] = P, P = MA + 1\r |
| 77 | 1001 CAS skip if A == M[MA], double skip if A < M[MA]\r |
| 78 | 1010 IRS M[MA] = M[MA] + 1, skip if M[MA] == 0\r |
| 79 | 1011 IMA A <=> M[MA]\r |
| 80 | 1100 (I/O) see I/O instructions\r |
| 81 | 1101 LDX/STX X = M[MA] (xr = 1), M[MA] = x (xr = 0)\r |
| 82 | 1110 MPY multiply\r |
| 83 | 1111 DIV divide\r |
| 84 | \r |
| 85 | In non-extend mode, memory reference instructions can access an address\r |
| 86 | space of 16K words. Multiple levels of indirection are supported, and\r |
| 87 | each indirect word supplies its own indirect and index bits.\r |
| 88 | \r |
| 89 | <1,2,7> mode action\r |
| 90 | \r |
| 91 | 0,0,0 sector zero direct MA = IR<8:0>\r |
| 92 | 0,0,1 current direct MA = P<13:9>'IR<8:0>\r |
| 93 | 0,1,0 sector zero indexed MA = IR<8:0> + X\r |
| 94 | 0,1,1 current direct MA = P<13:9>'IR<8:0> + X\r |
| 95 | 1,0,0 sector zero indirect MA = M[IR<8:0>]\r |
| 96 | 1,0,1 current indirect MA = M[P<13:9>'IR<8:0>]\r |
| 97 | 1,1,0 sector zero indirect indexed MA = M[IR<8:0> + X]\r |
| 98 | 1,1,1 current indirect indexed MA = M[MA = P<13:9>'IR<8:0> + X]\r |
| 99 | \r |
| 100 | In extend mode, memory reference instructions can access an address\r |
| 101 | space of 32K words. Multiple levels of indirection are supported, but\r |
| 102 | only post-indexing, based on the original instruction word index flag,\r |
| 103 | is allowed.\r |
| 104 | \r |
| 105 | The control format is:\r |
| 106 | \r |
| 107 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 108 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 109 | | 0 0 0 0 0 0| opcode | control\r |
| 110 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 111 | \r |
| 112 | The shift format is:\r |
| 113 | \r |
| 114 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 115 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 116 | | 0 1 0 0 0 0|dr|sz|type | shift count | shift\r |
| 117 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 118 | | | \-+-/\r |
| 119 | | | |\r |
| 120 | | | +--------------------- type\r |
| 121 | | +------------------------- long/A only\r |
| 122 | +---------------------------- right/left\r |
| 123 | \r |
| 124 | The skip format is:\r |
| 125 | \r |
| 126 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 127 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 128 | | 1 0 0 0 0 0|rv|po|pe|ev|ze|s1|s2|s3|s4|cz| skip\r |
| 129 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 130 | | | | | | | | | | |\r |
| 131 | | | | | | | | | | +- skip if C = 0\r |
| 132 | | | | | | | | | +---- skip if ssw 4 = 0\r |
| 133 | | | | | | | | +------- skip if ssw 3 = 0\r |
| 134 | | | | | | | +---------- skip if ssw 2 = 0\r |
| 135 | | | | | | +------------- skip if ssw 1 = 0\r |
| 136 | | | | | +---------------- skip if A == 0\r |
| 137 | | | | +------------------- skip if A<0> == 0\r |
| 138 | | | +---------------------- skip if mem par err\r |
| 139 | | +------------------------- skip if A<15> = 0\r |
| 140 | +---------------------------- reverse skip sense\r |
| 141 | \r |
| 142 | The operate format is:\r |
| 143 | \r |
| 144 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 145 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 146 | | 1 1 0 0 0 0| opcode | operate\r |
| 147 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 148 | \r |
| 149 | The I/O format is:\r |
| 150 | \r |
| 151 | 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16\r |
| 152 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 153 | | op | 1 1 0 0| function | device | I/O transfer\r |
| 154 | +--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+--+\r |
| 155 | \r |
| 156 | The IO transfer instruction controls the specified device.\r |
| 157 | Depending on the opcode, the instruction may set or clear\r |
| 158 | the device flag, start or stop I/O, or read or write data.\r |
| 159 | \r |
| 160 | This routine is the instruction decode routine for the Honeywell\r |
| 161 | 316/516. It is called from the simulator control program to execute\r |
| 162 | instructions in simulated memory, starting at the simulated PC.\r |
| 163 | It runs until 'reason' is set non-zero.\r |
| 164 | \r |
| 165 | General notes:\r |
| 166 | \r |
| 167 | 1. Reasons to stop. The simulator can be stopped by:\r |
| 168 | \r |
| 169 | HALT instruction\r |
| 170 | breakpoint encountered\r |
| 171 | infinite indirection loop\r |
| 172 | unimplemented instruction and stop_inst flag set\r |
| 173 | unknown I/O device and stop_dev flag set\r |
| 174 | I/O error in I/O simulator\r |
| 175 | \r |
| 176 | 2. Interrupts. Interrupts are maintained by two parallel variables:\r |
| 177 | \r |
| 178 | dev_int device interrupt flags\r |
| 179 | dev_enb device interrupt enable flags\r |
| 180 | \r |
| 181 | In addition, dev_int contains the interrupt enable and interrupt no\r |
| 182 | defer flags. If interrupt enable and interrupt no defer are set, and\r |
| 183 | at least one interrupt request is pending, then an interrupt occurs.\r |
| 184 | The order of flags in these variables corresponds to the order\r |
| 185 | in the SMK instruction.\r |
| 186 | \r |
| 187 | 3. Non-existent memory. On the H316/516, reads to non-existent memory\r |
| 188 | return zero, and writes are ignored. In the simulator, the\r |
| 189 | largest possible memory is instantiated and initialized to zero.\r |
| 190 | Thus, only writes need be checked against actual memory size.\r |
| 191 | \r |
| 192 | 4. Adding I/O devices. These modules must be modified:\r |
| 193 | \r |
| 194 | h316_defs.h add interrupt request definition\r |
| 195 | h316_cpu.c add device dispatch table entry\r |
| 196 | h316_sys.c add sim_devices table entry\r |
| 197 | */\r |
| 198 | \r |
| 199 | #include "h316_defs.h"\r |
| 200 | \r |
| 201 | #define PCQ_SIZE 64 /* must be 2**n */\r |
| 202 | #define PCQ_MASK (PCQ_SIZE - 1)\r |
| 203 | #define PCQ_ENTRY pcq[pcq_p = (pcq_p - 1) & PCQ_MASK] = PC\r |
| 204 | #define PCQ_TOP pcq[pcq_p]\r |
| 205 | #define m7 0001000 /* for generics */\r |
| 206 | #define m8 0000400\r |
| 207 | #define m9 0000200\r |
| 208 | #define m10 0000100\r |
| 209 | #define m11 0000040\r |
| 210 | #define m12 0000020\r |
| 211 | #define m13 0000010\r |
| 212 | #define m14 0000004\r |
| 213 | #define m15 0000002\r |
| 214 | #define m16 0000001\r |
| 215 | \r |
| 216 | #define HIST_PC 0x40000000\r |
| 217 | #define HIST_C 0x20000000\r |
| 218 | #define HIST_EA 0x10000000\r |
| 219 | #define HIST_MIN 64\r |
| 220 | #define HIST_MAX 65536\r |
| 221 | \r |
| 222 | typedef struct {\r |
| 223 | int32 pc;\r |
| 224 | int32 ir;\r |
| 225 | int32 ar;\r |
| 226 | int32 br;\r |
| 227 | int32 xr;\r |
| 228 | int32 ea;\r |
| 229 | int32 opnd;\r |
| 230 | } InstHistory;\r |
| 231 | \r |
| 232 | uint16 M[MAXMEMSIZE] = { 0 }; /* memory */\r |
| 233 | int32 saved_AR = 0; /* A register */\r |
| 234 | int32 saved_BR = 0; /* B register */\r |
| 235 | int32 saved_XR = 0; /* X register */\r |
| 236 | int32 PC = 0; /* P register */\r |
| 237 | int32 C = 0; /* C register */\r |
| 238 | int32 ext = 0; /* extend mode */\r |
| 239 | int32 pme = 0; /* prev mode extend */\r |
| 240 | int32 extoff_pending = 0; /* extend off pending */\r |
| 241 | int32 dp = 0; /* double mode */\r |
| 242 | int32 sc = 0; /* shift count */\r |
| 243 | int32 ss[4]; /* sense switches */\r |
| 244 | int32 dev_int = 0; /* dev ready */\r |
| 245 | int32 dev_enb = 0; /* dev enable */\r |
| 246 | int32 ind_max = 8; /* iadr nest limit */\r |
| 247 | int32 stop_inst = 1; /* stop on ill inst */\r |
| 248 | int32 stop_dev = 2; /* stop on ill dev */\r |
| 249 | uint16 pcq[PCQ_SIZE] = { 0 }; /* PC queue */\r |
| 250 | int32 pcq_p = 0; /* PC queue ptr */\r |
| 251 | REG *pcq_r = NULL; /* PC queue reg ptr */\r |
| 252 | uint32 dma_nch = DMA_MAX; /* number of chan */\r |
| 253 | uint32 dma_ad[DMA_MAX] = { 0 }; /* DMA addresses */\r |
| 254 | uint32 dma_wc[DMA_MAX] = { 0 }; /* DMA word count */\r |
| 255 | uint32 dma_eor[DMA_MAX] = { 0 }; /* DMA end of range */\r |
| 256 | uint32 chan_req = 0; /* channel requests */\r |
| 257 | uint32 chan_map[DMA_MAX + DMC_MAX] = { 0 }; /* chan->dev map */\r |
| 258 | int32 (*iotab[DEV_MAX])(int32 inst, int32 fnc, int32 dat, int32 dev) = { NULL };\r |
| 259 | int32 hst_p = 0; /* history pointer */\r |
| 260 | int32 hst_lnt = 0; /* history length */\r |
| 261 | InstHistory *hst = NULL; /* instruction history */\r |
| 262 | \r |
| 263 | extern int32 sim_int_char;\r |
| 264 | extern int32 sim_interval;\r |
| 265 | extern uint32 sim_brk_types, sim_brk_dflt, sim_brk_summ; /* breakpoint info */\r |
| 266 | extern FILE *sim_log;\r |
| 267 | extern DEVICE *sim_devices[];\r |
| 268 | \r |
| 269 | t_bool devtab_init (void);\r |
| 270 | int32 dmaio (int32 inst, int32 fnc, int32 dat, int32 dev);\r |
| 271 | int32 undio (int32 inst, int32 fnc, int32 dat, int32 dev);\r |
| 272 | t_stat cpu_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw);\r |
| 273 | t_stat cpu_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw);\r |
| 274 | t_stat cpu_reset (DEVICE *dptr);\r |
| 275 | t_stat cpu_set_noext (UNIT *uptr, int32 val, char *cptr, void *desc);\r |
| 276 | t_stat cpu_set_size (UNIT *uptr, int32 val, char *cptr, void *desc);\r |
| 277 | t_stat cpu_set_hist (UNIT *uptr, int32 val, char *cptr, void *desc);\r |
| 278 | t_stat cpu_show_hist (FILE *st, UNIT *uptr, int32 val, void *desc);\r |
| 279 | t_stat cpu_show_dma (FILE *st, UNIT *uptr, int32 val, void *desc);\r |
| 280 | t_stat cpu_set_nchan (UNIT *uptr, int32 val, char *cptr, void *desc);\r |
| 281 | t_stat cpu_show_nchan (FILE *st, UNIT *uptr, int32 val, void *desc);\r |
| 282 | \r |
| 283 | extern t_stat fprint_sym (FILE *of, t_addr addr, t_value *val,\r |
| 284 | UNIT *uptr, int32 sw);\r |
| 285 | \r |
| 286 | /* CPU data structures\r |
| 287 | \r |
| 288 | cpu_dev CPU device descriptor\r |
| 289 | cpu_unit CPU unit descriptor\r |
| 290 | cpu_reg CPU register list\r |
| 291 | cpu_mod CPU modifiers list\r |
| 292 | */\r |
| 293 | \r |
| 294 | DIB cpu_dib = { DMA, IOBUS, 1, &dmaio };\r |
| 295 | \r |
| 296 | UNIT cpu_unit = {\r |
| 297 | UDATA (NULL, UNIT_FIX+UNIT_BINK+UNIT_EXT+UNIT_HSA+UNIT_DMC, MAXMEMSIZE)\r |
| 298 | };\r |
| 299 | \r |
| 300 | REG cpu_reg[] = {\r |
| 301 | { ORDATA (P, PC, 15) },\r |
| 302 | { ORDATA (A, saved_AR, 16) },\r |
| 303 | { ORDATA (B, saved_BR, 16) },\r |
| 304 | { ORDATA (X, XR, 16) },\r |
| 305 | { ORDATA (SC, sc, 16) },\r |
| 306 | { FLDATA (C, C, 0) },\r |
| 307 | { FLDATA (EXT, ext, 0) },\r |
| 308 | { FLDATA (PME, pme, 0) },\r |
| 309 | { FLDATA (EXT_OFF, extoff_pending, 0) },\r |
| 310 | { FLDATA (DP, dp, 0) },\r |
| 311 | { FLDATA (SS1, ss[0], 0) },\r |
| 312 | { FLDATA (SS2, ss[1], 0) },\r |
| 313 | { FLDATA (SS3, ss[2], 0) },\r |
| 314 | { FLDATA (SS4, ss[3], 0) },\r |
| 315 | { FLDATA (ION, dev_int, INT_V_ON) },\r |
| 316 | { FLDATA (INODEF, dev_int, INT_V_NODEF) },\r |
| 317 | { FLDATA (START, dev_int, INT_V_START) },\r |
| 318 | { ORDATA (DEVINT, dev_int, 16), REG_RO },\r |
| 319 | { ORDATA (DEVENB, dev_enb, 16), REG_RO },\r |
| 320 | { ORDATA (CHREQ, chan_req, DMA_MAX + DMC_MAX) },\r |
| 321 | { BRDATA (DMAAD, dma_ad, 8, 16, DMA_MAX) },\r |
| 322 | { BRDATA (DMAWC, dma_wc, 8, 16, DMA_MAX) },\r |
| 323 | { BRDATA (DMAEOR, dma_eor, 8, 1, DMA_MAX) },\r |
| 324 | { ORDATA (DMANCH, dma_nch, 3), REG_HRO },\r |
| 325 | { FLDATA (MPERDY, dev_int, INT_V_MPE) },\r |
| 326 | { FLDATA (MPEENB, dev_enb, INT_V_MPE) },\r |
| 327 | { FLDATA (STOP_INST, stop_inst, 0) },\r |
| 328 | { FLDATA (STOP_DEV, stop_dev, 1) },\r |
| 329 | { DRDATA (INDMAX, ind_max, 8), REG_NZ + PV_LEFT },\r |
| 330 | { BRDATA (PCQ, pcq, 8, 15, PCQ_SIZE), REG_RO + REG_CIRC },\r |
| 331 | { ORDATA (PCQP, pcq_p, 6), REG_HRO },\r |
| 332 | { ORDATA (WRU, sim_int_char, 8) },\r |
| 333 | { NULL }\r |
| 334 | };\r |
| 335 | \r |
| 336 | MTAB cpu_mod[] = {\r |
| 337 | { UNIT_EXT, 0, "no extend", "NOEXTEND", &cpu_set_noext },\r |
| 338 | { UNIT_EXT, UNIT_EXT, "extend", "EXTEND", NULL },\r |
| 339 | { UNIT_HSA, 0, "no HSA", "NOHSA", NULL },\r |
| 340 | { UNIT_HSA, UNIT_HSA, "HSA", "HSA", NULL },\r |
| 341 | { UNIT_MSIZE, 4096, NULL, "4K", &cpu_set_size },\r |
| 342 | { UNIT_MSIZE, 8192, NULL, "8K", &cpu_set_size },\r |
| 343 | { UNIT_MSIZE, 12288, NULL, "12K", &cpu_set_size },\r |
| 344 | { UNIT_MSIZE, 16384, NULL, "16K", &cpu_set_size },\r |
| 345 | { UNIT_MSIZE, 24576, NULL, "24K", &cpu_set_size },\r |
| 346 | { UNIT_MSIZE, 32768, NULL, "32K", &cpu_set_size },\r |
| 347 | { MTAB_XTD | MTAB_VDV, 0, "channels", "CHANNELS",\r |
| 348 | &cpu_set_nchan, &cpu_show_nchan, NULL },\r |
| 349 | { UNIT_DMC, 0, "no DMC", "NODMC", NULL },\r |
| 350 | { UNIT_DMC, UNIT_DMC, "DMC", "DMC", NULL },\r |
| 351 | { MTAB_XTD|MTAB_VDV|MTAB_NMO|MTAB_SHP, 0, "HISTORY", "HISTORY",\r |
| 352 | &cpu_set_hist, &cpu_show_hist },\r |
| 353 | { MTAB_XTD | MTAB_VDV | MTAB_NMO, 0, "DMA1", NULL,\r |
| 354 | NULL, &cpu_show_dma, NULL },\r |
| 355 | { MTAB_XTD | MTAB_VDV | MTAB_NMO, 1, "DMA2", NULL,\r |
| 356 | NULL, &cpu_show_dma, NULL },\r |
| 357 | { MTAB_XTD | MTAB_VDV | MTAB_NMO, 2, "DMA3", NULL,\r |
| 358 | NULL, &cpu_show_dma, NULL },\r |
| 359 | { MTAB_XTD | MTAB_VDV | MTAB_NMO, 3, "DMA4", NULL,\r |
| 360 | NULL, &cpu_show_dma, NULL },\r |
| 361 | { 0 }\r |
| 362 | };\r |
| 363 | \r |
| 364 | DEVICE cpu_dev = {\r |
| 365 | "CPU", &cpu_unit, cpu_reg, cpu_mod,\r |
| 366 | 1, 8, 15, 1, 8, 16,\r |
| 367 | &cpu_ex, &cpu_dep, &cpu_reset,\r |
| 368 | NULL, NULL, NULL,\r |
| 369 | &cpu_dib, 0\r |
| 370 | };\r |
| 371 | \r |
| 372 | t_stat sim_instr (void)\r |
| 373 | {\r |
| 374 | int32 AR, BR, MB, Y, t1, t2, t3, skip, dev;\r |
| 375 | uint32 ut;\r |
| 376 | t_stat reason;\r |
| 377 | t_stat Ea (int32 inst, int32 *addr);\r |
| 378 | void Write (int32 addr, int32 val);\r |
| 379 | int32 Add16 (int32 val1, int32 val2);\r |
| 380 | int32 Add31 (int32 val1, int32 val2);\r |
| 381 | int32 Operate (int32 MB, int32 AR);\r |
| 382 | \r |
| 383 | #define Read(ad) M[(ad)]\r |
| 384 | #define GETDBL_S(h,l) (((h) << 15) | ((l) & MMASK))\r |
| 385 | #define GETDBL_U(h,l) (((h) << 16) | (l))\r |
| 386 | #define PUTDBL_S(x) AR = ((x) >> 15) & DMASK; \\r |
| 387 | BR = (BR & SIGN) | ((x) & MMASK)\r |
| 388 | #define PUTDBL_U(x) AR = ((x) >> 16) & DMASK; \\r |
| 389 | BR = (x) & DMASK\r |
| 390 | #define SEXT(x) (((x) & SIGN)? ((x) | ~DMASK): ((x) & DMASK))\r |
| 391 | #define NEWA(c,n) (ext? (((c) & ~X_AMASK) | ((n) & X_AMASK)): \\r |
| 392 | (((c) & ~NX_AMASK) | ((n) & NX_AMASK)))\r |
| 393 | \r |
| 394 | /* Restore register state */\r |
| 395 | \r |
| 396 | if (devtab_init ()) return SCPE_STOP; /* init tables */\r |
| 397 | AR = saved_AR & DMASK; /* restore reg */\r |
| 398 | BR = saved_BR & DMASK;\r |
| 399 | XR = saved_XR & DMASK;\r |
| 400 | PC = PC & ((cpu_unit.flags & UNIT_EXT)? X_AMASK: NX_AMASK); /* mask PC */\r |
| 401 | reason = 0;\r |
| 402 | \r |
| 403 | /* Main instruction fetch/decode loop */\r |
| 404 | \r |
| 405 | while (reason == 0) { /* loop until halted */\r |
| 406 | \r |
| 407 | if (sim_interval <= 0) { /* check clock queue */\r |
| 408 | if (reason = sim_process_event ()) break;\r |
| 409 | }\r |
| 410 | \r |
| 411 | /* Channel breaks (DMA and DMC) */\r |
| 412 | \r |
| 413 | if (chan_req) { /* channel request? */\r |
| 414 | int32 i, t, ch, dev, st, end, ad, dmcad;\r |
| 415 | t_stat r;\r |
| 416 | for (i = 0, ch = chan_req; ch != 0; i++, ch = ch >> 1) {\r |
| 417 | if (ch & 1) { /* req on chan i? */\r |
| 418 | dev = chan_map[i]; /* get dev for chan */\r |
| 419 | if (iotab[dev] == &undio) return SCPE_IERR;\r |
| 420 | chan_req = chan_req & ~(1 << i); /* clear req */\r |
| 421 | if (Q_DMA (i)) st = dma_ad[i]; /* DMA? */\r |
| 422 | else { /* DMC */\r |
| 423 | dmcad = DMC_BASE + ((i - DMC_V_DMC1) << 1);\r |
| 424 | st = Read (dmcad); /* DMC ctrl word */\r |
| 425 | }\r |
| 426 | ad = st & X_AMASK; /* get curr addr */\r |
| 427 | if (st & DMA_IN) { /* input? */\r |
| 428 | t = iotab[dev] (ioINA, 0, 0, dev); /* input word */\r |
| 429 | if ((t & IOT_SKIP) == 0) return STOP_DMAER;\r |
| 430 | if ((r = t >> IOT_V_REASON) != 0) return r;\r |
| 431 | Write (ad, t & DMASK); /* write to mem */\r |
| 432 | }\r |
| 433 | else { /* no, output */\r |
| 434 | t = iotab[dev] (ioOTA, 0, Read (ad), dev); /* output word */\r |
| 435 | if ((t & IOT_SKIP) == 0) return STOP_DMAER;\r |
| 436 | if (r = (t >> IOT_V_REASON)) return r;\r |
| 437 | }\r |
| 438 | if (Q_DMA (i)) { /* DMA? */\r |
| 439 | dma_ad[i] = (dma_ad[i] & DMA_IN) | ((ad + 1) & X_AMASK);\r |
| 440 | dma_wc[i] = (dma_wc[i] + 1) & 077777; /* update wc */\r |
| 441 | if (dma_wc[i] == 0) { /* done? */\r |
| 442 | dma_eor[i] = 1; /* set end of range */\r |
| 443 | t = iotab[dev] (ioEND, 0, 0, dev); /* send end range */\r |
| 444 | if ((r = t >> IOT_V_REASON) != 0) return r;\r |
| 445 | }\r |
| 446 | }\r |
| 447 | else { /* DMC */\r |
| 448 | st = (st & DMA_IN) | ((ad + 1) & X_AMASK);\r |
| 449 | Write (dmcad, st); /* update start */\r |
| 450 | end = Read (dmcad + 1); /* get end */\r |
| 451 | if (((ad ^ end) & X_AMASK) == 0) { /* start == end? */\r |
| 452 | t = iotab[dev] (ioEND, 0, 0, dev); /* send end range */\r |
| 453 | if ((r = t >> IOT_V_REASON) != 0) return r;\r |
| 454 | } /* end if end range */\r |
| 455 | } /* end else DMC */\r |
| 456 | } /* end if chan i */\r |
| 457 | } /* end for */\r |
| 458 | } /* end if chan_req */\r |
| 459 | \r |
| 460 | \r |
| 461 | /* Interrupts */\r |
| 462 | \r |
| 463 | if ((dev_int & (INT_PEND|INT_NMI|dev_enb)) > INT_PEND) {/* int req? */\r |
| 464 | pme = ext; /* save extend */\r |
| 465 | if (cpu_unit.flags & UNIT_EXT) ext = 1; /* ext opt? extend on */\r |
| 466 | dev_int = dev_int & ~INT_ON; /* intr off */\r |
| 467 | MB = 0120000 | M_INT; /* inst = JST* 63 */\r |
| 468 | }\r |
| 469 | \r |
| 470 | /* Instruction fetch */\r |
| 471 | \r |
| 472 | else {\r |
| 473 | if (sim_brk_summ &&\r |
| 474 | sim_brk_test (PC, SWMASK ('E'))) { /* breakpoint? */\r |
| 475 | reason = STOP_IBKPT; /* stop simulation */\r |
| 476 | break;\r |
| 477 | }\r |
| 478 | Y = PC; /* set mem addr */\r |
| 479 | MB = Read (Y); /* fetch instr */\r |
| 480 | PC = NEWA (Y, Y + 1); /* incr PC */\r |
| 481 | dev_int = dev_int | INT_NODEF;\r |
| 482 | }\r |
| 483 | \r |
| 484 | dev_int = dev_int & ~INT_START; /* clr start button int */\r |
| 485 | sim_interval = sim_interval - 1;\r |
| 486 | if (hst_lnt) { /* instr hist? */\r |
| 487 | hst_p = (hst_p + 1); /* next entry */\r |
| 488 | if (hst_p >= hst_lnt) hst_p = 0;\r |
| 489 | hst[hst_p].pc = Y | HIST_PC | (C? HIST_C: 0); /* fill slots */\r |
| 490 | hst[hst_p].ir = MB;\r |
| 491 | hst[hst_p].ar = AR;\r |
| 492 | hst[hst_p].br = BR;\r |
| 493 | hst[hst_p].xr = XR;\r |
| 494 | }\r |
| 495 | \r |
| 496 | /* Memory reference instructions */\r |
| 497 | \r |
| 498 | switch (I_GETOP (MB)) { /* case on <1:6> */\r |
| 499 | \r |
| 500 | case 001: case 021: case 041: case 061: /* JMP */\r |
| 501 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 502 | PCQ_ENTRY; /* save PC */\r |
| 503 | PC = NEWA (PC, Y); /* set new PC */\r |
| 504 | if (extoff_pending) ext = extoff_pending = 0; /* cond ext off */\r |
| 505 | break;\r |
| 506 | \r |
| 507 | case 002: case 022: case 042: case 062: /* LDA */\r |
| 508 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 509 | if (dp) { /* double prec? */\r |
| 510 | AR = Read (Y & ~1); /* get doubleword */\r |
| 511 | BR = Read (Y | 1);\r |
| 512 | sc = 0;\r |
| 513 | }\r |
| 514 | else AR = Read (Y); /* no, get word */\r |
| 515 | break;\r |
| 516 | \r |
| 517 | case 003: case 023: case 043: case 063: /* ANA */\r |
| 518 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 519 | AR = AR & Read (Y);\r |
| 520 | break;\r |
| 521 | \r |
| 522 | case 004: case 024: case 044: case 064: /* STA */\r |
| 523 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 524 | Write (Y, AR); /* store A */\r |
| 525 | if (dp) { /* double prec? */\r |
| 526 | Write (Y | 1, BR); /* store B */\r |
| 527 | sc = 0;\r |
| 528 | }\r |
| 529 | break;\r |
| 530 | \r |
| 531 | case 005: case 025: case 045: case 065: /* ERA */\r |
| 532 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 533 | AR = AR ^ Read (Y);\r |
| 534 | break;\r |
| 535 | \r |
| 536 | case 006: case 026: case 046: case 066: /* ADD */\r |
| 537 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 538 | if (dp) { /* double prec? */\r |
| 539 | t1 = GETDBL_S (AR, BR); /* get A'B */\r |
| 540 | t2 = GETDBL_S (Read (Y & ~1), Read (Y | 1));\r |
| 541 | t1 = Add31 (t1, t2); /* 31b add */\r |
| 542 | PUTDBL_S (t1);\r |
| 543 | sc = 0;\r |
| 544 | }\r |
| 545 | else AR = Add16 (AR, Read (Y)); /* no, 16b add */\r |
| 546 | break;\r |
| 547 | \r |
| 548 | case 007: case 027: case 047: case 067: /* SUB */\r |
| 549 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 550 | if (dp) { /* double prec? */\r |
| 551 | t1 = GETDBL_S (AR, BR); /* get A'B */\r |
| 552 | t2 = GETDBL_S (Read (Y & ~1), Read (Y | 1));\r |
| 553 | t1 = Add31 (t1, -t2); /* 31b sub */\r |
| 554 | PUTDBL_S (t1);\r |
| 555 | sc = 0;\r |
| 556 | }\r |
| 557 | else AR = Add16 (AR, (-Read (Y)) & DMASK); /* no, 16b sub */\r |
| 558 | break;\r |
| 559 | \r |
| 560 | case 010: case 030: case 050: case 070: /* JST */\r |
| 561 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 562 | MB = NEWA (Read (Y), PC); /* merge old PC */\r |
| 563 | Write (Y, MB);\r |
| 564 | PCQ_ENTRY;\r |
| 565 | PC = NEWA (PC, Y + 1); /* set new PC */\r |
| 566 | break;\r |
| 567 | \r |
| 568 | case 011: case 031: case 051: case 071: /* CAS */\r |
| 569 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 570 | MB = Read (Y);\r |
| 571 | if (AR == MB) PC = NEWA (PC, PC + 1);\r |
| 572 | else if (SEXT (AR) < SEXT (MB)) PC = NEWA (PC, PC + 2);\r |
| 573 | break;\r |
| 574 | \r |
| 575 | case 012: case 032: case 052: case 072: /* IRS */\r |
| 576 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 577 | MB = (Read (Y) + 1) & DMASK; /* incr, rewrite */\r |
| 578 | Write (Y, MB);\r |
| 579 | if (MB == 0) PC = NEWA (PC, PC + 1); /* skip if zero */\r |
| 580 | break;\r |
| 581 | \r |
| 582 | case 013: case 033: case 053: case 073: /* IMA */\r |
| 583 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 584 | MB = Read (Y);\r |
| 585 | Write (Y, AR); /* A to mem */\r |
| 586 | AR = MB; /* mem to A */\r |
| 587 | break;\r |
| 588 | \r |
| 589 | case 015: case 055: /* STX */\r |
| 590 | if (reason = Ea (MB & ~IDX, &Y)) break; /* eff addr */\r |
| 591 | Write (Y, XR); /* store XR */\r |
| 592 | break;\r |
| 593 | \r |
| 594 | case 035: case 075: /* LDX */\r |
| 595 | if (reason = Ea (MB & ~IDX, &Y)) break; /* eff addr */\r |
| 596 | XR = Read (Y); /* load XR */\r |
| 597 | break;\r |
| 598 | \r |
| 599 | case 016: case 036: case 056: case 076: /* MPY */\r |
| 600 | if (cpu_unit.flags & UNIT_HSA) { /* installed? */\r |
| 601 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 602 | t1 = SEXT (AR) * SEXT (Read (Y));\r |
| 603 | PUTDBL_S (t1);\r |
| 604 | sc = 0;\r |
| 605 | }\r |
| 606 | else reason = stop_inst;\r |
| 607 | break;\r |
| 608 | \r |
| 609 | case 017: case 037: case 057: case 077: /* DIV */\r |
| 610 | if (cpu_unit.flags & UNIT_HSA) { /* installed? */\r |
| 611 | if (reason = Ea (MB, &Y)) break; /* eff addr */\r |
| 612 | t2 = SEXT (Read (Y)); /* divr */\r |
| 613 | if (t2) { /* divr != 0? */\r |
| 614 | t1 = GETDBL_S (SEXT (AR), BR); /* get A'B signed */\r |
| 615 | BR = (t1 % t2) & DMASK; /* remainder */\r |
| 616 | t1 = t1 / t2; /* quotient */\r |
| 617 | AR = t1 & DMASK;\r |
| 618 | if ((t1 > MMASK) || (t1 < (-SIGN))) C = 1;\r |
| 619 | else C = 0;\r |
| 620 | sc = 0;\r |
| 621 | }\r |
| 622 | else C = 1;\r |
| 623 | }\r |
| 624 | else reason = stop_inst;\r |
| 625 | break;\r |
| 626 | \r |
| 627 | /* I/O instructions */\r |
| 628 | \r |
| 629 | case 014: /* OCP */\r |
| 630 | dev = MB & DEVMASK;\r |
| 631 | t2 = iotab[dev] (ioOCP, I_GETFNC (MB), AR, dev);\r |
| 632 | reason = t2 >> IOT_V_REASON;\r |
| 633 | break;\r |
| 634 | \r |
| 635 | case 034: /* SKS */\r |
| 636 | dev = MB & DEVMASK;\r |
| 637 | t2 = iotab[dev] (ioSKS, I_GETFNC (MB), AR, dev);\r |
| 638 | reason = t2 >> IOT_V_REASON;\r |
| 639 | if (t2 & IOT_SKIP) PC = NEWA (PC, PC + 1); /* skip? */\r |
| 640 | break;\r |
| 641 | \r |
| 642 | case 054: /* INA */\r |
| 643 | dev = MB & DEVMASK;\r |
| 644 | if (MB & INCLRA) AR = 0;\r |
| 645 | t2 = iotab[dev] (ioINA, I_GETFNC (MB & ~INCLRA), AR, dev);\r |
| 646 | reason = t2 >> IOT_V_REASON;\r |
| 647 | if (t2 & IOT_SKIP) PC = NEWA (PC, PC + 1); /* skip? */\r |
| 648 | AR = t2 & DMASK; /* data */\r |
| 649 | break;\r |
| 650 | \r |
| 651 | case 074: /* OTA */\r |
| 652 | dev = MB & DEVMASK;\r |
| 653 | t2 = iotab[dev] (ioOTA, I_GETFNC (MB), AR, dev);\r |
| 654 | reason = t2 >> IOT_V_REASON;\r |
| 655 | if (t2 & IOT_SKIP) PC = NEWA (PC, PC + 1); /* skip? */\r |
| 656 | break;\r |
| 657 | \r |
| 658 | /* Control */\r |
| 659 | \r |
| 660 | case 000:\r |
| 661 | if ((MB & 1) == 0) { /* HLT */\r |
| 662 | if ((reason = sim_process_event ()) != SCPE_OK) break;\r |
| 663 | reason = STOP_HALT;\r |
| 664 | break;\r |
| 665 | }\r |
| 666 | if (MB & m14) { /* SGL, DBL */\r |
| 667 | if (cpu_unit.flags & UNIT_HSA) dp = (MB & m15)? 1: 0;\r |
| 668 | else reason = stop_inst;\r |
| 669 | }\r |
| 670 | if (MB & m13) { /* DXA, EXA */\r |
| 671 | if (!(cpu_unit.flags & UNIT_EXT)) reason = stop_inst;\r |
| 672 | else if (MB & m15) { /* EXA */\r |
| 673 | ext = 1;\r |
| 674 | extoff_pending = 0; /* DXA */\r |
| 675 | }\r |
| 676 | else extoff_pending = 1;\r |
| 677 | }\r |
| 678 | if (MB & m12) CLR_INT (INT_MPE); /* RMP */\r |
| 679 | if (MB & m11) { /* SCA, INK */\r |
| 680 | if (MB & m15) /* INK */\r |
| 681 | AR = (C << 15) | (dp << 14) | (pme << 13) | (sc & 037);\r |
| 682 | else if (cpu_unit.flags & UNIT_HSA) /* SCA */\r |
| 683 | AR = sc & 037;\r |
| 684 | else reason = stop_inst; \r |
| 685 | }\r |
| 686 | else if (MB & m10) { /* NRM */\r |
| 687 | if (cpu_unit.flags & UNIT_HSA) {\r |
| 688 | for (sc = 0;\r |
| 689 | (sc <= 32) && ((AR & SIGN) != ((AR << 1) & SIGN));\r |
| 690 | sc++) {\r |
| 691 | AR = (AR & SIGN) | ((AR << 1) & MMASK) |\r |
| 692 | ((BR >> 14) & 1);\r |
| 693 | BR = (BR & SIGN) | ((BR << 1) & MMASK);\r |
| 694 | }\r |
| 695 | sc = sc & 037;\r |
| 696 | }\r |
| 697 | else reason = stop_inst;\r |
| 698 | }\r |
| 699 | else if (MB & m9) { /* IAB */\r |
| 700 | sc = BR;\r |
| 701 | BR = AR;\r |
| 702 | AR = sc;\r |
| 703 | }\r |
| 704 | if (MB & m8) /* ENB */\r |
| 705 | dev_int = (dev_int | INT_ON) & ~INT_NODEF;\r |
| 706 | if (MB & m7) /* INH */\r |
| 707 | dev_int = dev_int & ~INT_ON;\r |
| 708 | break;\r |
| 709 | \r |
| 710 | /* Shift\r |
| 711 | \r |
| 712 | Shifts are microcoded as follows:\r |
| 713 | \r |
| 714 | op<7> = right/left\r |
| 715 | op<8> = long/short\r |
| 716 | op<9> = shift/rotate (rotate bits "or" into new position)\r |
| 717 | op<10> = logical/arithmetic\r |
| 718 | \r |
| 719 | If !op<7> && op<10> (right arithmetic), A<1> propagates rightward\r |
| 720 | If op<7> && op<10> (left arithmetic), C is set if A<1> changes state\r |
| 721 | If !op<8> && op<10> (long arithmetic), B<1> is skipped\r |
| 722 | \r |
| 723 | This microcoding "explains" how the 4 undefined opcodes actually work\r |
| 724 | 003 = long arith rotate right, skip B<1>, propagate A<1>,\r |
| 725 | bits rotated out "or" into A<1>\r |
| 726 | 007 = short arith rotate right, propagate A<1>,\r |
| 727 | bits rotated out "or" into A<1>\r |
| 728 | 013 = long arith rotate left, skip B<1>, C = overflow\r |
| 729 | 017 = short arith rotate left, C = overflow\r |
| 730 | */\r |
| 731 | \r |
| 732 | case 020:\r |
| 733 | C = 0; /* clear C */\r |
| 734 | sc = 0; /* clear sc */\r |
| 735 | if ((t1 = (-MB) & SHFMASK) == 0) break; /* shift count */\r |
| 736 | switch (I_GETFNC (MB)) { /* case shift fnc */\r |
| 737 | \r |
| 738 | case 000: /* LRL */\r |
| 739 | if (t1 > 32) ut = 0; /* >32? all 0 */\r |
| 740 | else {\r |
| 741 | ut = GETDBL_U (AR, BR); /* get A'B */\r |
| 742 | C = (ut >> (t1 - 1)) & 1; /* C = last out */\r |
| 743 | if (t1 == 32) ut = 0; /* =32? all 0 */\r |
| 744 | else ut = ut >> t1; /* log right */\r |
| 745 | }\r |
| 746 | PUTDBL_U (ut); /* store A,B */\r |
| 747 | break;\r |
| 748 | \r |
| 749 | case 001: /* LRS */\r |
| 750 | if (t1 > 31) t1 = 31; /* limit to 31 */\r |
| 751 | t2 = GETDBL_S (SEXT (AR), BR); /* get A'B signed */\r |
| 752 | C = (t2 >> (t1 - 1)) & 1; /* C = last out */\r |
| 753 | t2 = t2 >> t1; /* arith right */\r |
| 754 | PUTDBL_S (t2); /* store A,B */\r |
| 755 | break;\r |
| 756 | \r |
| 757 | case 002: /* LRR */\r |
| 758 | t2 = t1 % 32; /* mod 32 */\r |
| 759 | ut = GETDBL_U (AR, BR); /* get A'B */\r |
| 760 | ut = (ut >> t2) | (ut << (32 - t2)); /* rot right */\r |
| 761 | C = (ut >> 31) & 1; /* C = A<1> */\r |
| 762 | PUTDBL_U (ut); /* store A,B */\r |
| 763 | break;\r |
| 764 | \r |
| 765 | case 003: /* "long right arot" */\r |
| 766 | if (reason = stop_inst) break; /* stop on undef? */\r |
| 767 | for (t2 = 0; t2 < t1; t2++) { /* bit by bit */\r |
| 768 | C = BR & 1; /* C = last out */\r |
| 769 | BR = (BR & SIGN) | ((AR & 1) << 14) |\r |
| 770 | ((BR & MMASK) >> 1);\r |
| 771 | AR = ((AR & SIGN) | (C << 15)) | (AR >> 1);\r |
| 772 | }\r |
| 773 | break;\r |
| 774 | \r |
| 775 | case 004: /* LGR */\r |
| 776 | if (t1 > 16) AR = 0; /* > 16? all 0 */\r |
| 777 | else {\r |
| 778 | C = (AR >> (t1 - 1)) & 1; /* C = last out */\r |
| 779 | AR = (AR >> t1) & DMASK; /* log right */\r |
| 780 | }\r |
| 781 | break;\r |
| 782 | \r |
| 783 | case 005: /* ARS */\r |
| 784 | if (t1 > 16) t1 = 16; /* limit to 16 */\r |
| 785 | C = ((SEXT (AR)) >> (t1 - 1)) & 1; /* C = last out */\r |
| 786 | AR = ((SEXT (AR)) >> t1) & DMASK; /* arith right */\r |
| 787 | break; \r |
| 788 | \r |
| 789 | case 006: /* ARR */\r |
| 790 | t2 = t1 % 16; /* mod 16 */\r |
| 791 | AR = ((AR >> t2) | (AR << (16 - t2))) & DMASK;\r |
| 792 | C = (AR >> 15) & 1; /* C = A<1> */\r |
| 793 | break;\r |
| 794 | \r |
| 795 | case 007: /* "short right arot" */\r |
| 796 | if (reason = stop_inst) break; /* stop on undef? */\r |
| 797 | for (t2 = 0; t2 < t1; t2++) { /* bit by bit */\r |
| 798 | C = AR & 1; /* C = last out */\r |
| 799 | AR = ((AR & SIGN) | (C << 15)) | (AR >> 1);\r |
| 800 | }\r |
| 801 | break;\r |
| 802 | \r |
| 803 | case 010: /* LLL */\r |
| 804 | if (t1 > 32) ut = 0; /* > 32? all 0 */\r |
| 805 | else {\r |
| 806 | ut = GETDBL_U (AR, BR); /* get A'B */\r |
| 807 | C = (ut >> (32 - t1)) & 1; /* C = last out */\r |
| 808 | if (t1 == 32) ut = 0; /* =32? all 0 */\r |
| 809 | else ut = ut << t1; /* log left */\r |
| 810 | }\r |
| 811 | PUTDBL_U (ut); /* store A,B */\r |
| 812 | break;\r |
| 813 | \r |
| 814 | case 011: /* LLS */\r |
| 815 | if (t1 > 31) t1 = 31; /* limit to 31 */\r |
| 816 | t2 = GETDBL_S (SEXT (AR), BR); /* get A'B */\r |
| 817 | t3 = t2 << t1; /* "arith" left */\r |
| 818 | PUTDBL_S (t3); /* store A'B */\r |
| 819 | if ((t2 >> (31 - t1)) != /* shf out = sgn? */\r |
| 820 | ((AR & SIGN)? -1: 0)) C = 1;\r |
| 821 | break;\r |
| 822 | \r |
| 823 | case 012: /* LLR */\r |
| 824 | t2 = t1 % 32; /* mod 32 */\r |
| 825 | ut = GETDBL_U (AR, BR); /* get A'B */\r |
| 826 | ut = (ut << t2) | (ut >> (32 - t2)); /* rot left */\r |
| 827 | C = ut & 1; /* C = B<16> */\r |
| 828 | PUTDBL_U (ut); /* store A,B */\r |
| 829 | break;\r |
| 830 | \r |
| 831 | case 013: /* "long left arot" */\r |
| 832 | if (reason = stop_inst) break; /* stop on undef? */\r |
| 833 | for (t2 = 0; t2 < t1; t2++) { /* bit by bit */\r |
| 834 | AR = (AR << 1) | ((BR >> 14) & 1);\r |
| 835 | BR = (BR & SIGN) | ((BR << 1) & MMASK) |\r |
| 836 | ((AR >> 16) & 1);\r |
| 837 | if ((AR & SIGN) != ((AR >> 1) & SIGN)) C = 1;\r |
| 838 | AR = AR & DMASK;\r |
| 839 | }\r |
| 840 | break;\r |
| 841 | \r |
| 842 | case 014: /* LGL */\r |
| 843 | if (t1 > 16) AR = 0; /* > 16? all 0 */\r |
| 844 | else {\r |
| 845 | C = (AR >> (16 - t1)) & 1; /* C = last out */\r |
| 846 | AR = (AR << t1) & DMASK; /* log left */\r |
| 847 | }\r |
| 848 | break;\r |
| 849 | \r |
| 850 | case 015: /* ALS */\r |
| 851 | if (t1 > 16) t1 = 16; /* limit to 16 */\r |
| 852 | t2 = SEXT (AR); /* save AR */\r |
| 853 | AR = (AR << t1) & DMASK; /* "arith" left */\r |
| 854 | if ((t2 >> (16 - t1)) != /* shf out + sgn */\r |
| 855 | ((AR & SIGN)? -1: 0)) C = 1;\r |
| 856 | break;\r |
| 857 | \r |
| 858 | case 016: /* ALR */\r |
| 859 | t2 = t1 % 16; /* mod 16 */\r |
| 860 | AR = ((AR << t2) | (AR >> (16 - t2))) & DMASK;\r |
| 861 | C = AR & 1; /* C = A<16> */\r |
| 862 | break;\r |
| 863 | \r |
| 864 | case 017: /* "short left arot" */\r |
| 865 | if (reason = stop_inst) break; /* stop on undef? */\r |
| 866 | for (t2 = 0; t2 < t1; t2++) { /* bit by bit */\r |
| 867 | if ((AR & SIGN) != ((AR << 1) & SIGN)) C = 1;\r |
| 868 | AR = ((AR << 1) | (AR >> 15)) & DMASK;\r |
| 869 | }\r |
| 870 | break; /* end case fnc */\r |
| 871 | }\r |
| 872 | break;\r |
| 873 | \r |
| 874 | /* Skip */\r |
| 875 | \r |
| 876 | case 040:\r |
| 877 | skip = 0;\r |
| 878 | if (((MB & 000001) && C) || /* SSC */\r |
| 879 | ((MB & 000002) && ss[3]) || /* SS4 */\r |
| 880 | ((MB & 000004) && ss[2]) || /* SS3 */\r |
| 881 | ((MB & 000010) && ss[1]) || /* SS2 */\r |
| 882 | ((MB & 000020) && ss[0]) || /* SS1 */\r |
| 883 | ((MB & 000040) && AR) || /* SNZ */\r |
| 884 | ((MB & 000100) && (AR & 1)) || /* SLN */\r |
| 885 | ((MB & 000200) && (TST_INTREQ (INT_MPE))) || /* SPS */\r |
| 886 | ((MB & 000400) && (AR & SIGN))) skip = 1; /* SMI */\r |
| 887 | if ((MB & 001000) == 0) skip = skip ^ 1; /* reverse? */\r |
| 888 | PC = NEWA (PC, PC + skip);\r |
| 889 | break;\r |
| 890 | \r |
| 891 | /* Operate */\r |
| 892 | \r |
| 893 | case 060:\r |
| 894 | if (MB == 0140024) AR = AR ^ SIGN; /* CHS */\r |
| 895 | else if (MB == 0140040) AR = 0; /* CRA */\r |
| 896 | else if (MB == 0140100) AR = AR & ~SIGN; /* SSP */\r |
| 897 | else if (MB == 0140200) C = 0; /* RCB */\r |
| 898 | else if (MB == 0140320) { /* CSA */\r |
| 899 | C = (AR & SIGN) >> 15;\r |
| 900 | AR = AR & ~SIGN;\r |
| 901 | }\r |
| 902 | else if (MB == 0140401) AR = AR ^ DMASK; /* CMA */\r |
| 903 | else if (MB == 0140407) { /* TCA */\r |
| 904 | AR = (-AR) & DMASK;\r |
| 905 | sc = 0;\r |
| 906 | }\r |
| 907 | else if (MB == 0140500) AR = AR | SIGN; /* SSM */\r |
| 908 | else if (MB == 0140600) C = 1; /* SCB */\r |
| 909 | else if (MB == 0141044) AR = AR & 0177400; /* CAR */\r |
| 910 | else if (MB == 0141050) AR = AR & 0377; /* CAL */\r |
| 911 | else if (MB == 0141140) AR = AR >> 8; /* ICL */\r |
| 912 | else if (MB == 0141206) AR = Add16 (AR, 1); /* AOA */\r |
| 913 | else if (MB == 0141216) AR = Add16 (AR, C); /* ACA */\r |
| 914 | else if (MB == 0141240) AR = (AR << 8) & DMASK; /* ICR */\r |
| 915 | else if (MB == 0141340) /* ICA */\r |
| 916 | AR = ((AR << 8) | (AR >> 8)) & DMASK;\r |
| 917 | else if (reason = stop_inst) break;\r |
| 918 | else AR = Operate (MB, AR); /* undefined */\r |
| 919 | break;\r |
| 920 | } /* end case op */\r |
| 921 | } /* end while */\r |
| 922 | \r |
| 923 | saved_AR = AR & DMASK;\r |
| 924 | saved_BR = BR & DMASK;\r |
| 925 | saved_XR = XR & DMASK;\r |
| 926 | pcq_r->qptr = pcq_p; /* update pc q ptr */\r |
| 927 | return reason;\r |
| 928 | }\r |
| 929 | \r |
| 930 | /* Effective address\r |
| 931 | \r |
| 932 | The effective address calculation consists of three phases:\r |
| 933 | - base address calculation: 0/pagenumber'displacement\r |
| 934 | - (extend): indirect address resolution\r |
| 935 | (non-extend): pre-indexing\r |
| 936 | - (extend): post-indexing\r |
| 937 | (non-extend): indirect address/post-indexing resolution\r |
| 938 | \r |
| 939 | In extend mode, address calculations are carried out to 16b\r |
| 940 | and masked to 15b at exit. In non-extend mode, address bits\r |
| 941 | <1:2> are preserved by the NEWA macro; address bit <1> is\r |
| 942 | masked at exit.\r |
| 943 | */\r |
| 944 | \r |
| 945 | t_stat Ea (int32 IR, int32 *addr)\r |
| 946 | {\r |
| 947 | int32 i;\r |
| 948 | int32 Y = IR & (IA | DISP); /* ind + disp */\r |
| 949 | \r |
| 950 | if (IR & SC) Y = ((PC - 1) & PAGENO) | Y; /* cur sec? + pageno */\r |
| 951 | if (ext) { /* extend mode? */\r |
| 952 | for (i = 0; (i < ind_max) && (Y & IA); i++) { /* resolve ind addr */\r |
| 953 | Y = Read (Y & X_AMASK); /* get ind addr */\r |
| 954 | }\r |
| 955 | if (IR & IDX) Y = Y + XR; /* post-index */\r |
| 956 | } /* end if ext */\r |
| 957 | else { /* non-extend */\r |
| 958 | Y = NEWA (PC, Y + ((IR & IDX)? XR: 0)); /* pre-index */\r |
| 959 | for (i = 0; (i < ind_max) && (IR & IA); i++) { /* resolve ind addr */\r |
| 960 | IR = Read (Y & X_AMASK); /* get ind addr */\r |
| 961 | Y = NEWA (Y, IR + ((IR & IDX)? XR: 0)); /* post-index */\r |
| 962 | }\r |
| 963 | } /* end else */\r |
| 964 | *addr = Y = Y & X_AMASK; /* return addr */\r |
| 965 | if (hst_lnt) { /* history? */\r |
| 966 | hst[hst_p].pc = hst[hst_p].pc | HIST_EA;\r |
| 967 | hst[hst_p].ea = Y;\r |
| 968 | hst[hst_p].opnd = Read (Y);\r |
| 969 | }\r |
| 970 | if (i >= ind_max) return STOP_IND; /* too many ind? */\r |
| 971 | return SCPE_OK;\r |
| 972 | }\r |
| 973 | \r |
| 974 | /* Write memory */\r |
| 975 | \r |
| 976 | void Write (int32 addr, int32 val)\r |
| 977 | {\r |
| 978 | if (((addr == 0) || (addr >= 020)) && MEM_ADDR_OK (addr))\r |
| 979 | M[addr] = val;\r |
| 980 | return;\r |
| 981 | }\r |
| 982 | \r |
| 983 | /* Add */\r |
| 984 | \r |
| 985 | int32 Add16 (int32 v1, int32 v2)\r |
| 986 | {\r |
| 987 | int32 r = v1 + v2;\r |
| 988 | \r |
| 989 | if (((v1 ^ ~v2) & (v1 ^ r)) & SIGN) C = 1;\r |
| 990 | else C = 0;\r |
| 991 | return (r & DMASK);\r |
| 992 | }\r |
| 993 | \r |
| 994 | int32 Add31 (int32 v1, int32 v2)\r |
| 995 | {\r |
| 996 | int32 r = v1 + v2;\r |
| 997 | \r |
| 998 | if (((v1 ^ ~v2) & (v1 ^ r)) & DP_SIGN) C = 1;\r |
| 999 | else C = 0;\r |
| 1000 | return r;\r |
| 1001 | }\r |
| 1002 | \r |
| 1003 | /* Unimplemented I/O device */\r |
| 1004 | \r |
| 1005 | int32 undio (int32 op, int32 fnc, int32 val, int32 dev)\r |
| 1006 | {\r |
| 1007 | return ((stop_dev << IOT_V_REASON) | val);\r |
| 1008 | }\r |
| 1009 | \r |
| 1010 | /* DMA control */\r |
| 1011 | \r |
| 1012 | int32 dmaio (int32 inst, int32 fnc, int32 dat, int32 dev)\r |
| 1013 | {\r |
| 1014 | int32 ch = (fnc - 1) & 03;\r |
| 1015 | \r |
| 1016 | switch (inst) { /* case on opcode */\r |
| 1017 | \r |
| 1018 | case ioOCP: /* OCP */\r |
| 1019 | if ((fnc >= 001) && (fnc <= 004)) { /* load addr ctr */\r |
| 1020 | dma_ad[ch] = dat;\r |
| 1021 | dma_wc[ch] = 0;\r |
| 1022 | dma_eor[ch] = 0;\r |
| 1023 | }\r |
| 1024 | else if ((fnc >= 011) && (fnc <= 014)) /* load range ctr */\r |
| 1025 | dma_wc[ch] = (dma_wc[ch] | dat) & 077777;\r |
| 1026 | else return IOBADFNC (dat); /* undefined */\r |
| 1027 | break;\r |
| 1028 | \r |
| 1029 | case ioINA: /* INA */\r |
| 1030 | if ((fnc >= 011) && (fnc <= 014)) {\r |
| 1031 | if (dma_eor[ch]) return dat; /* end range? nop */\r |
| 1032 | return IOSKIP (0100000 | dma_wc[ch]); /* return range */\r |
| 1033 | }\r |
| 1034 | else return IOBADFNC (dat);\r |
| 1035 | }\r |
| 1036 | \r |
| 1037 | return dat;\r |
| 1038 | }\r |
| 1039 | \r |
| 1040 | /* Undefined operate instruction. This code is reached when the\r |
| 1041 | opcode does not correspond to a standard operate instruction.\r |
| 1042 | It simulates the behavior of the actual logic.\r |
| 1043 | \r |
| 1044 | An operate instruction executes in 4 or 6 phases. A 'normal'\r |
| 1045 | instruction takes 4 phases:\r |
| 1046 | \r |
| 1047 | t1 t1\r |
| 1048 | t2/tlate t2/t2 extended into t3\r |
| 1049 | t3/tlate t3\r |
| 1050 | t4 t4\r |
| 1051 | \r |
| 1052 | A '1.5 cycle' instruction takes 6 phases:\r |
| 1053 | \r |
| 1054 | t1 t1\r |
| 1055 | t2/tlate t2/t2 extended into t3\r |
| 1056 | t3/tlate t3\r |
| 1057 | t2/tlate 'special' t2/t2 extended into t3\r |
| 1058 | t3/tlate t3\r |
| 1059 | t4 t4\r |
| 1060 | \r |
| 1061 | The key signals, by phase, are the following\r |
| 1062 | \r |
| 1063 | tlate EASTL enable A to sum leg 1 (else 0)\r |
| 1064 | (((m12+m16)x!azzzz)+(m9+m11+azzzz)\r |
| 1065 | EASBM enable 0 to sum leg 2 (else 177777)\r |
| 1066 | (m9+m11+azzzz)\r |
| 1067 | JAMKN jam carry network to 0 = force XOR\r |
| 1068 | ((m12+m16)x!azzzz)\r |
| 1069 | EIKI7 force carry into adder\r |
| 1070 | ((m15x(C+!m13))x!JAMKN)\r |
| 1071 | \r |
| 1072 | t3 CLDTR set D to 177777 (always)\r |
| 1073 | ESDTS enable adder sum to D (always)\r |
| 1074 | SETAZ enable repeat cycle = set azzzz\r |
| 1075 | (m8xm15)\r |
| 1076 | \r |
| 1077 | if azzzz {\r |
| 1078 | t2 CLATR clear A register (due to azzzz)\r |
| 1079 | EDAHS enable D high to A high register (due to azzzz)\r |
| 1080 | EDALS enable D low to A low register (due to azzzz)\r |
| 1081 | \r |
| 1082 | tlate, t3 as above\r |
| 1083 | }\r |
| 1084 | \r |
| 1085 | t4 CLATR clear A register\r |
| 1086 | (m11+m15+m16)\r |
| 1087 | CLA1R clear A1 register\r |
| 1088 | (m10+m14)\r |
| 1089 | EDAHS enable D high to A high register\r |
| 1090 | ((m11xm14)+m15+m16)\r |
| 1091 | EDALS enable D low to A low register\r |
| 1092 | ((m11xm13)+m15+m16)\r |
| 1093 | ETAHS enable D transposed to A high register\r |
| 1094 | (m9xm11)\r |
| 1095 | ETALS enable D transposed to A low register\r |
| 1096 | (m10xm11)\r |
| 1097 | EDA1R enable D1 to A1 register\r |
| 1098 | ((m8xm10)+m14)\r |
| 1099 | CBITL clear C, conditionally set C from adder output\r |
| 1100 | (m9x!m11)\r |
| 1101 | CBITG conditionally set C if D1\r |
| 1102 | (m10xm12xD1)\r |
| 1103 | CBITE unconditionally set C\r |
| 1104 | (m8xm9)\r |
| 1105 | */\r |
| 1106 | \r |
| 1107 | int32 Operate (int32 MB, int32 AR)\r |
| 1108 | {\r |
| 1109 | int32 D, jamkn, eiki7, easbm, eastl, setaz;\r |
| 1110 | int32 clatr, cla1r, edahs, edals, etahs, etals, eda1r;\r |
| 1111 | int32 cbitl, cbitg, cbite;\r |
| 1112 | int32 aleg, bleg, ARx;\r |
| 1113 | \r |
| 1114 | /* Phase tlate */\r |
| 1115 | \r |
| 1116 | ARx = AR; /* default */\r |
| 1117 | jamkn = (MB & (m12+m16)) != 0; /* m12+m16 */\r |
| 1118 | easbm = (MB & (m9+m11)) != 0; /* m9+m11 */\r |
| 1119 | eastl = jamkn || easbm; /* m9+m11+m12+m16 */\r |
| 1120 | setaz = (MB & (m8+m15)) == (m8+m15); /* m8xm15*/\r |
| 1121 | eiki7 = (MB & m15) && (C || !(MB & m13)); /* cin */\r |
| 1122 | aleg = eastl? AR: 0; /* a input */\r |
| 1123 | bleg = easbm? 0: DMASK; /* b input */\r |
| 1124 | if (jamkn) D = aleg ^ bleg; /* jammin? xor */\r |
| 1125 | else D = (aleg + bleg + eiki7) & DMASK; /* else add */\r |
| 1126 | \r |
| 1127 | /* Possible repeat at end of tlate - special t2, repeat tlate */\r |
| 1128 | \r |
| 1129 | if (setaz) {\r |
| 1130 | ARx = D; /* forced: t2 */\r |
| 1131 | aleg = ARx; /* forced: tlate */\r |
| 1132 | bleg = 0; /* forced */\r |
| 1133 | jamkn = 0; /* forced */\r |
| 1134 | D = (aleg + bleg + eiki7) & DMASK; /* forced add */\r |
| 1135 | sc = 0; /* ends repeat */\r |
| 1136 | }\r |
| 1137 | \r |
| 1138 | /* Phase t4 */\r |
| 1139 | \r |
| 1140 | clatr = (MB & (m11+m15+m16)) != 0; /* m11+m15+m16 */\r |
| 1141 | cla1r = (MB & (m10+m14)) != 0; /* m10+m14 */\r |
| 1142 | edahs = ((MB & (m11+m14)) == (m11+m14)) || /* (m11xm14)+m15+m16 */\r |
| 1143 | (MB & (m15+m16));\r |
| 1144 | edals = ((MB & (m11+m13)) == (m11+m13)) || /* (m11xm13)+m15+m16 */\r |
| 1145 | (MB & (m15+m16));\r |
| 1146 | etahs = (MB & (m9+m11)) == (m9+m11); /* m9xm11 */\r |
| 1147 | etals = (MB & (m10+m11)) == (m10+m11); /* m10xm11 */\r |
| 1148 | eda1r = ((MB & (m8+m10)) == (m8+m10)) || (MB & m14); /* (m8xm10)+m14 */\r |
| 1149 | cbitl = (MB & (m9+m11)) == m9; /* m9x!m11 */\r |
| 1150 | cbite = (MB & (m8+m9)) == (m8+m9); /* m8xm9 */\r |
| 1151 | cbitg = (MB & (m10+m12)) == (m10+m12); /* m10xm12 */\r |
| 1152 | \r |
| 1153 | if (clatr) ARx = 0; /* clear A */\r |
| 1154 | if (cla1r) ARx = ARx & ~SIGN; /* clear A1 */\r |
| 1155 | if (edahs) ARx = ARx | (D & 0177400); /* D hi to A hi */\r |
| 1156 | if (edals) ARx = ARx | (D & 0000377); /* D lo to A lo */\r |
| 1157 | if (etahs) ARx = ARx | ((D << 8) & 0177400); /* D lo to A hi */\r |
| 1158 | if (etals) ARx = ARx | ((D >> 8) & 0000377); /* D hi to A lo */\r |
| 1159 | if (eda1r) ARx = ARx | (D & SIGN); /* D1 to A1 */\r |
| 1160 | if (cbitl) { /* ovflo to C */\r |
| 1161 | \r |
| 1162 | /* Overflow calculation. Cases:\r |
| 1163 | \r |
| 1164 | aleg bleg cin overflow\r |
| 1165 | \r |
| 1166 | 0 x x can't overflow\r |
| 1167 | A 0 0 can't overflow\r |
| 1168 | A -1 1 can't overflow\r |
| 1169 | A 0 1 overflow if 77777->100000\r |
| 1170 | A -1 0 overflow if 100000->77777\r |
| 1171 | */\r |
| 1172 | \r |
| 1173 | if (!jamkn &&\r |
| 1174 | ((bleg && !eiki7 && (D == 0077777)) ||\r |
| 1175 | (!bleg && eiki7 && (D == 0100000)))) C = 1;\r |
| 1176 | else C = 0;\r |
| 1177 | }\r |
| 1178 | if (cbite || (cbitg && (D & SIGN))) C = 1; /* C = 1 */\r |
| 1179 | return ARx;\r |
| 1180 | }\r |
| 1181 | \r |
| 1182 | /* Reset routines */\r |
| 1183 | \r |
| 1184 | t_stat cpu_reset (DEVICE *dptr)\r |
| 1185 | {\r |
| 1186 | int32 i;\r |
| 1187 | \r |
| 1188 | saved_AR = saved_BR = saved_XR = 0;\r |
| 1189 | C = 0;\r |
| 1190 | dp = 0;\r |
| 1191 | ext = pme = extoff_pending = 0;\r |
| 1192 | dev_int = dev_int & ~(INT_PEND|INT_NMI);\r |
| 1193 | dev_enb = 0;\r |
| 1194 | for (i = 0; i < DMA_MAX; i++) dma_ad[i] = dma_wc[i] = dma_eor[i] = 0;\r |
| 1195 | chan_req = 0;\r |
| 1196 | pcq_r = find_reg ("PCQ", NULL, dptr);\r |
| 1197 | if (pcq_r) pcq_r->qptr = 0;\r |
| 1198 | else return SCPE_IERR;\r |
| 1199 | sim_brk_types = sim_brk_dflt = SWMASK ('E');\r |
| 1200 | return SCPE_OK;\r |
| 1201 | }\r |
| 1202 | \r |
| 1203 | /* Memory examine */\r |
| 1204 | \r |
| 1205 | t_stat cpu_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw)\r |
| 1206 | {\r |
| 1207 | int32 d;\r |
| 1208 | \r |
| 1209 | if (addr >= MEMSIZE) return SCPE_NXM;\r |
| 1210 | if (addr == 0) d = saved_XR;\r |
| 1211 | else d = M[addr];\r |
| 1212 | if (vptr != NULL) *vptr = d & DMASK;\r |
| 1213 | return SCPE_OK;\r |
| 1214 | }\r |
| 1215 | \r |
| 1216 | /* Memory deposit */\r |
| 1217 | \r |
| 1218 | t_stat cpu_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw)\r |
| 1219 | {\r |
| 1220 | if (addr >= MEMSIZE) return SCPE_NXM;\r |
| 1221 | if (addr == 0) saved_XR = val & DMASK;\r |
| 1222 | else M[addr] = val & DMASK;\r |
| 1223 | return SCPE_OK;\r |
| 1224 | }\r |
| 1225 | \r |
| 1226 | /* Option processors */\r |
| 1227 | \r |
| 1228 | t_stat cpu_set_noext (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1229 | {\r |
| 1230 | if (MEMSIZE > (NX_AMASK + 1)) return SCPE_ARG;\r |
| 1231 | return SCPE_OK;\r |
| 1232 | }\r |
| 1233 | \r |
| 1234 | t_stat cpu_set_size (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1235 | {\r |
| 1236 | int32 mc = 0;\r |
| 1237 | uint32 i;\r |
| 1238 | \r |
| 1239 | if ((val <= 0) || (val > MAXMEMSIZE) || ((val & 07777) != 0) ||\r |
| 1240 | (((cpu_unit.flags & UNIT_EXT) == 0) && (val > (NX_AMASK + 1))))\r |
| 1241 | return SCPE_ARG;\r |
| 1242 | for (i = val; i < MEMSIZE; i++) mc = mc | M[i];\r |
| 1243 | if ((mc != 0) && (!get_yn ("Really truncate memory [N]?", FALSE)))\r |
| 1244 | return SCPE_OK;\r |
| 1245 | MEMSIZE = val;\r |
| 1246 | for (i = MEMSIZE; i < MAXMEMSIZE; i++) M[i] = 0;\r |
| 1247 | return SCPE_OK;\r |
| 1248 | }\r |
| 1249 | \r |
| 1250 | t_stat cpu_set_nchan (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1251 | {\r |
| 1252 | uint32 i, newmax;\r |
| 1253 | t_stat r;\r |
| 1254 | \r |
| 1255 | if (cptr == NULL) return SCPE_ARG;\r |
| 1256 | newmax = get_uint (cptr, 10, DMA_MAX, &r); /* get new max */\r |
| 1257 | if ((r != SCPE_OK) || (newmax == dma_nch)) return r; /* err or no chg? */\r |
| 1258 | dma_nch = newmax; /* set new max */\r |
| 1259 | for (i = newmax; i < DMA_MAX; i++) { /* reset chan */\r |
| 1260 | dma_ad[i] = dma_wc[i] = dma_eor[i] = 0;\r |
| 1261 | chan_req = chan_req & ~(1 << i);\r |
| 1262 | }\r |
| 1263 | return SCPE_OK;\r |
| 1264 | }\r |
| 1265 | \r |
| 1266 | /* Show DMA channels */\r |
| 1267 | \r |
| 1268 | t_stat cpu_show_nchan (FILE *st, UNIT *uptr, int32 val, void *desc)\r |
| 1269 | {\r |
| 1270 | if (dma_nch) fprintf (st, "DMA channels = %d", dma_nch);\r |
| 1271 | else fprintf (st, "no DMA channels");\r |
| 1272 | return SCPE_OK;\r |
| 1273 | }\r |
| 1274 | \r |
| 1275 | /* Show channel state */\r |
| 1276 | \r |
| 1277 | t_stat cpu_show_dma (FILE *st, UNIT *uptr, int32 val, void *desc)\r |
| 1278 | {\r |
| 1279 | if ((val < 0) || (val >= DMA_MAX)) return SCPE_IERR;\r |
| 1280 | fputs ((dma_ad[val] & DMA_IN)? "Input": "Output", st);\r |
| 1281 | fprintf (st, ", addr = %06o, count = %06o, ", dma_ad[val] & X_AMASK, dma_wc[val]);\r |
| 1282 | fprintf (st, "end of range %s\n", (dma_eor[val]? "set": "clear"));\r |
| 1283 | return SCPE_OK;\r |
| 1284 | }\r |
| 1285 | \r |
| 1286 | /* Set I/O device to IOBUS / DMA channel / DMC channel */\r |
| 1287 | \r |
| 1288 | t_stat io_set_iobus (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1289 | {\r |
| 1290 | DEVICE *dptr;\r |
| 1291 | DIB *dibp;\r |
| 1292 | \r |
| 1293 | if (val || cptr || (uptr == NULL)) return SCPE_IERR;\r |
| 1294 | dptr = find_dev_from_unit (uptr);\r |
| 1295 | if (dptr == NULL) return SCPE_IERR;\r |
| 1296 | dibp = (DIB *) dptr->ctxt;\r |
| 1297 | if (dibp == NULL) return SCPE_IERR;\r |
| 1298 | dibp->chan = 0;\r |
| 1299 | return SCPE_OK;\r |
| 1300 | }\r |
| 1301 | \r |
| 1302 | t_stat io_set_dma (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1303 | {\r |
| 1304 | DEVICE *dptr;\r |
| 1305 | DIB *dibp;\r |
| 1306 | uint32 newc;\r |
| 1307 | t_stat r;\r |
| 1308 | \r |
| 1309 | if ((cptr == NULL) || (uptr == NULL)) return SCPE_IERR;\r |
| 1310 | dptr = find_dev_from_unit (uptr);\r |
| 1311 | if (dptr == NULL) return SCPE_IERR;\r |
| 1312 | dibp = (DIB *) dptr->ctxt;\r |
| 1313 | if (dibp == NULL) return SCPE_IERR;\r |
| 1314 | if (dma_nch == 0) return SCPE_NOFNC;\r |
| 1315 | newc = get_uint (cptr, 10, DMA_MAX, &r); /* get new */\r |
| 1316 | if ((r != SCPE_OK) || (newc == 0) || (newc > dma_nch)) return SCPE_ARG;\r |
| 1317 | dibp->chan = (newc - DMA_MIN) + DMA_V_DMA1 + 1; /* store */\r |
| 1318 | return SCPE_OK;\r |
| 1319 | }\r |
| 1320 | \r |
| 1321 | t_stat io_set_dmc (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1322 | {\r |
| 1323 | DEVICE *dptr;\r |
| 1324 | DIB *dibp;\r |
| 1325 | uint32 newc;\r |
| 1326 | t_stat r;\r |
| 1327 | \r |
| 1328 | if ((cptr == NULL) || (uptr == NULL)) return SCPE_IERR;\r |
| 1329 | dptr = find_dev_from_unit (uptr);\r |
| 1330 | if (dptr == NULL) return SCPE_IERR;\r |
| 1331 | dibp = (DIB *) dptr->ctxt;\r |
| 1332 | if (dibp == NULL) return SCPE_IERR;\r |
| 1333 | if (!(cpu_unit.flags & UNIT_DMC)) return SCPE_NOFNC;\r |
| 1334 | newc = get_uint (cptr, 10, DMC_MAX, &r); /* get new */\r |
| 1335 | if ((r != SCPE_OK) || (newc == 0)) return SCPE_ARG;\r |
| 1336 | dibp->chan = (newc - DMC_MIN) + DMC_V_DMC1 + 1; /* store */\r |
| 1337 | return SCPE_OK;\r |
| 1338 | }\r |
| 1339 | \r |
| 1340 | /* Show channel configuration */\r |
| 1341 | \r |
| 1342 | t_stat io_show_chan (FILE *st, UNIT *uptr, int32 val, void *desc)\r |
| 1343 | {\r |
| 1344 | DEVICE *dptr;\r |
| 1345 | DIB *dibp;\r |
| 1346 | \r |
| 1347 | if (uptr == NULL) return SCPE_IERR;\r |
| 1348 | dptr = find_dev_from_unit (uptr);\r |
| 1349 | if (dptr == NULL) return SCPE_IERR;\r |
| 1350 | dibp = (DIB *) dptr->ctxt;\r |
| 1351 | if (dibp == NULL) return SCPE_IERR;\r |
| 1352 | if (dibp->chan == 0) fprintf (st, "IO bus");\r |
| 1353 | else if (dibp->chan < (DMC_V_DMC1 + 1))\r |
| 1354 | fprintf (st, "DMA channel %d", dibp->chan);\r |
| 1355 | else fprintf (st, "DMC channel %d", dibp->chan - DMC_V_DMC1);\r |
| 1356 | return SCPE_OK;\r |
| 1357 | }\r |
| 1358 | \r |
| 1359 | /* Set up I/O dispatch and channel maps */\r |
| 1360 | \r |
| 1361 | t_bool devtab_init (void)\r |
| 1362 | {\r |
| 1363 | DEVICE *dptr;\r |
| 1364 | DIB *dibp;\r |
| 1365 | uint32 i, j, dno, chan;\r |
| 1366 | \r |
| 1367 | for (i = 0; i < DEV_MAX; i++) iotab[i] = NULL;\r |
| 1368 | for (i = 0; i < (DMA_MAX + DMC_MAX); i++) chan_map[i] = 0;\r |
| 1369 | for (i = 0; dptr = sim_devices[i]; i++) { /* loop thru devices */\r |
| 1370 | dibp = (DIB *) dptr->ctxt; /* get DIB */\r |
| 1371 | if ((dibp == NULL) || (dptr->flags & DEV_DIS)) continue; /* exist, enabled? */\r |
| 1372 | dno = dibp->dev; /* device number */\r |
| 1373 | for (j = 0; j < dibp->num; j++) { /* repeat for slots */\r |
| 1374 | if (iotab[dno + j]) { /* conflict? */\r |
| 1375 | printf ("%s device number conflict, devno = %02o\n",\r |
| 1376 | sim_dname (dptr), dno + j);\r |
| 1377 | if (sim_log) fprintf (sim_log,\r |
| 1378 | "%s device number conflict, devno = %02o\n",\r |
| 1379 | sim_dname (dptr), dno + j);\r |
| 1380 | return TRUE;\r |
| 1381 | }\r |
| 1382 | iotab[dno + j] = dibp->io; /* set I/O routine */\r |
| 1383 | } /* end for */\r |
| 1384 | if (dibp->chan) { /* DMA/DMC? */\r |
| 1385 | chan = dibp->chan - 1;\r |
| 1386 | if ((chan < DMC_V_DMC1) && (chan >= dma_nch)) {\r |
| 1387 | printf ("%s configured for DMA channel %d\n",\r |
| 1388 | sim_dname (dptr), chan + 1);\r |
| 1389 | if (sim_log) fprintf (sim_log,\r |
| 1390 | "%s configured for DMA channel %d\n",\r |
| 1391 | sim_dname (dptr), chan + 1);\r |
| 1392 | return TRUE;\r |
| 1393 | }\r |
| 1394 | if ((chan >= DMC_V_DMC1) && !(cpu_unit.flags & UNIT_DMC)) {\r |
| 1395 | printf ("%s configured for DMC, option disabled\n",\r |
| 1396 | sim_dname (dptr));\r |
| 1397 | if (sim_log) fprintf (sim_log, \r |
| 1398 | "%s configured for DMC, option disabled\n",\r |
| 1399 | sim_dname (dptr));\r |
| 1400 | return TRUE;\r |
| 1401 | }\r |
| 1402 | if (chan_map[chan]) { /* channel conflict? */\r |
| 1403 | printf ("%s DMA/DMC channel conflict, devno = %02o\n",\r |
| 1404 | sim_dname (dptr), dno);\r |
| 1405 | if (sim_log) fprintf (sim_log,\r |
| 1406 | "%s DMA/DMC channel conflict, devno = %02o\n",\r |
| 1407 | sim_dname (dptr), dno);\r |
| 1408 | return TRUE;\r |
| 1409 | }\r |
| 1410 | chan_map[chan] = dno; /* channel back map */\r |
| 1411 | }\r |
| 1412 | } /* end for */\r |
| 1413 | for (i = 0; i < DEV_MAX; i++) { /* fill in blanks */\r |
| 1414 | if (iotab[i] == NULL) iotab[i] = &undio;\r |
| 1415 | }\r |
| 1416 | return FALSE;\r |
| 1417 | }\r |
| 1418 | \r |
| 1419 | /* Set history */\r |
| 1420 | \r |
| 1421 | t_stat cpu_set_hist (UNIT *uptr, int32 val, char *cptr, void *desc)\r |
| 1422 | {\r |
| 1423 | int32 i, lnt;\r |
| 1424 | t_stat r;\r |
| 1425 | \r |
| 1426 | if (cptr == NULL) {\r |
| 1427 | for (i = 0; i < hst_lnt; i++) hst[i].pc = 0;\r |
| 1428 | hst_p = 0;\r |
| 1429 | return SCPE_OK;\r |
| 1430 | }\r |
| 1431 | lnt = (int32) get_uint (cptr, 10, HIST_MAX, &r);\r |
| 1432 | if ((r != SCPE_OK) || (lnt && (lnt < HIST_MIN))) return SCPE_ARG;\r |
| 1433 | hst_p = 0;\r |
| 1434 | if (hst_lnt) {\r |
| 1435 | free (hst);\r |
| 1436 | hst_lnt = 0;\r |
| 1437 | hst = NULL;\r |
| 1438 | }\r |
| 1439 | if (lnt) {\r |
| 1440 | hst = (InstHistory *) calloc (lnt, sizeof (InstHistory));\r |
| 1441 | if (hst == NULL) return SCPE_MEM;\r |
| 1442 | hst_lnt = lnt;\r |
| 1443 | }\r |
| 1444 | return SCPE_OK;\r |
| 1445 | }\r |
| 1446 | \r |
| 1447 | /* Show history */\r |
| 1448 | \r |
| 1449 | t_stat cpu_show_hist (FILE *st, UNIT *uptr, int32 val, void *desc)\r |
| 1450 | {\r |
| 1451 | int32 cr, k, di, op, lnt;\r |
| 1452 | char *cptr = (char *) desc;\r |
| 1453 | t_value sim_eval;\r |
| 1454 | t_stat r;\r |
| 1455 | InstHistory *h;\r |
| 1456 | extern t_stat fprint_sym (FILE *ofile, t_addr addr, t_value *val,\r |
| 1457 | UNIT *uptr, int32 sw);\r |
| 1458 | static uint8 has_opnd[16] = {\r |
| 1459 | 0, 0, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1\r |
| 1460 | };\r |
| 1461 | \r |
| 1462 | if (hst_lnt == 0) return SCPE_NOFNC; /* enabled? */\r |
| 1463 | if (cptr) {\r |
| 1464 | lnt = (int32) get_uint (cptr, 10, hst_lnt, &r);\r |
| 1465 | if ((r != SCPE_OK) || (lnt == 0)) return SCPE_ARG;\r |
| 1466 | }\r |
| 1467 | else lnt = hst_lnt;\r |
| 1468 | di = hst_p - lnt; /* work forward */\r |
| 1469 | if (di < 0) di = di + hst_lnt;\r |
| 1470 | fprintf (st, "PC C A B X ea IR\n\n");\r |
| 1471 | for (k = 0; k < lnt; k++) { /* print specified */\r |
| 1472 | h = &hst[(++di) % hst_lnt]; /* entry pointer */\r |
| 1473 | if (h->pc & HIST_PC) { /* instruction? */\r |
| 1474 | cr = (h->pc & HIST_C)? 1: 0; /* carry */\r |
| 1475 | fprintf (st, "%05o %o %06o %06o %06o ",\r |
| 1476 | h->pc & X_AMASK, cr, h->ar, h->br, h->xr);\r |
| 1477 | if (h->pc & HIST_EA) fprintf (st, "%05o ", h->ea);\r |
| 1478 | else fprintf (st, " ");\r |
| 1479 | sim_eval = h->ir;\r |
| 1480 | if ((fprint_sym (st, h->pc & X_AMASK, &sim_eval,\r |
| 1481 | &cpu_unit, SWMASK ('M'))) > 0)\r |
| 1482 | fprintf (st, "(undefined) %06o", h->ir);\r |
| 1483 | op = I_GETOP (h->ir) & 017; /* base op */\r |
| 1484 | if (has_opnd[op]) fprintf (st, " [%06o]", h->opnd);\r |
| 1485 | fputc ('\n', st); /* end line */\r |
| 1486 | } /* end else instruction */\r |
| 1487 | } /* end for */\r |
| 1488 | return SCPE_OK;\r |
| 1489 | }\r |