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simh-testsetgenerator/scp.c
Bob Supnik 4ffd3be790 Notes For V3.0-0 
Because some key files have changed, V3.0 should be unzipped to a
clean directory.

1. New Features in 3.0-0

1.1 SCP and Libraries

- Added ASSIGN/DEASSIGN (logical name) commands.
- Changed RESTORE to unconditionally detach files.
- Added E11 and TPC format support to magtape library.
- Fixed bug in SHOW CONNECTIONS.
- Added USE_ADDR64 support

1.2 All magtapes

- Magtapes support SIMH format, E11 format, and TPC format (read only).
- SET <tape_unit> FORMAT=format sets the specified tape unit's format.
- SHOW <tape_unit> FORMAT displays the specified tape unit's format.
- Tape format can also be set as part of the ATTACH command, using
  the -F switch.

1.3 VAX

- VAX can be compiled without USE_INT64.
- If compiled with USE_INT64 and USE_ADDR64, RQ and TQ controllers support
  files > 2GB.
- VAX ROM has speed control (SET ROM DELAY/NODELAY).

2. Bugs Fixed in 3.01-0

2.1 VAX

- Fixed CVTfi bug: integer overflow not set if exponent out of range
- Fixed EMODx bugs:
  o First and second operands reversed
  o Separated fraction received wrong exponent
  o Overflow calculation on separated integer incorrect
  o Fraction not set to zero if exponent out of range
- Fixed interval timer and ROM access to pass power-up self-test even on very
  fast host processors (fixes from Mark Pizzolato).

2.2 1401

- Fixed mnemonic, instruction lengths, and reverse scan length check bug for MCS.
- Fixed MCE bug, BS off by 1 if zero suppress.
- Fixed chaining bug, D lost if return to SCP.
- Fixed H branch, branch occurs after continue.
- Added check for invalid 8 character MCW, LCA.
- Fixed magtape load-mode end of record response.

2.3 Nova

- Fixed DSK variable size interaction with restore.

2.4 PDP-1

- Fixed DT variable size interaction with restore.

2.5 PDP-11

- Fixed DT variable size interaction with restore.
- Fixed bug in MMR1 update (found by Tim Stark).
- Added XQ features and fixed bugs:
  o Corrected XQ interrupts on IE state transition (code by Tom Evans).
  o Added XQ interrupt clear on soft reset.
  o Removed XQ interrupt when setting XL or RL (multiple people).
  o Added SET/SHOW XQ STATS.
  o Added SHOW XQ FILTERS.
  o Added ability to split received packet into multiple buffers.
  o Added explicit runt and giant packet processing.

2.6 PDP-18B

- Fixed DT, RF variable size interaction with restore.
- Fixed MT bug in MTTR.

2.7 PDP-8

- Fixed DT, DF, RF, RX variable size interaction with restore.
- Fixed MT bug in SKTR.

2.8 HP2100

- Fixed bug in DP (13210A controller only), DQ read status.
- Fixed bug in DP, DQ seek complete.

2.9 GRI

- Fixed bug in SC queue pointer management.

3. New Features in 3.0 vs prior releases

N/A

4. Bugs Fixed in 3.0 vs prior releases

N/A

5. General Notes

WARNING: The RESTORE command has changed.  RESTORE will now
detach an attached file on a unit, if that unit did not have
an attached file in the saved configuration.  This is required
to assure that the unit flags and the file state are consistent.

WARNING: The compilation scheme for the PDP-10, PDP-11, and VAX
has changed.  Use one of the supplied build files, or read the
documentation carefully, before compiling any of these simulators.
2011-04-15 08:34:08 -07:00

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/* scp.c: simulator control program
Copyright (c) 1993-2003, 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.
15-Jun-03 RMS Added register flag REG_VMIO
25-Apr-03 RMS Added extended address support (V3.0)
Fixed bug in SAVE (found by Peter Schorn)
Added u5, u6 fields
Added logical name support
03-Mar-03 RMS Added sim_fsize
27-Feb-03 RMS Fixed bug in multiword deposits to files
08-Feb-03 RMS Changed sim_os_sleep to void, match_ext to char*
Added multiple actions, .ini file support
Added multiple switch evaluations per line
07-Feb-03 RMS Added VMS support for ! (from Mark Pizzolato)
01-Feb-03 RMS Added breakpoint table extension, actions
14-Jan-03 RMS Added missing function prototypes
10-Jan-03 RMS Added attach/restore flag, dynamic memory size support,
case sensitive SET options
22-Dec-02 RMS Added ! (OS command) feature (from Mark Pizzolato)
17-Dec-02 RMS Added get_ipaddr
02-Dec-02 RMS Added EValuate command
16-Nov-02 RMS Fixed bug in register name match algorithm
13-Oct-02 RMS Fixed Borland compiler warnings (found by Hans Pufal)
05-Oct-02 RMS Fixed bugs in set_logon, ssh_break (found by David Hittner)
Added support for fixed buffer devices
Added support for Telnet console, removed VT support
Added help <command>
Added VMS file optimizations (from Robert Alan Byer)
Added quiet mode, DO with parameters, GUI interface,
extensible commands (from Brian Knittel)
Added device enable/disable commands
14-Jul-02 RMS Fixed exit bug in do, added -v switch (from Brian Knittel)
17-May-02 RMS Fixed bug in fxread/fxwrite error usage (found by
Norm Lastovic)
02-May-02 RMS Added VT emulation interface, changed {NO}LOG to SET {NO}LOG
22-Apr-02 RMS Fixed laptop sleep problem in clock calibration, added
magtape record length error (found by Jonathan Engdahl)
26-Feb-02 RMS Fixed initialization bugs in do_cmd, get_avail
(found by Brian Knittel)
10-Feb-02 RMS Fixed problem in clock calibration
06-Jan-02 RMS Moved device enable/disable to simulators
30-Dec-01 RMS Generalized timer packaged, added circular arrays
19-Dec-01 RMS Fixed DO command bug (found by John Dundas)
07-Dec-01 RMS Implemented breakpoint package
05-Dec-01 RMS Fixed bug in universal register logic
03-Dec-01 RMS Added read-only units, extended SET/SHOW, universal registers
24-Nov-01 RMS Added unit-based registers
16-Nov-01 RMS Added DO command
28-Oct-01 RMS Added relative range addressing
08-Oct-01 RMS Added SHOW VERSION
30-Sep-01 RMS Relaxed attach test in BOOT
27-Sep-01 RMS Added queue count routine, fixed typo in ex/mod
17-Sep-01 RMS Removed multiple console support
07-Sep-01 RMS Removed conditional externs on function prototypes
Added special modifier print
31-Aug-01 RMS Changed int64 to t_int64 for Windoze (V2.7)
18-Jul-01 RMS Minor changes for Macintosh port
12-Jun-01 RMS Fixed bug in big-endian I/O (found by Dave Conroy)
27-May-01 RMS Added multiple console support
16-May-01 RMS Added logging
15-May-01 RMS Added features from Tim Litt
12-May-01 RMS Fixed missing return in disable_cmd
25-Mar-01 RMS Added ENABLE/DISABLE
14-Mar-01 RMS Revised LOAD/DUMP interface (again)
05-Mar-01 RMS Added clock calibration support
05-Feb-01 RMS Fixed bug, DETACH buffered unit with hwmark = 0
04-Feb-01 RMS Fixed bug, RESTORE not using device's attach routine
21-Jan-01 RMS Added relative time
22-Dec-00 RMS Fixed find_device for devices ending in numbers
08-Dec-00 RMS V2.5a changes
30-Oct-00 RMS Added output file option to examine
11-Jul-99 RMS V2.5 changes
13-Apr-99 RMS Fixed handling of 32b addresses
04-Oct-98 RMS V2.4 changes
20-Aug-98 RMS Added radix commands
05-Jun-98 RMS Fixed bug in ^D handling for UNIX
10-Apr-98 RMS Added switches to all commands
26-Oct-97 RMS Added search capability
25-Jan-97 RMS Revised data types
23-Jan-97 RMS Added bi-endian I/O
06-Sep-96 RMS Fixed bug in variable length IEXAMINE
16-Jun-96 RMS Changed interface to parse/print_sym
06-Apr-96 RMS Added error checking in reset all
07-Jan-96 RMS Added register buffers in save/restore
11-Dec-95 RMS Fixed ordering bug in save/restore
22-May-95 RMS Added symbolic input
13-Apr-95 RMS Added symbolic printouts
*/
/* Macros and data structures */
#include "sim_defs.h"
#include "sim_rev.h"
#include "sim_sock.h"
#include "sim_tmxr.h"
#include <signal.h>
#include <ctype.h>
#define EX_D 0 /* deposit */
#define EX_E 1 /* examine */
#define EX_I 2 /* interactive */
#define SCH_OR 0 /* search logicals */
#define SCH_AND 1
#define SCH_XOR 2
#define SCH_E 0 /* search booleans */
#define SCH_N 1
#define SCH_G 2
#define SCH_L 3
#define SCH_EE 4
#define SCH_NE 5
#define SCH_GE 6
#define SCH_LE 7
#define SSH_ST 0 /* set */
#define SSH_SH 1 /* show */
#define SSH_CL 2 /* clear */
#define RU_RUN 0 /* run */
#define RU_GO 1 /* go */
#define RU_STEP 2 /* step */
#define RU_CONT 3 /* continue */
#define RU_BOOT 4 /* boot */
#define SRBSIZ 1024 /* save/restore buffer */
#define SIM_BRK_INILNT 4096 /* bpt tbl length */
#define SIM_BRK_ALLTYP 0xFFFFFFFF
#define SIM_NTIMERS 8 /* # timers */
#define SIM_TMAX 500 /* max timer makeup */
#define UPDATE_SIM_TIME(x) sim_time = sim_time + (x - sim_interval); \
sim_rtime = sim_rtime + ((uint32) (x - sim_interval)); \
x = sim_interval
#define print_val(a,b,c,d) fprint_val (stdout, (a), (b), (c), (d))
#define SZ_D(dp) (size_map[((dp)->dwidth + CHAR_BIT - 1) / CHAR_BIT])
#define SZ_R(rp) \
(size_map[((rp)->width + (rp)->offset + CHAR_BIT - 1) / CHAR_BIT])
#if defined (t_int64)
#define SZ_LOAD(sz,v,mb,j) \
if (sz == sizeof (uint8)) v = *(((uint8 *) mb) + ((uint32) j)); \
else if (sz == sizeof (uint16)) v = *(((uint16 *) mb) + ((uint32) j)); \
else if (sz == sizeof (uint32)) v = *(((uint32 *) mb) + ((uint32) j)); \
else v = *(((t_uint64 *) mb) + ((uint32) j));
#define SZ_STORE(sz,v,mb,j) \
if (sz == sizeof (uint8)) *(((uint8 *) mb) + j) = (uint8) v; \
else if (sz == sizeof (uint16)) *(((uint16 *) mb) + ((uint32) j)) = (uint16) v; \
else if (sz == sizeof (uint32)) *(((uint32 *) mb) + ((uint32) j)) = (uint32) v; \
else *(((t_uint64 *) mb) + ((uint32) j)) = v;
#else
#define SZ_LOAD(sz,v,mb,j) \
if (sz == sizeof (uint8)) v = *(((uint8 *) mb) + ((uint32) j)); \
else if (sz == sizeof (uint16)) v = *(((uint16 *) mb) + ((uint32) j)); \
else v = *(((uint32 *) mb) + ((uint32) j));
#define SZ_STORE(sz,v,mb,j) \
if (sz == sizeof (uint8)) *(((uint8 *) mb) + ((uint32) j)) = (uint8) v; \
else if (sz == sizeof (uint16)) *(((uint16 *) mb) + ((uint32) j)) = (uint16) v; \
else *(((uint32 *) mb) + ((uint32) j)) = v;
#endif
#define GET_SWITCHES(cp) \
if ((cp = get_sim_sw (cp)) == NULL) return SCPE_INVSW
#define GET_RADIX(val,dft) \
if (sim_switches & SWMASK ('O')) val = 8; \
else if (sim_switches & SWMASK ('D')) val = 10; \
else if (sim_switches & SWMASK ('H')) val = 16; \
else val = dft;
#if defined(VMS)
#define FOPEN(file_spec, mode) fopen (file_spec, mode, "ALQ=32", "DEQ=4096", \
"MBF=6", "MBC=127", "FOP=cbt,tef", "ROP=rah,wbh", "CTX=stm")
#else
#define FOPEN(file_spec, mode) fopen (file_spec, mode)
#endif
/* VM interface */
extern char sim_name[];
extern DEVICE *sim_devices[];
extern REG *sim_PC;
extern char *sim_stop_messages[];
extern t_stat sim_instr (void);
extern t_stat sim_load (FILE *ptr, char *cptr, char *fnam, int32 flag);
extern int32 sim_emax;
extern t_stat fprint_sym (FILE *ofile, t_addr addr, t_value *val,
UNIT *uptr, int32 sw);
extern t_stat parse_sym (char *cptr, t_addr addr, UNIT *uptr, t_value *val,
int32 sw);
/* The per-simulator init routine is a weak global that defaults to NULL
The other per-simulator pointers can be overrriden by the init routine */
void (*sim_vm_init) (void);
char* (*sim_vm_read) (char *ptr, int32 size, FILE *stream) = NULL;
void (*sim_vm_post) (t_bool from_scp) = NULL;
CTAB *sim_vm_cmd = NULL;
/* External routines */
extern t_stat ttinit (void);
extern t_stat ttrunstate (void);
extern t_stat ttcmdstate (void);
extern t_stat ttclose (void);
extern t_stat sim_os_poll_kbd (void);
extern t_stat sim_os_putchar (int32 out);
extern uint32 sim_os_msec (void);
/* Prototypes */
/* Command processors */
t_stat reset_cmd (int32 flag, char *ptr);
t_stat exdep_cmd (int32 flag, char *ptr);
t_stat eval_cmd (int32 flag, char *ptr);
t_stat load_cmd (int32 flag, char *ptr);
t_stat run_cmd (int32 flag, char *ptr);
t_stat attach_cmd (int32 flag, char *ptr);
t_stat detach_cmd (int32 flag, char *ptr);
t_stat assign_cmd (int32 flag, char *ptr);
t_stat deassign_cmd (int32 flag, char *ptr);
t_stat save_cmd (int32 flag, char *ptr);
t_stat restore_cmd (int32 flag, char *ptr);
t_stat exit_cmd (int32 flag, char *ptr);
t_stat set_cmd (int32 flag, char *ptr);
t_stat show_cmd (int32 flag, char *ptr);
t_stat brk_cmd (int32 flag, char *ptr);
t_stat do_cmd (int32 flag, char *ptr);
t_stat help_cmd (int32 flag, char *ptr);
t_stat spawn_cmd (int32 flag, char *ptr);
/* Set and show command processors */
t_stat set_telnet (int32 flg, char *cptr);
t_stat set_notelnet (int32 flg, char *cptr);
t_stat set_logon (int32 flag, char *cptr);
t_stat set_logoff (int32 flag, char *cptr);
t_stat set_radix (DEVICE *dptr, UNIT *uptr, int32 flag);
t_stat set_devenbdis (DEVICE *dptr, UNIT *uptr, int32 flag);
t_stat set_onoff (DEVICE *dptr, UNIT *uptr, int32 flag);
t_stat ssh_break (FILE *st, char *cptr, int32 flg);
t_stat show_config (FILE *st, int32 flag, char *cptr);
t_stat show_queue (FILE *st, int32 flag, char *cptr);
t_stat show_time (FILE *st, int32 flag, char *cptr);
t_stat show_mod_names (FILE *st, int32 flag, char *cptr);
t_stat show_log_names (FILE *st, int32 flag, char *cptr);
t_stat show_log (FILE *st, int32 flag, char *cptr);
t_stat show_telnet (FILE *st, int32 flag, char *cptr);
t_stat show_version (FILE *st, int32 flag, char *cptr);
t_stat show_break (FILE *st, int32 flag, char *cptr);
t_stat show_device (FILE *st, DEVICE *dptr, int32 flag);
t_stat show_unit (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag);
t_stat show_all_mods (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flg);
t_stat show_one_mod (FILE *st, DEVICE *dptr, UNIT *uptr, MTAB *mptr, int32 flag);
t_stat sim_check_console (int32 sec);
t_stat sim_save (FILE *sfile);
t_stat sim_rest (FILE *rfile);
/* Breakpoint package */
t_stat sim_brk_init (void);
t_stat sim_brk_set (t_addr loc, int32 sw, int32 ncnt, char *act);
t_stat sim_brk_clr (t_addr loc, int32 sw);
t_stat sim_brk_clrall (int32 sw);
t_stat sim_brk_show (FILE *st, t_addr loc, int32 sw);
t_stat sim_brk_showall (FILE *st, int32 sw);
char *sim_brk_getact (char *buf, int32 size);
void sim_brk_clract (void);
void sim_brk_npc (void);
BRKTAB *sim_brk_new (t_addr loc);
/* Commands support routines */
SCHTAB *get_search (char *cptr, DEVICE *dptr, SCHTAB *schptr);
int32 test_search (t_value val, SCHTAB *schptr);
char *get_glyph_gen (char *iptr, char *optr, char mchar, t_bool uc);
int32 get_switches (char *cptr);
char *get_sim_sw (char *cptr);
t_stat get_aval (t_addr addr, DEVICE *dptr, UNIT *uptr);
t_value get_rval (REG *rptr, uint32 idx);
void put_rval (REG *rptr, uint32 idx, t_value val);
t_value strtotv (char *inptr, char **endptr, uint32 radix);
void fprint_help (FILE *st);
void fprint_stopped (FILE *st, t_stat r);
void fprint_capac (FILE *st, DEVICE *dptr, UNIT *uptr);
char *read_line (char *ptr, int32 size, FILE *stream);
CTAB *find_ctab (CTAB *tab, char *gbuf);
C1TAB *find_c1tab (C1TAB *tab, char *gbuf);
CTAB *find_cmd (char *gbuf);
DEVICE *find_dev (char *ptr);
DEVICE *find_unit (char *ptr, UNIT **uptr);
REG *find_reg_glob (char *ptr, char **optr, DEVICE **gdptr);
/* Forward references within commands */
t_bool restore_skip_val (FILE *rfile);
t_bool qdisable (DEVICE *dptr);
t_stat attach_err (UNIT *uptr, t_stat stat);
t_stat detach_all (int32 start_device, t_bool shutdown);
t_stat assign_device (DEVICE *dptr, char *cptr);
t_stat deassign_device (DEVICE *dptr);
t_stat exdep_reg_loop (FILE *ofile, SCHTAB *schptr, int32 flag, char *cptr,
REG *lowr, REG *highr, uint32 lows, uint32 highs);
t_stat ex_reg (FILE *ofile, t_value val, int32 flag, REG *rptr, uint32 idx);
t_stat dep_reg (int32 flag, char *cptr, REG *rptr, uint32 idx);
t_stat exdep_addr_loop (FILE *ofile, SCHTAB *schptr, int32 flag, char *cptr,
t_addr low, t_addr high, DEVICE *dptr, UNIT *uptr);
t_stat ex_addr (FILE *ofile, int32 flag, t_addr addr, DEVICE *dptr, UNIT *uptr);
t_stat dep_addr (int32 flag, char *cptr, t_addr addr, DEVICE *dptr,
UNIT *uptr, int32 dfltinc);
t_stat step_svc (UNIT *ptr);
void sub_args (char *instr, char *tmpbuf, int32 maxstr, int32 nargs, char *do_arg[]);
/* Global data */
UNIT *sim_clock_queue = NULL;
int32 sim_interval = 0;
int32 sim_switches = 0;
int32 sim_is_running = 0;
uint32 sim_brk_summ = 0;
uint32 sim_brk_types = 0;
uint32 sim_brk_dflt = 0;
char *sim_brk_act = NULL;
BRKTAB *sim_brk_tab = NULL;
int32 sim_brk_ent = 0;
int32 sim_brk_lnt = 0;
int32 sim_brk_ins = 0;
t_bool sim_brk_pend = FALSE;
t_addr sim_brk_ploc = 0;
int32 sim_quiet = 0;
static double sim_time;
static uint32 sim_rtime;
static int32 noqueue_time;
volatile int32 stop_cpu = 0;
t_value *sim_eval = NULL;
int32 sim_end = 1; /* 1 = little */
FILE *sim_log = NULL; /* log file */
unsigned char sim_flip[FLIP_SIZE];
TMLN sim_con_ldsc = { 0 }; /* console line descr */
TMXR sim_con_tmxr = { 1, 0, 0, &sim_con_ldsc }; /* console line mux */
UNIT step_unit = { UDATA (&step_svc, 0, 0) };
/* Tables and strings */
const char save_vercur[] = "V3.0";
const char save_ver210[] = "V2.10";
const char save_ver26[] = "V2.6";
const char *scp_error_messages[] = {
"Address space exceeded",
"Unit not attached",
"I/O error",
"Checksum error",
"Format error",
"Unit not attachable",
"File open error",
"Memory exhausted",
"Invalid argument",
"Step expired",
"Unknown command",
"Read only argument",
"Command not completed",
"Simulation stopped",
"Goodbye",
"Console input I/O error",
"Console output I/O error",
"End of file",
"Relocation error",
"No settable parameters",
"Unit already attached",
"Hardware timer error",
"SIGINT handler setup error",
"Console terminal setup error",
"Subscript out of range",
"Command not allowed",
"Unit disabled",
"Read only operation not allowed",
"Invalid switch",
"Missing value",
"Too few arguments",
"Too many arguments",
"Non-existent device",
"Non-existent unit",
"Non-existent register",
"Non-existent parameter",
"Nested DO commands",
"Internal error",
"Invalid magtape record length",
"Console Telnet connection lost",
"Console Telnet connection timed out"
};
const size_t size_map[] = { sizeof (int8),
sizeof (int8), sizeof (int16), sizeof (int32), sizeof (int32)
#if defined (t_int64)
, sizeof (t_int64), sizeof (t_int64), sizeof (t_int64), sizeof (t_int64)
#endif
};
const t_value width_mask[] = { 0,
0x1, 0x3, 0x7, 0xF,
0x1F, 0x3F, 0x7F, 0xFF,
0x1FF, 0x3FF, 0x7FF, 0xFFF,
0x1FFF, 0x3FFF, 0x7FFF, 0xFFFF,
0x1FFFF, 0x3FFFF, 0x7FFFF, 0xFFFFF,
0x1FFFFF, 0x3FFFFF, 0x7FFFFF, 0xFFFFFF,
0x1FFFFFF, 0x3FFFFFF, 0x7FFFFFF, 0xFFFFFFF,
0x1FFFFFFF, 0x3FFFFFFF, 0x7FFFFFFF, 0xFFFFFFFF
#if defined (t_int64)
, 0x1FFFFFFFF, 0x3FFFFFFFF, 0x7FFFFFFFF, 0xFFFFFFFFF,
0x1FFFFFFFFF, 0x3FFFFFFFFF, 0x7FFFFFFFFF, 0xFFFFFFFFFF,
0x1FFFFFFFFFF, 0x3FFFFFFFFFF, 0x7FFFFFFFFFF, 0xFFFFFFFFFFF,
0x1FFFFFFFFFFF, 0x3FFFFFFFFFFF, 0x7FFFFFFFFFFF, 0xFFFFFFFFFFFF,
0x1FFFFFFFFFFFF, 0x3FFFFFFFFFFFF, 0x7FFFFFFFFFFFF, 0xFFFFFFFFFFFFF,
0x1FFFFFFFFFFFFF, 0x3FFFFFFFFFFFFF, 0x7FFFFFFFFFFFFF, 0xFFFFFFFFFFFFFF,
0x1FFFFFFFFFFFFFF, 0x3FFFFFFFFFFFFFF,
0x7FFFFFFFFFFFFFF, 0xFFFFFFFFFFFFFFF,
0x1FFFFFFFFFFFFFFF, 0x3FFFFFFFFFFFFFFF,
0x7FFFFFFFFFFFFFFF, 0xFFFFFFFFFFFFFFFF
#endif
};
static CTAB cmd_table[] = {
{ "RESET", &reset_cmd, 0,
"r{eset} {ALL|<device>} reset simulator\n" },
{ "EXAMINE", &exdep_cmd, EX_E,
"e{xamine} <list> examine memory or registers\n" },
{ "IEXAMINE", &exdep_cmd, EX_E+EX_I,
"ie{xamine} <list> interactive examine memory or registers\n" },
{ "DEPOSIT", &exdep_cmd, EX_D,
"d{eposit} <list> <val> deposit in memory or registers\n" },
{ "IDEPOSIT", &exdep_cmd, EX_D+EX_I,
"id{eposit} <list> interactive deposit in memory or registers\n" },
{ "EVALUATE", &eval_cmd, 0,
"ev{aluate} <expr> evaluate symbolic expression\n" },
{ "RUN", &run_cmd, RU_RUN,
"ru{n} {new PC} reset and start simulation\n" },
{ "GO", &run_cmd, RU_GO,
"go {new PC} start simulation\n" },
{ "STEP", &run_cmd, RU_STEP,
"s{tep} {n} simulate n instructions\n" },
{ "CONT", &run_cmd, RU_CONT,
"c{ont} continue simulation\n" },
{ "BOOT", &run_cmd, RU_BOOT,
"b{oot} <unit> bootstrap unit\n" },
{ "BREAK", &brk_cmd, SSH_ST,
"br{eak} <list> set breakpoints\n" },
{ "NOBREAK", &brk_cmd, SSH_CL,
"nobr{eak} <list> clear breakpoints\n" },
{ "ATTACH", &attach_cmd, 0,
"at{tach} <unit> <file> attach file to simulated unit\n" },
{ "DETACH", &detach_cmd, 0,
"det{ach} <unit> detach file from simulated unit\n" },
{ "ASSIGN", &assign_cmd, 0,
"as{sign} <device> <name> assign logical name for device\n" },
{ "DEASSIGN", &deassign_cmd, 0,
"dea{ssign} <device> deassign logical name for device\n" },
{ "SAVE", &save_cmd, 0,
"sa{ve} <file> save simulator to file\n" },
{ "RESTORE", &restore_cmd, 0,
"rest{ore}|ge{t} <file> restore simulator from file\n" },
{ "GET", &restore_cmd, 0, NULL },
{ "LOAD", &load_cmd, 0,
"l{oad} <file> {<args>} load binary file\n" },
{ "DUMP", &load_cmd, 1,
"du(mp) <file> {<args>} dump binary file\n" },
{ "EXIT", &exit_cmd, 0,
"exi{t}|q{uit}|by{e} exit from simulation\n" },
{ "QUIT", &exit_cmd, 0, NULL },
{ "BYE", &exit_cmd, 0, NULL },
{ "SET", &set_cmd, 0,
"set log <file> enable logging to file\n"
"set nolog disable logging\n"
"set telnet <port> enable Telnet port for console\n"
"set notelnet disable Telnet for console\n"
"set <dev> OCT|DEC|HEX set device display radix\n"
"set <dev> ENABLED enable device\n"
"set <dev> DISABLED disable device\n"
"set <unit> ONLINE enable unit\n"
"set <unit> OFFLINE disable unit\n"
"set <dev>|<unit> <prm> set device/unit parameter\n"
},
{ "SHOW", &show_cmd, 0,
"sh{ow} br{eak} <list> show breakpoints on address list\n"
"sh{ow} c{onfiguration} show configuration\n"
"sh{ow} d{evices} show devices\n"
"sh{ow} l{og} show log\n"
"sh{ow} m{odifiers} show modifiers\n"
"sh{ow} n{ames} show logical names\n"
"sh{ow} q{ueue} show event queue\n"
"sh{ow} te{lnet} show console Telnet status\n"
"sh{ow} ti{me} show simulated time\n"
"sh{ow} ve{rsion} show simulator version\n"
"sh{ow} <dev>|<unit> show device parameters\n" },
{ "DO", &do_cmd, 0,
"do <file> {arg,arg...} process command file\n" },
{ "HELP", &help_cmd, 0,
"h{elp} type this message\n"
"h{elp} <command> type help for command\n" },
{ "!", &spawn_cmd, 0,
"! execute local command interpreter\n"
"! <command> execute local host command\n" },
{ NULL, NULL, 0 } };
/* Main command loop */
int main (int argc, char *argv[])
{
char cbuf[CBUFSIZE], gbuf[CBUFSIZE], *cptr;
int32 i, sw;
t_bool lookswitch;
t_stat stat;
CTAB *cmdp;
union {int32 i; char c[sizeof (int32)]; } end_test;
#if defined (__MWERKS__) && defined (macintosh)
argc = ccommand (&argv);
#endif
*cbuf = 0; /* init arg buffer */
sim_switches = 0; /* init switches */
lookswitch = TRUE;
for (i = 1; i < argc; i++) { /* loop thru args */
if (argv[i] == NULL) continue; /* paranoia */
if ((*argv[i] == '-') && lookswitch) { /* switch? */
if ((sw = get_switches (argv[i])) < 0) {
fprintf (stderr, "Invalid switch %s\n", argv[i]);
return 0; }
sim_switches = sim_switches | sw; }
else { if ((strlen (argv[i]) + strlen (cbuf) + 1) >= CBUFSIZE) {
fprintf (stderr, "Argument string too long\n");
return 0; }
if (*cbuf) strcat (cbuf, " "); /* concat args */
strcat (cbuf, argv[i]);
lookswitch = FALSE; } /* no more switches */
} /* end for */
sim_quiet = sim_switches & SWMASK ('Q'); /* -q means quiet */
if (sim_vm_init != NULL) (*sim_vm_init)(); /* call once only */
end_test.i = 1; /* test endian-ness */
sim_end = end_test.c[0];
stop_cpu = 0;
sim_interval = 0;
sim_time = sim_rtime = 0;
noqueue_time = 0;
sim_clock_queue = NULL;
sim_is_running = 0;
sim_log = NULL;
if (sim_emax <= 0) sim_emax = 1;
if ((stat = ttinit ()) != SCPE_OK) {
fprintf (stderr, "Fatal terminal initialization error\n%s\n",
scp_error_messages[stat - SCPE_BASE]);
return 0; }
if ((sim_eval = calloc (sim_emax, sizeof (t_value))) == NULL) {
fprintf (stderr, "Unable to allocate examine buffer\n");
return 0; };
if ((stat = reset_all (0)) != SCPE_OK) {
fprintf (stderr, "Fatal simulator initialization error\n%s\n",
scp_error_messages[stat - SCPE_BASE]);
return 0; }
if ((stat = sim_brk_init ()) != SCPE_OK) {
fprintf (stderr, "Fatal breakpoint table initialization error\n%s\n",
scp_error_messages[stat - SCPE_BASE]);
return 0; }
if (!sim_quiet) {
printf ("\n");
show_version (stdout, 0, NULL); }
if (*cbuf) { /* cmd file arg? */
stat = do_cmd (1, cbuf); /* proc cmd file */
if (stat == SCPE_OPENERR) /* error? */
fprintf (stderr, "Can't open file %s\n", cbuf); }
else if (*argv[0]) { /* sim name arg? */
char nbuf[PATH_MAX + 7], *np; /* "path.ini" */
nbuf[0] = '"'; /* starting " */
strncpy (nbuf + 1, argv[0], PATH_MAX + 1); /* copy sim name */
if (np = match_ext (nbuf, "EXE")) *np = 0; /* remove .exe */
strcat (nbuf, ".ini\""); /* add .ini" */
stat = do_cmd (1, nbuf); } /* proc cmd file */
while (stat != SCPE_EXIT) { /* in case exit */
printf ("sim> "); /* prompt */
if (cptr = sim_brk_getact (cbuf, CBUFSIZE)) /* pending action? */
printf ("%s\n", cptr); /* echo */
else if (sim_vm_read != NULL) /* sim routine? */
cptr = (*sim_vm_read) (cbuf, CBUFSIZE, stdin);
else cptr = read_line (cbuf, CBUFSIZE, stdin); /* read command line */
if (cptr == NULL) continue; /* ignore EOF */
if (*cptr == 0) continue; /* ignore blank */
if (sim_log) fprintf (sim_log, "sim> %s\n", cptr); /* log cmd */
cptr = get_glyph (cptr, gbuf, 0); /* get command glyph */
sim_switches = 0; /* init switches */
if (cmdp = find_cmd (gbuf)) /* lookup command */
stat = cmdp->action (cmdp->arg, cptr); /* if found, exec */
else stat = SCPE_UNK;
if (stat >= SCPE_BASE) { /* error? */
printf ("%s\n", scp_error_messages[stat - SCPE_BASE]);
if (sim_log) fprintf (sim_log, "%s\n",
scp_error_messages[stat - SCPE_BASE]); }
if (sim_vm_post != NULL) (*sim_vm_post) (TRUE);
} /* end while */
detach_all (0, TRUE); /* close files */
set_logoff (0, NULL); /* close log */
set_notelnet (0, NULL); /* close Telnet */
ttclose (); /* close console */
return 0;
}
/* Find command routine */
CTAB *find_cmd (char *gbuf)
{
CTAB *cmdp = NULL;
if (sim_vm_cmd) cmdp = find_ctab (sim_vm_cmd, gbuf); /* try ext commands */
if (cmdp == NULL) cmdp = find_ctab (cmd_table, gbuf); /* try regular cmds */
return cmdp;
}
/* Exit command */
t_stat exit_cmd (int32 flag, char *cptr)
{
return SCPE_EXIT;
}
/* Help command */
void fprint_help (FILE *st)
{
CTAB *cmdp;
for (cmdp = cmd_table; cmdp && (cmdp->name != NULL); cmdp++) {
if (cmdp->help) fprintf (st, cmdp->help); }
for (cmdp = sim_vm_cmd; cmdp && (cmdp->name != NULL); cmdp++) {
if (cmdp->help) fprintf (st, cmdp->help); }
return;
}
t_stat help_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
CTAB *cmdp;
GET_SWITCHES (cptr);
if (*cptr) {
cptr = get_glyph (cptr, gbuf, 0);
if (*cptr) return SCPE_2MARG;
if (cmdp = find_cmd (gbuf)) {
printf (cmdp->help);
if (sim_log) fprintf (sim_log, cmdp->help); }
else return SCPE_ARG; }
else { fprint_help (stdout);
if (sim_log) fprint_help (sim_log); }
return SCPE_OK;
}
/* Spawn command */
t_stat spawn_cmd (int32 flag, char *cptr)
{
if ((cptr == NULL) || (strlen (cptr) == 0)) cptr = getenv("SHELL");
if ((cptr == NULL) || (strlen (cptr) == 0)) cptr = getenv("ComSpec");
#if defined (VMS)
if ((cptr == NULL) || (strlen (cptr) == 0)) cptr = "SPAWN/INPUT=SYS$COMMAND:";
#endif
fflush(stdout); /* flush stdout */
if (sim_log) fflush (sim_log); /* flush log if enabled */
system (cptr);
#if defined (VMS)
printf ("\n");
#endif
return SCPE_OK;
}
/* Do command */
t_stat do_cmd (int32 flag, char *fcptr)
{
char *cptr, cbuf[CBUFSIZE], gbuf[CBUFSIZE], *c, quote, *do_arg[10];
FILE *fpin;
CTAB *cmdp;
int32 echo, nargs;
t_stat stat = SCPE_OK;
if (flag == 0) { GET_SWITCHES (fcptr); } /* get switches */
echo = sim_switches & SWMASK ('V'); /* -v means echo */
c = fcptr;
for (nargs = 0; nargs < 10; ) { /* extract arguments */
while (isspace (*c)) c++; /* skip blanks */
if (*c == 0) break; /* all done */
if (*c == '\'' || *c == '"') quote = *c++; /* quoted string? */
else quote = 0;
do_arg[nargs++] = c; /* save start */
while (*c && (quote? (*c != quote): !isspace (*c))) c++;
if (*c) *c++ = 0; /* term at quote/spc */
} /* end for */
if (nargs <= 0) return SCPE_2FARG; /* need at least 1 */
if ((fpin = fopen (do_arg[0], "r")) == NULL) /* cmd file failed to open? */
return SCPE_OPENERR;
do { cptr = read_line (cbuf, CBUFSIZE, fpin); /* get cmd line */
sub_args (cbuf, gbuf, CBUFSIZE, nargs, do_arg);
if (cptr == NULL) break; /* exit on eof */
if (*cptr == 0) continue; /* ignore blank */
if (echo) printf("do> %s\n", cptr); /* echo if -v */
if (sim_log) fprintf (sim_log, "do> %s\n", cptr);
cptr = get_glyph (cptr, gbuf, 0); /* get command glyph */
sim_switches = 0; /* init switches */
if (strcmp (gbuf, "DO") == 0) { /* don't recurse */
fclose (fpin);
return SCPE_NEST; }
if (cmdp = find_cmd (gbuf)) /* lookup command */
stat = cmdp->action (cmdp->arg, cptr); /* if found, exec */
else stat = SCPE_UNK;
if (stat >= SCPE_BASE) /* error? */
printf ("%s\n", scp_error_messages[stat - SCPE_BASE]);
if (sim_vm_post != NULL) (*sim_vm_post) (TRUE);
} while (stat != SCPE_EXIT);
fclose (fpin); /* close file */
return (stat == SCPE_EXIT)? SCPE_EXIT: SCPE_OK;
}
/* Substitute_args - replace %n tokens in 'instr' with the do command's arguments
Calling sequence
instr = input string
tmpbuf = temp buffer
maxstr = min (len (instr), len (tmpbuf))
nargs = number of arguments
do_arg[10] = arguments
*/
void sub_args (char *instr, char *tmpbuf, int32 maxstr, int32 nargs, char *do_arg[])
{
char *ip, *op, *ap, *oend = tmpbuf + maxstr - 2;
for (ip = instr, op = tmpbuf; *ip && (op < oend); ) {
if ((*ip == '\\') && (ip[1] == '%')) { /* \% = literal % */
ip++; /* skip \ */
if (*ip) *op++ = *ip++; } /* copy next */
else if ((*ip == '%') && /* %n = sub */
((ip[1] >= '1') && (ip[1] <= ('0'+ nargs - 1)))) {
ap = do_arg[ip[1] - '0'];
ip = ip + 2;
while (*ap && (op < oend)) *op++ = *ap++; }/* copy the argument */
else *op++ = *ip++; } /* literal character */
*op = 0; /* term buffer */
strcpy (instr, tmpbuf);
return;
}
/* Set command */
t_stat set_cmd (int32 flag, char *cptr)
{
int32 lvl;
t_stat r;
char gbuf[CBUFSIZE], *cvptr, *svptr;
DEVICE *dptr;
UNIT *uptr;
MTAB *mptr;
CTAB *gcmdp;
C1TAB *ctbr, *glbr;
static CTAB set_glob_tab[] = {
{ "TELNET", &set_telnet, 0 },
{ "NOTELNET", &set_notelnet, 0 },
{ "LOG", &set_logon, 0 },
{ "NOLOG", &set_logoff, 0 },
{ "BREAK", &brk_cmd, SSH_ST },
{ NULL, NULL, 0 } };
static C1TAB set_dev_tab[] = {
{ "OCTAL", &set_radix, 8 },
{ "DECIMAL", &set_radix, 10 },
{ "HEX", &set_radix, 16 },
{ "ENABLED", &set_devenbdis, 1 },
{ "DISABLED", &set_devenbdis, 0 },
{ NULL, NULL, 0 } };
static C1TAB set_unit_tab[] = {
{ "ONLINE", &set_onoff, 1 },
{ "OFFLINE", &set_onoff, 0 },
{ NULL, NULL, 0 } };
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get glob/dev/unit */
if (dptr = find_dev (gbuf)) { /* device match? */
uptr = dptr->units; /* first unit */
ctbr = set_dev_tab; /* global table */
lvl = MTAB_VDV; } /* device match */
else if (dptr = find_unit (gbuf, &uptr)) { /* unit match? */
if (uptr == NULL) return SCPE_NXUN; /* invalid unit */
ctbr = set_unit_tab; /* global table */
lvl = MTAB_VUN; } /* unit match */
else if (gcmdp = find_ctab (set_glob_tab, gbuf)) /* global? */
return gcmdp->action (gcmdp->arg, cptr); /* do the rest */
else return SCPE_NXDEV; /* no match */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
while (*cptr != 0) { /* do all mods */
cptr = get_glyph (svptr = cptr, gbuf, ','); /* get modifier */
if (cvptr = strchr (gbuf, '=')) *cvptr++ = 0; /* = value? */
for (mptr = dptr->modifiers; mptr && (mptr->mask != 0); mptr++) {
if ((mptr->mstring) && /* match string */
(MATCH_CMD (gbuf, mptr->mstring) == 0)) { /* matches option? */
if (mptr->mask & MTAB_XTD) { /* extended? */
if ((lvl & mptr->mask) == 0) return SCPE_ARG;
if ((lvl & MTAB_VUN) && (uptr->flags & UNIT_DIS))
return SCPE_UDIS; /* unit disabled? */
if (mptr->valid) { /* validation rtn? */
if (cvptr && (mptr->mask & MTAB_NC))
get_glyph_nc (svptr, gbuf, ',');
r = mptr->valid (uptr, mptr->match, cvptr, mptr->desc);
if (r != SCPE_OK) return r; }
else if (!mptr->desc) break; /* value desc? */
else if (mptr->mask & MTAB_VAL) { /* take a value? */
if (!cvptr) return SCPE_MISVAL; /* none? error */
r = dep_reg (0, cvptr, (REG *) mptr->desc, 0);
if (r != SCPE_OK) return r; }
else if (cvptr) return SCPE_ARG; /* = value? */
else *((int32 *) mptr->desc) = mptr->match;
} /* end if xtd */
else { /* old style */
if (cvptr) return SCPE_ARG; /* = value? */
if (uptr->flags & UNIT_DIS) /* disabled? */
return SCPE_UDIS;
if ((mptr->valid) && ((r = mptr->valid
(uptr, mptr->match, cvptr, mptr->desc))
!= SCPE_OK)) return r; /* invalid? */
uptr->flags = (uptr->flags & ~(mptr->mask)) |
(mptr->match & mptr->mask); /* set new value */
} /* end else xtd */
break; /* terminate for */
} /* end if match */
} /* end for */
if (!mptr || (mptr->mask == 0)) { /* no match? */
if (glbr = find_c1tab (ctbr, gbuf)) { /* global match? */
r = glbr->action (dptr, uptr, glbr->arg); /* do global */
if (r != SCPE_OK) return r; }
else if (!dptr->modifiers) return SCPE_NOPARAM; /* no modifiers? */
else return SCPE_NXPAR; } /* end if no mat */
} /* end while */
return SCPE_OK; /* done all */
}
/* Match CTAB/CTAB1 name */
CTAB *find_ctab (CTAB *tab, char *gbuf)
{
for (; tab->name != NULL; tab++) {
if (MATCH_CMD (gbuf, tab->name) == 0) return tab; }
return NULL;
}
C1TAB *find_c1tab (C1TAB *tab, char *gbuf)
{
for (; tab->name != NULL; tab++) {
if (MATCH_CMD (gbuf, tab->name) == 0) return tab; }
return NULL;
}
/* Log on routine */
t_stat set_logon (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
if (*cptr == 0) return SCPE_2FARG; /* need arg */
cptr = get_glyph_nc (cptr, gbuf, 0); /* get file name */
if (*cptr != 0) return SCPE_2MARG; /* now eol? */
set_logoff (0, NULL); /* close cur log */
sim_log = FOPEN (gbuf, "a"); /* open log */
if (sim_log == NULL) return SCPE_OPENERR; /* error? */
if (!sim_quiet) printf ("Logging to file \"%s\"\n", gbuf);
fprintf (sim_log, "Logging to file \"%s\"\n", gbuf); /* start of log */
return SCPE_OK;
}
/* Log off routine */
t_stat set_logoff (int32 flag, char *cptr)
{
if (cptr && (*cptr != 0)) return SCPE_2MARG; /* now eol? */
if (sim_log == NULL) return SCPE_OK; /* no log? */
if (!sim_quiet) printf ("Log file closed\n");
fprintf (sim_log, "Log file closed\n"); /* close log */
fclose (sim_log);
sim_log = NULL;
return SCPE_OK;
}
/* Set controller data radix routine */
t_stat set_radix (DEVICE *dptr, UNIT *uptr, int32 flag)
{
dptr->dradix = flag & 037;
return SCPE_OK;
}
/* Set controller enabled/disabled routine */
t_stat set_devenbdis (DEVICE *dptr, UNIT *uptr, int32 flag)
{
UNIT *up;
uint32 i;
if ((dptr->flags & DEV_DISABLE) == 0) return SCPE_NOFNC;/* allowed? */
if (flag) { /* enable? */
if ((dptr->flags & DEV_DIS) == 0) return SCPE_OK; /* already enb? ok */
dptr->flags = dptr->flags & ~DEV_DIS; } /* no, enable */
else { /* disable */
if (dptr->flags & DEV_DIS) return SCPE_OK; /* already dsb? ok */
for (i = 0; i < dptr->numunits; i++) { /* check units */
up = (dptr->units) + i; /* att or active? */
if ((up->flags & UNIT_ATT) || sim_is_active (up))
return SCPE_NOFNC; } /* can't do it */
dptr->flags = dptr->flags | DEV_DIS; } /* disable */
if (dptr->reset) return dptr->reset (dptr); /* reset device */
else return SCPE_OK;
}
/* Set unit online/offline routine */
t_stat set_onoff (DEVICE *dptr, UNIT *uptr, int32 flag)
{
if (!(uptr->flags & UNIT_DISABLE)) return SCPE_NOFNC; /* allowed? */
if (flag) uptr->flags = uptr->flags & ~UNIT_DIS; /* onl? enable */
else { /* offline? */
if ((uptr->flags & UNIT_ATT) || sim_is_active (uptr))
return SCPE_NOFNC; /* more tests */
uptr->flags = uptr->flags | UNIT_DIS; } /* disable */
return SCPE_OK;
}
/* Show command */
t_stat show_cmd (int32 flag, char *cptr)
{
int32 i, lvl;
t_stat r;
char gbuf[CBUFSIZE];
DEVICE *dptr;
UNIT *uptr;
MTAB *mptr;
static SHTAB show_table[] = {
{ "CONFIGURATION", &show_config, 0 },
{ "DEVICES", &show_config, 1 },
{ "QUEUE", &show_queue, 0 },
{ "TIME", &show_time, 0 },
{ "MODIFIERS", &show_mod_names, 0 },
{ "NAMES", &show_log_names, 0 },
{ "VERSION", &show_version, 0 },
{ "LOG", &show_log, 0 },
{ "TELNET", &show_telnet, 0 },
{ "BREAK", &show_break, 0 },
{ NULL, NULL, 0 } };
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
for (i = 0; show_table[i].name != NULL; i++) { /* find command */
if (MATCH_CMD (gbuf, show_table[i].name) == 0) {
r = show_table[i].action (stdout, show_table[i].arg, cptr);
if (sim_log) show_table[i].action (sim_log, show_table[i].arg, cptr);
return r; } }
if (dptr = find_dev (gbuf)) { /* device match? */
uptr = dptr->units; /* first unit */
lvl = MTAB_VDV; } /* device match */
else if (dptr = find_unit (gbuf, &uptr)) { /* unit match? */
if (uptr == NULL) return SCPE_NXUN; /* invalid unit */
if (uptr->flags & UNIT_DIS) return SCPE_UDIS; /* disabled? */
lvl = MTAB_VUN; } /* unit match */
else return SCPE_NXDEV; /* no match */
if (*cptr == 0) { /* now eol? */
if (lvl == MTAB_VDV) { /* show dev? */
r = show_device (stdout, dptr, 0);
if (sim_log) show_device (sim_log, dptr, 0);
return r; }
else {
r = show_unit (stdout, dptr, uptr, -1);
if (sim_log) show_unit (sim_log, dptr, uptr, -1);
return r; } }
if (dptr->modifiers == NULL) return SCPE_NOPARAM; /* any modifiers? */
while (*cptr != 0) { /* do all mods */
cptr = get_glyph (cptr, gbuf, ','); /* get modifier */
for (mptr = dptr->modifiers; mptr->mask != 0; mptr++) {
if (((mptr->mask & MTAB_XTD)? /* right level? */
(mptr->mask & lvl): (MTAB_VUN & lvl)) &&
((mptr->disp && mptr->pstring && /* named disp? */
(MATCH_CMD (gbuf, mptr->pstring) == 0)) ||
((mptr->mask & MTAB_VAL) && /* named value? */
mptr->mstring &&
(MATCH_CMD (gbuf, mptr->mstring) == 0)))) {
show_one_mod (stdout, dptr, uptr, mptr, 1);
if (sim_log) show_one_mod (sim_log, dptr, uptr, mptr, 1);
break;
} /* end if */
} /* end for */
if (mptr->mask == 0) return SCPE_ARG; /* any match? */
} /* end while */
return SCPE_OK;
}
/* Show device and unit */
t_stat show_device (FILE *st, DEVICE *dptr, int32 flag)
{
uint32 j, ucnt;
UNIT *uptr;
fprintf (st, "%s", sim_dname (dptr)); /* print dev name */
if (qdisable (dptr)) { /* disabled? */
fprintf (st, ", disabled\n");
return SCPE_OK; }
for (j = ucnt = 0; j < dptr->numunits; j++) { /* count units */
uptr = dptr->units + j;
if (!(uptr->flags & UNIT_DIS)) ucnt++; }
show_all_mods (st, dptr, dptr->units, MTAB_VDV); /* show dev mods */
if (dptr->numunits == 0) fprintf (st, "\n");
else { if (ucnt == 0) fprintf (st, ", all units disabled\n");
else if (ucnt > 1) fprintf (st, ", %d units\n", ucnt);
else if (flag) fprintf (st, "\n"); }
if (flag) return SCPE_OK; /* dev only? */
for (j = 0; j < dptr->numunits; j++) { /* loop thru units */
uptr = dptr->units + j;
if ((uptr->flags & UNIT_DIS) == 0)
show_unit (st, dptr, uptr, ucnt); }
return SCPE_OK;
}
t_stat show_unit (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag)
{
int32 u = uptr - dptr->units;
if (flag > 1) fprintf (st, " %s%d", sim_dname (dptr), u);
else if (flag < 0) fprintf (st, "%s%d", sim_dname (dptr), u);
if (uptr->flags & UNIT_FIX) {
fprintf (st, ", ");
fprint_capac (st, dptr, uptr); }
if (uptr->flags & UNIT_ATT) {
fprintf (st, ", attached to %s", uptr->filename);
if (uptr->flags & UNIT_RO) fprintf (st, ", read only"); }
else if (uptr->flags & UNIT_ATTABLE)
fprintf (st, ", not attached");
show_all_mods (st, dptr, uptr, MTAB_VUN); /* show unit mods */
fprintf (st, "\n");
return SCPE_OK;
}
void fprint_capac (FILE *st, DEVICE *dptr, UNIT *uptr)
{
t_addr kval = (uptr->flags & UNIT_BINK)? 1024: 1000;
t_addr mval = kval * kval;
t_addr psize = uptr->capac;
char scale, width;
if ((dptr->dwidth / dptr->aincr) > 8) width = 'W';
else width = 'B';
if (uptr->capac < (kval * 10)) scale = 0;
else if (uptr->capac < (mval * 10)) {
scale = 'K';
psize = psize / kval; }
else { scale = 'M';
psize = psize / mval; }
fprint_val (st, (t_value) psize, 10, T_ADDR_W, PV_LEFT);
if (scale) fputc (scale, st);
fputc (width, st);
return;
}
/* Show <global name> processors */
t_stat show_version (FILE *st, int32 flag, char *cptr)
{
int32 vmaj = SIM_MAJOR, vmin = SIM_MINOR, vpat = SIM_PATCH;
if (cptr && (*cptr != 0)) return SCPE_2MARG;
fprintf (st, "%s simulator V%d.%d-%d\n", sim_name, vmaj, vmin, vpat);
return SCPE_OK;
}
t_stat show_config (FILE *st, int32 flag, char *cptr)
{
int32 i;
DEVICE *dptr;
if (cptr && (*cptr != 0)) return SCPE_2MARG;
fprintf (st, "%s simulator configuration\n\n", sim_name);
for (i = 0; (dptr = sim_devices[i]) != NULL; i++)
show_device (st, dptr, flag);
return SCPE_OK;
}
t_stat show_log_names (FILE *st, int32 flag, char *cptr)
{
int32 i;
DEVICE *dptr;
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) {
if (dptr->lname) fprintf (st, "%s -> %s\n",
dptr->lname, dptr->name); }
return SCPE_OK;
}
t_stat show_queue (FILE *st, int32 flag, char *cptr)
{
DEVICE *dptr;
UNIT *uptr;
int32 accum;
if (cptr && (*cptr != 0)) return SCPE_2MARG;
if (sim_clock_queue == NULL) {
fprintf (st, "%s event queue empty, time = %.0f\n",
sim_name, sim_time);
return SCPE_OK; }
fprintf (st, "%s event queue status, time = %.0f\n",
sim_name, sim_time);
accum = 0;
for (uptr = sim_clock_queue; uptr != NULL; uptr = uptr->next) {
if (uptr == &step_unit) fprintf (st, " Step timer");
else if ((dptr = find_dev_from_unit (uptr)) != NULL) {
fprintf (st, " %s", sim_dname (dptr));
if (dptr->numunits > 1) fprintf (st, " unit %d",
uptr - dptr->units); }
else fprintf (st, " Unknown");
fprintf (st, " at %d\n", accum + uptr->time);
accum = accum + uptr->time; }
return SCPE_OK;
}
t_stat show_time (FILE *st, int32 flag, char *cptr)
{
if (cptr && (*cptr != 0)) return SCPE_2MARG;
fprintf (st, "Time: %.0f\n", sim_time);
return SCPE_OK;
}
t_stat show_log (FILE *st, int32 flag, char *cptr)
{
if (cptr && (*cptr != 0)) return SCPE_2MARG;
if (sim_log) fprintf (st, "Logging enabled\n");
else fprintf (st, "Logging disabled\n");
return SCPE_OK;
}
t_stat show_break (FILE *st, int32 flag, char *cptr)
{
t_stat r;
if (cptr && (*cptr != 0)) { /* more? */
r = ssh_break (stdout, cptr, 1);
if (sim_log) ssh_break (sim_log, cptr, SSH_SH); }
else { r = sim_brk_showall (stdout, sim_switches);
if (sim_log) sim_brk_showall (sim_log,sim_switches); }
return r;
}
/* Show modifiers */
t_stat show_mod_names (FILE *st, int32 flag, char *cptr)
{
int32 i, any, enb;
DEVICE *dptr;
MTAB *mptr;
if (cptr && (*cptr != 0)) return SCPE_2MARG; /* now eol? */
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) {
any = enb = 0;
if (dptr->modifiers) {
for (mptr = dptr->modifiers; mptr->mask != 0; mptr++) {
if (mptr->mstring) {
if (strcmp (mptr->mstring, "ENABLED") == 0) enb = 1;
if (any++) fprintf (st, ", %s", mptr->mstring);
else fprintf (st, "%s\t%s", sim_dname (dptr), mptr->mstring); } } }
if (!enb && (dptr->flags & DEV_DISABLE)) {
if (any++) fprintf (st, ", ENABLED, DISABLED");
else fprintf (st, "%s\tENABLED, DISABLED", sim_dname (dptr)); }
if (any) fprintf (st, "\n"); }
return SCPE_OK;
}
t_stat show_all_mods (FILE *st, DEVICE *dptr, UNIT *uptr, int32 flag)
{
MTAB *mptr;
if (dptr->modifiers == NULL) return SCPE_OK;
for (mptr = dptr->modifiers; mptr->mask != 0; mptr++) {
if (mptr->pstring && ((mptr->mask & MTAB_XTD)?
((mptr->mask & flag) && !(mptr->mask & MTAB_NMO)):
((MTAB_VUN & flag) && ((uptr->flags & mptr->mask) == mptr->match)))) {
fputs (", ", st);
show_one_mod (st, dptr, uptr, mptr, 0); } }
return SCPE_OK;
}
t_stat show_one_mod (FILE *st, DEVICE *dptr, UNIT *uptr, MTAB *mptr, int32 flag)
{
t_value val;
if (mptr->disp) mptr->disp (st, uptr, mptr->match, mptr->desc);
else if ((mptr->mask & MTAB_XTD) && (mptr->mask & MTAB_VAL)) {
REG *rptr = (REG *) mptr->desc;
fprintf (st, "%s=", mptr->pstring);
val = get_rval (rptr, 0);
fprint_val (st, val, rptr->radix, rptr->width,
rptr->flags & REG_FMT); }
else fputs (mptr->pstring, st);
if (flag && !((mptr->mask & MTAB_XTD) &&
(mptr->mask & MTAB_NMO))) fputc ('\n', st);
return SCPE_OK;
}
/* Breakpoint commands */
t_stat brk_cmd (int32 flg, char *cptr)
{
GET_SWITCHES (cptr); /* get switches */
return ssh_break (NULL, cptr, flg); /* call common code */
}
t_stat ssh_break (FILE *st, char *cptr, int32 flg)
{
char gbuf[CBUFSIZE], *tptr, *t1ptr, *aptr;
DEVICE *dptr = sim_devices[0];
UNIT *uptr = dptr->units;
t_stat r;
t_addr lo, hi, max = uptr->capac - dptr->aincr;
int32 cnt;
if (*cptr == 0) return SCPE_2FARG;
if (sim_brk_types == 0) return SCPE_NOFNC;
if ((dptr == NULL) || (uptr == NULL)) return SCPE_IERR;
if (aptr = strchr (cptr, ';')) { /* ;action? */
if (flg != SSH_ST) return SCPE_ARG; /* only on SET */
*aptr++ = 0; } /* separate strings */
while (*cptr) {
cptr = get_glyph (cptr, gbuf, ',');
tptr = get_range (gbuf, &lo, &hi, dptr->aradix, max, 0);
if (tptr == NULL) return SCPE_ARG;
if (*tptr == '[') {
cnt = (int32) strtotv (tptr + 1, &t1ptr, 10);
if ((tptr == t1ptr) || (*t1ptr != ']') ||
(flg != SSH_ST)) return SCPE_ARG;
tptr = t1ptr + 1; }
else cnt = 0;
if (*tptr != 0) return SCPE_ARG;
if ((lo == 0) && (hi == max)) {
if (flg == SSH_CL) sim_brk_clrall (sim_switches);
else if (flg == SSH_SH) sim_brk_showall (st, sim_switches);
else return SCPE_ARG; }
else {
for ( ; lo <= hi; lo = lo + dptr->aincr) {
if (flg == SSH_ST) r = sim_brk_set (lo, sim_switches, cnt, aptr);
else if (flg == SSH_CL) r = sim_brk_clr (lo, sim_switches);
else if (flg == SSH_SH) r = sim_brk_show (st, lo, sim_switches);
else return SCPE_ARG;
if (r != SCPE_OK) return r;
}
}
}
return SCPE_OK;
}
/* Reset command and routines
re[set] reset all devices
re[set] all reset all devices
re[set] device reset specific device
*/
t_stat reset_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return (reset_all (0)); /* reset(cr) */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
if (*cptr != 0) return SCPE_2MARG; /* now eol? */
if (strcmp (gbuf, "ALL") == 0) return (reset_all (0));
dptr = find_dev (gbuf); /* locate device */
if (dptr == NULL) return SCPE_NXDEV; /* found it? */
if (dptr->reset != NULL) return dptr->reset (dptr);
else return SCPE_OK;
}
/* Reset devices start..end
Inputs:
start = number of starting device
Outputs:
status = error status
*/
t_stat reset_all (uint32 start)
{
DEVICE *dptr;
uint32 i;
t_stat reason;
if (start < 0) return SCPE_IERR;
for (i = 0; i < start; i++) {
if (sim_devices[i] == NULL) return SCPE_IERR; }
for (i = start; (dptr = sim_devices[i]) != NULL; i++) {
if (dptr->reset != NULL) {
reason = dptr->reset (dptr);
if (reason != SCPE_OK) return reason; } }
return SCPE_OK;
}
/* Load and dump commands
lo[ad] filename {arg} load specified file
du[mp] filename {arg} dump to specified file
*/
t_stat load_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
FILE *loadfile;
t_stat reason;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph_nc (cptr, gbuf, 0); /* get file name */
loadfile = FOPEN (gbuf, flag? "wb": "rb"); /* open for wr/rd */
if (loadfile == NULL) return SCPE_OPENERR;
GET_SWITCHES (cptr); /* get switches */
reason = sim_load (loadfile, cptr, gbuf, flag); /* load or dump */
fclose (loadfile);
return reason;
}
/* Attach command
at[tach] unit file attach specified unit to file
*/
t_stat attach_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
UNIT *uptr;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* now eol? */
dptr = find_unit (gbuf, &uptr); /* locate unit */
if (dptr == NULL) return SCPE_NXDEV; /* found dev? */
if (uptr == NULL) return SCPE_NXUN; /* valid unit? */
if (dptr->attach != NULL) return dptr->attach (uptr, cptr);
return attach_unit (uptr, cptr);
}
t_stat attach_unit (UNIT *uptr, char *cptr)
{
DEVICE *dptr;
t_stat reason;
if (uptr->flags & UNIT_DIS) return SCPE_UDIS; /* disabled? */
if (!(uptr->flags & UNIT_ATTABLE)) return SCPE_NOATT; /* not attachable? */
if ((dptr = find_dev_from_unit (uptr)) == NULL) return SCPE_NOATT;
if (uptr->flags & UNIT_ATT) { /* already attached? */
reason = detach_unit (uptr);
if (reason != SCPE_OK) return reason; }
uptr->filename = calloc (CBUFSIZE, sizeof (char));
if (uptr->filename == NULL) return SCPE_MEM;
strncpy (uptr->filename, cptr, CBUFSIZE);
if (sim_switches & SWMASK ('R')) { /* read only? */
if ((uptr->flags & UNIT_ROABLE) == 0) /* allowed? */
return attach_err (uptr, SCPE_NORO); /* no, error */
uptr->fileref = FOPEN (cptr, "rb"); /* open rd only */
if (uptr->fileref == NULL) /* open fail? */
return attach_err (uptr, SCPE_OPENERR); /* yes, error */
uptr->flags = uptr->flags | UNIT_RO; /* set rd only */
if (!sim_quiet) printf ("%s: unit is read only\n", sim_dname (dptr)); }
else { /* normal */
uptr->fileref = FOPEN (cptr, "rb+"); /* open r/w */
if (uptr->fileref == NULL) { /* open fail? */
if (errno == EROFS) { /* read only? */
if ((uptr->flags & UNIT_ROABLE) == 0) /* allowed? */
return attach_err (uptr, SCPE_NORO); /* no error */
uptr->fileref = FOPEN (cptr, "rb"); /* open rd only */
if (uptr->fileref == NULL) /* open fail? */
return attach_err (uptr, SCPE_OPENERR); /* yes, error */
uptr->flags = uptr->flags | UNIT_RO; /* set rd only */
if (!sim_quiet) printf ("%s: unit is read only\n", sim_dname (dptr)); }
else { /* doesn't exist */
if (sim_switches & SWMASK ('E')) /* must exist? */
return attach_err (uptr, SCPE_OPENERR); /* yes, error */
uptr->fileref = FOPEN (cptr, "wb+"); /* open new file */
if (uptr->fileref == NULL) /* open fail? */
return attach_err (uptr, SCPE_OPENERR); /* yes, error */
if (!sim_quiet) printf ("%s: creating new file\n", sim_dname (dptr)); }
} /* end if null */
} /* end else */
if (uptr->flags & UNIT_BUFABLE) { /* buffer? */
uint32 cap = ((uint32) uptr->capac) / dptr->aincr; /* effective size */
if (uptr->flags & UNIT_MUSTBUF) /* dyn alloc? */
uptr->filebuf = calloc (cap, SZ_D (dptr)); /* allocate */
if (uptr->filebuf == NULL) /* no buffer? */
return attach_err (uptr, SCPE_MEM); /* error */
if (!sim_quiet) printf ("%s: buffering file in memory\n", sim_dname (dptr));
uptr->hwmark = fxread (uptr->filebuf, SZ_D (dptr), /* read file */
cap, uptr->fileref);
uptr->flags = uptr->flags | UNIT_BUF; } /* set buffered */
uptr->flags = uptr->flags | UNIT_ATT;
uptr->pos = 0;
return SCPE_OK;
}
t_stat attach_err (UNIT *uptr, t_stat stat)
{
free (uptr->filename);
uptr->filename = NULL;
return stat;
}
/* Detach command
det[ach] all detach all units
det[ach] unit detach specified unit
*/
t_stat detach_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
UNIT *uptr;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
if (*cptr != 0) return SCPE_2MARG; /* now eol? */
if (strcmp (gbuf, "ALL") == 0) return (detach_all (0, FALSE));
dptr = find_unit (gbuf, &uptr); /* locate unit */
if (dptr == NULL) return SCPE_NXDEV; /* found dev? */
if (uptr == NULL) return SCPE_NXUN; /* valid unit? */
if (!(uptr->flags & UNIT_ATTABLE)) return SCPE_NOATT;
if (dptr->detach != NULL) return dptr->detach (uptr);
return detach_unit (uptr);
}
/* Detach devices start..end
Inputs:
start = number of starting device
shutdown = TRUE if simulator shutting down
Outputs:
status = error status
*/
t_stat detach_all (int32 start, t_bool shutdown)
{
uint32 i, j;
t_stat reason;
DEVICE *dptr;
UNIT *uptr;
if ((start < 0) || (start > 1)) return SCPE_IERR;
for (i = start; (dptr = sim_devices[i]) != NULL; i++) {
for (j = 0; j < dptr->numunits; j++) {
uptr = (dptr->units) + j;
if ((uptr->flags & UNIT_ATTABLE) || shutdown) {
if (dptr->detach != NULL) reason = dptr->detach (uptr);
else reason = detach_unit (uptr);
if (reason != SCPE_OK) return reason; } } }
return SCPE_OK;
}
t_stat detach_unit (UNIT *uptr)
{
DEVICE *dptr;
if (uptr == NULL) return SCPE_IERR;
if (!(uptr->flags & UNIT_ATT)) return SCPE_OK;
if ((dptr = find_dev_from_unit (uptr)) == NULL) return SCPE_OK;
if (uptr->flags & UNIT_BUF) {
uint32 cap = (uptr->hwmark + dptr->aincr - 1) / dptr->aincr;
if (uptr->hwmark && ((uptr->flags & UNIT_RO) == 0)) {
if (!sim_quiet) printf ("%s: writing buffer to file\n", sim_dname (dptr));
rewind (uptr->fileref);
fxwrite (uptr->filebuf, SZ_D (dptr), cap, uptr->fileref);
if (ferror (uptr->fileref)) perror ("I/O error"); }
if (uptr->flags & UNIT_MUSTBUF) { /* dyn alloc? */
free (uptr->filebuf); /* free buf */
uptr->filebuf = NULL; }
uptr->flags = uptr->flags & ~UNIT_BUF; }
uptr->flags = uptr->flags & ~(UNIT_ATT | UNIT_RO);
free (uptr->filename);
uptr->filename = NULL;
return (fclose (uptr->fileref) == EOF)? SCPE_IOERR: SCPE_OK;
}
/* Assign command
as[sign] device name assign logical name to device
*/
t_stat assign_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* now eol? */
dptr = find_dev (gbuf); /* locate device */
if (dptr == NULL) return SCPE_NXDEV; /* found dev? */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
if (*cptr != 0) return SCPE_2MARG; /* must be eol */
if (find_dev (gbuf)) return SCPE_ARG; /* name in use */
deassign_device (dptr); /* release current */
return assign_device (dptr, gbuf);
}
t_stat assign_device (DEVICE *dptr, char *cptr)
{
dptr->lname = calloc (CBUFSIZE, sizeof (char));
if (dptr->lname == NULL) return SCPE_MEM;
strncpy (dptr->lname, cptr, CBUFSIZE);
return SCPE_OK;
}
/* Deassign command
dea[ssign] device deassign logical name
*/
t_stat deassign_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
DEVICE *dptr;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
if (*cptr != 0) return SCPE_2MARG; /* now eol? */
dptr = find_dev (gbuf); /* locate device */
if (dptr == NULL) return SCPE_NXDEV; /* found dev? */
return deassign_device (dptr);
}
t_stat deassign_device (DEVICE *dptr)
{
if (dptr->lname) free (dptr->lname);
dptr->lname = NULL;
return SCPE_OK;
}
/* Get device display name */
char *sim_dname (DEVICE *dptr)
{
return (dptr->lname? dptr->lname: dptr->name);
}
/* Save command
sa[ve] filename save state to specified file
*/
t_stat save_cmd (int32 flag, char *cptr)
{
FILE *sfile;
t_stat r;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
if ((sfile = FOPEN (cptr, "wb")) == NULL) return SCPE_OPENERR;
r = sim_save (sfile);
fclose (sfile);
return r;
}
t_stat sim_save (FILE *sfile)
{
void *mbuf;
int32 l, t;
uint32 i, j;
t_addr k, high;
t_value val;
t_stat r;
t_bool zeroflg;
size_t sz;
DEVICE *dptr;
UNIT *uptr;
REG *rptr;
#define WRITE_I(xx) fxwrite (&(xx), sizeof (xx), 1, sfile)
fputs (save_vercur, sfile); /* [V2.5] save format */
fputc ('\n', sfile);
fputs (sim_name, sfile); /* sim name */
fputc ('\n', sfile);
WRITE_I (sim_time); /* sim time */
WRITE_I (sim_rtime); /* [V2.6] sim rel time */
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) { /* loop thru devices */
fputs (dptr->name, sfile); /* device name */
fputc ('\n', sfile);
if (dptr->lname) fputs (dptr->lname, sfile); /* [V3.0] logical name */
fputc ('\n', sfile);
WRITE_I (dptr->flags); /* [V2.10] flags */
for (j = 0; j < dptr->numunits; j++) {
uptr = dptr->units + j;
t = sim_is_active (uptr);
WRITE_I (j); /* unit number */
WRITE_I (t); /* activation time */
WRITE_I (uptr->u3); /* unit specific */
WRITE_I (uptr->u4);
WRITE_I (uptr->u5); /* [V3.0] more unit */
WRITE_I (uptr->u6);
WRITE_I (uptr->flags); /* [V2.10] flags */
if (uptr->flags & UNIT_ATT) fputs (uptr->filename, sfile);
fputc ('\n', sfile);
if (((uptr->flags & (UNIT_FIX + UNIT_ATTABLE)) == UNIT_FIX) &&
(dptr->examine != NULL) &&
((high = uptr->capac) != 0)) { /* memory-like unit? */
WRITE_I (high); /* [V2.5] write size */
sz = SZ_D (dptr);
if ((mbuf = calloc (SRBSIZ, sz)) == NULL) {
fclose (sfile);
return SCPE_MEM; }
for (k = 0; k < high; ) { /* loop thru mem */
zeroflg = TRUE;
for (l = 0; (l < SRBSIZ) && (k < high); l++,
k = k + (dptr->aincr)) { /* check for 0 block */
r = dptr->examine (&val, k, uptr, 0);
if (r != SCPE_OK) return r;
if (val) zeroflg = FALSE;
SZ_STORE (sz, val, mbuf, l);
} /* end for l */
if (zeroflg) { /* all zero's? */
l = -l; /* invert block count */
WRITE_I (l); } /* write only count */
else {
WRITE_I (l); /* block count */
fxwrite (mbuf, sz, l, sfile); }
} /* end for k */
free (mbuf); /* dealloc buffer */
} /* end if mem */
else { /* no memory */
high = 0; /* write 0 */
WRITE_I (high);
} /* end else mem */
} /* end unit loop */
t = -1; /* end units */
WRITE_I (t); /* write marker */
for (rptr = dptr->registers; (rptr != NULL) && /* loop thru regs */
(rptr->name != NULL); rptr++) {
fputs (rptr->name, sfile); /* name */
fputc ('\n', sfile);
WRITE_I (rptr->depth); /* [V2.10] depth */
for (j = 0; j < rptr->depth; j++) { /* loop thru values */
val = get_rval (rptr, j); /* get value */
WRITE_I (val); } } /* store */
fputc ('\n', sfile); } /* end registers */
fputc ('\n', sfile); /* end devices */
return (ferror (sfile))? SCPE_IOERR: SCPE_OK; /* error during save? */
}
/* Restore command
re[store] filename restore state from specified file
*/
t_stat restore_cmd (int32 flag, char *cptr)
{
FILE *rfile;
t_stat r;
GET_SWITCHES (cptr); /* get switches */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
if ((rfile = FOPEN (cptr, "rb")) == NULL) return SCPE_OPENERR;
r = sim_rest (rfile);
fclose (rfile);
return r;
}
t_stat sim_rest (FILE *rfile)
{
char buf[CBUFSIZE];
void *mbuf;
int32 j, blkcnt, limit, unitno, time, flg;
uint32 us, depth;
t_addr k, high;
t_value val, mask;
t_stat r;
size_t sz;
t_bool v30 = FALSE, v210 = FALSE;
DEVICE *dptr;
UNIT *uptr;
REG *rptr;
#define READ_S(xx) if (read_line ((xx), CBUFSIZE, rfile) == NULL) \
return SCPE_IOERR;
#define READ_I(xx) if (fxread (&xx, sizeof (xx), 1, rfile) == 0) \
return SCPE_IOERR;
READ_S (buf); /* [V2.5+] read version */
if (strcmp (buf, save_vercur) == 0) v30 = v210 = TRUE; /* version 2.11? */
else if (strcmp (buf, save_ver210) == 0) v210 = TRUE; /* version 2.10? */
else if (strcmp (buf, save_ver26) != 0) { /* version 2.6? */
printf ("Invalid file version: %s\n", buf); /* no, unknown */
return SCPE_INCOMP; }
READ_S (buf); /* read sim name */
if (strcmp (buf, sim_name)) { /* name match? */
printf ("Wrong system type: %s\n", buf);
return SCPE_INCOMP; }
READ_I (sim_time); /* sim time */
READ_I (sim_rtime); /* [V2.6+] sim rel time */
for ( ;; ) { /* device loop */
READ_S (buf); /* read device name */
if (buf[0] == 0) break; /* last? */
if ((dptr = find_dev (buf)) == NULL) { /* locate device */
printf ("Invalid device name: %s\n", buf);
return SCPE_INCOMP; }
if (v30) { /* [V3.0+] */
READ_S (buf); /* read logical name */
deassign_device (dptr); /* delete old name */
if ((buf[0] != 0) &&
((r = assign_device (dptr, buf)) != SCPE_OK)) return r; }
if (v210) { /* [V2.10+] */
READ_I (flg); /* cont flags */
dptr->flags = (dptr->flags & ~DEV_RFLAGS) | /* restore */
(flg & DEV_RFLAGS); }
for ( ;; ) { /* unit loop */
READ_I (unitno); /* unit number */
if (unitno < 0) break; /* end units? */
if ((uint32) unitno >= dptr->numunits) { /* too big? */
printf ("Invalid unit number: %s%d\n", sim_dname (dptr), unitno);
return SCPE_INCOMP; }
READ_I (time); /* event time */
uptr = (dptr->units) + unitno;
sim_cancel (uptr);
if (time > 0) sim_activate (uptr, time - 1);
READ_I (uptr->u3); /* device specific */
READ_I (uptr->u4);
if (v30) { /* [V3.0+] */
READ_I (uptr->u5); /* more dev specific */
READ_I (uptr->u6); }
if (v210) { /* [V2.10+] */
READ_I (flg); /* unit flags */
uptr->flags = (uptr->flags & ~UNIT_RFLAGS) |
(flg & UNIT_RFLAGS); } /* restore */
READ_S (buf); /* attached file */
if (!(dptr->flags & DEV_NET) || /* if not net dev or */
!(uptr->flags & UNIT_ATT) || /* not currently att */
(buf[0] == 0)) { /* or will not be att */
if (dptr->detach) r = dptr->detach (uptr); /* detach old */
else r = detach_unit (uptr);
if (r != SCPE_OK) return r;
if (buf[0] != 0) { /* any file? */
uptr->flags = uptr->flags & ~UNIT_DIS;
sim_switches = SIM_SW_REST; /* attach/rest */
if (v210 && (flg & UNIT_RO)) /* saved flgs & RO? */
sim_switches |= SWMASK ('R'); /* RO attach */
if (dptr->attach != NULL) r = dptr->attach (uptr, buf);
else r = attach_unit (uptr, buf);
if (r != SCPE_OK) return r; } }
READ_I (high); /* memory capacity */
if (high > 0) { /* [V2.5+] any memory? */
if (((uptr->flags & (UNIT_FIX + UNIT_ATTABLE)) != UNIT_FIX) ||
(dptr->deposit == NULL)) {
printf ("Can't restore memory: %s%d\n", sim_dname (dptr), unitno);
return SCPE_INCOMP; }
if (high != uptr->capac) {
if ((dptr->flags & DEV_DYNM) &&
((dptr->msize == NULL) ||
(dptr->msize (uptr, (int32) high, NULL, NULL) != SCPE_OK))) {
printf ("Can't change memory size: %s%d\n",
sim_dname (dptr), unitno);
return SCPE_INCOMP; }
uptr->capac = high;
printf ("Memory size changed: %s%d = ", sim_dname (dptr), unitno);
fprint_capac (stdout, dptr, uptr);
printf ("\n"); }
sz = SZ_D (dptr); /* allocate buffer */
if ((mbuf = calloc (SRBSIZ, sz)) == NULL)
return SCPE_MEM;
for (k = 0; k < high; ) { /* loop thru mem */
READ_I (blkcnt); /* block count */
if (blkcnt < 0) limit = -blkcnt; /* compressed? */
else limit = fxread (mbuf, sz, blkcnt, rfile);
if (limit <= 0) return SCPE_IOERR; /* invalid or err? */
for (j = 0; j < limit; j++, k = k + (dptr->aincr)) {
if (blkcnt < 0) val = 0; /* compressed? */
else SZ_LOAD (sz, val, mbuf, j);/* saved value */
r = dptr->deposit (val, k, uptr, 0);
if (r != SCPE_OK) return r;
} /* end for j */
} /* end for k */
free (mbuf); /* dealloc buffer */
} /* end if high */
} /* end unit loop */
for ( ;; ) { /* register loop */
READ_S (buf); /* read reg name */
if (buf[0] == 0) break; /* last? */
if (v210) { READ_I (depth); } /* [V2.10+] depth */
if ((rptr = find_reg (buf, NULL, dptr)) == NULL) {
printf ("Invalid register name: %s %s\n", sim_dname (dptr), buf);
if (v210) { /* [V2.10]+ */
for (us = 0; us < depth; us++) { /* skip values */
READ_I (val); } }
else {
READ_I (val); /* must be one val */
if (!restore_skip_val (rfile)) /* grope for next reg */
return SCPE_INCOMP; } /* err or eof? */
continue; } /* pray! */
if (v210 && (depth != rptr->depth)) /* [V2.10+] mismatch? */
printf ("Register depth mismatch: %s %s, file = %d, sim = %d\n",
sim_dname (dptr), buf, depth, rptr->depth);
else depth = rptr->depth; /* depth validated */
mask = width_mask[rptr->width]; /* get mask */
for (us = 0; us < depth; us++) { /* loop thru values */
READ_I (val); /* read value */
if (val > mask) /* value ok? */
printf ("Invalid register value: %s %s\n", sim_dname (dptr), buf);
else if (us < rptr->depth) /* in range? */
put_rval (rptr, us, val); } }
} /* end device loop */
return SCPE_OK;
}
/* Restore skip values (pre V2.10)
To find the next register name, sift through bytes looking for valid
upper case ASCII characters terminated by \n */
t_bool restore_skip_val (FILE *rfile)
{
t_bool instr = FALSE;
char c;
int32 ic, pos;
if ((ic = fgetc (rfile)) == EOF) return FALSE; /* one char */
fseek (rfile, ftell (rfile) - 1, SEEK_SET); /* back up over */
if ((ic & 0377) == '\n') return TRUE; /* immediate nl? */
while ((ic = fgetc (rfile)) != EOF) { /* get char */
c = ic & 0377; /* cut to 8b */
if (isalnum (c) || (c == '*') || (c == '_')) { /* valid reg char? */
if (!instr) pos = ftell (rfile) - 1; /* new? save pos */
instr = TRUE; }
else { /* not ASCII */
if ((c == '\n') && instr) { /* nl & in string? */
fseek (rfile, pos, SEEK_SET); /* rewind file */
return TRUE; }
instr = FALSE; } /* not in string */
} /* end while */
return FALSE; /* error */
}
/* Run, go, cont, step commands
ru[n] [new PC] reset and start simulation
go [new PC] start simulation
co[nt] start simulation
s[tep] [step limit] start simulation for 'limit' instructions
b[oot] device bootstrap from device and start simulation
*/
t_stat run_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE];
uint32 i, j;
int32 step, unitno;
t_stat r;
DEVICE *dptr;
UNIT *uptr;
void int_handler (int signal);
GET_SWITCHES (cptr); /* get switches */
step = 0;
if (((flag == RU_RUN) || (flag == RU_GO)) && (*cptr != 0)) { /* run or go */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
if ((r = dep_reg (0, gbuf, sim_PC, 0)) != SCPE_OK) return r; }
if (flag == RU_STEP) { /* step */
if (*cptr == 0) step = 1;
else {
cptr = get_glyph (cptr, gbuf, 0);
step = (int32) get_uint (gbuf, 10, INT_MAX, &r);
if ((r != SCPE_OK) || (step == 0)) return SCPE_ARG; } }
if (flag == RU_BOOT) { /* boot */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
cptr = get_glyph (cptr, gbuf, 0); /* get next glyph */
dptr = find_unit (gbuf, &uptr); /* locate unit */
if (dptr == NULL) return SCPE_NXDEV; /* found dev? */
if (uptr == NULL) return SCPE_NXUN; /* valid unit? */
if (dptr->boot == NULL) return SCPE_NOFNC; /* can it boot? */
if (uptr->flags & UNIT_DIS) return SCPE_UDIS; /* disabled? */
if ((uptr->flags & UNIT_ATTABLE) &&
!(uptr->flags & UNIT_ATT)) return SCPE_UNATT;
unitno = uptr - dptr->units; /* recover unit# */
if ((r = dptr->boot (unitno, dptr)) != SCPE_OK) return r; }
if (*cptr != 0) return SCPE_2MARG; /* now eol? */
if ((flag == RU_RUN) || (flag == RU_BOOT)) { /* run or boot */
sim_interval = 0; /* reset queue */
sim_time = sim_rtime = 0;
noqueue_time = 0;
sim_clock_queue = NULL;
if ((r = reset_all (0)) != SCPE_OK) return r; }
for (i = 1; (dptr = sim_devices[i]) != NULL; i++) {
for (j = 0; j < dptr->numunits; j++) {
uptr = dptr->units + j;
if ((uptr->flags & (UNIT_ATT + UNIT_SEQ)) ==
(UNIT_ATT + UNIT_SEQ))
fseek_ext (uptr->fileref, uptr->pos, SEEK_SET); } }
stop_cpu = 0;
if (signal (SIGINT, int_handler) == SIG_ERR) { /* set WRU */
return SCPE_SIGERR; }
if (ttrunstate () != SCPE_OK) { /* set console mode */
ttcmdstate ();
return SCPE_TTYERR; }
if ((r = sim_check_console (30)) != SCPE_OK) { /* check console, error? */
ttcmdstate ();
return r; }
if (step) sim_activate (&step_unit, step); /* set step timer */
sim_is_running = 1; /* flag running */
sim_brk_clract (); /* defang actions */
r = sim_instr();
sim_is_running = 0; /* flag idle */
ttcmdstate (); /* restore console */
signal (SIGINT, SIG_DFL); /* cancel WRU */
sim_cancel (&step_unit); /* cancel step timer */
if (sim_clock_queue != NULL) { /* update sim time */
UPDATE_SIM_TIME (sim_clock_queue->time); }
else { UPDATE_SIM_TIME (noqueue_time); }
#if defined (VMS)
printf ("\n");
#endif
fprint_stopped (stdout, r); /* print msg */
if (sim_log) fprint_stopped (sim_log, r); /* log if enabled */
return SCPE_OK;
}
/* Print stopped message */
void fprint_stopped (FILE *stream, t_stat v)
{
int32 i;
t_stat r;
t_addr k;
t_value pcval;
DEVICE *dptr;
if (v >= SCPE_BASE) fprintf (stream, "\n%s, %s: ",
scp_error_messages[v - SCPE_BASE], sim_PC->name);
else fprintf (stream, "\n%s, %s: ", sim_stop_messages[v], sim_PC->name);
pcval = get_rval (sim_PC, 0);
fprint_val (stream, pcval, sim_PC->radix, sim_PC->width,
sim_PC->flags & REG_FMT);
if (((dptr = sim_devices[0]) != NULL) && (dptr->examine != NULL)) {
for (i = 0; i < sim_emax; i++) sim_eval[i] = 0;
for (i = 0, k = (t_addr) pcval; i < sim_emax; i++, k = k + dptr->aincr) {
if ((r = dptr->examine (&sim_eval[i], k, dptr->units,
SWMASK ('V'))) != SCPE_OK) break; }
if ((r == SCPE_OK) || (i > 0)) {
fprintf (stream, " (");
if (fprint_sym (stream, (t_addr) pcval, sim_eval, NULL, SWMASK('M')) > 0)
fprint_val (stream, sim_eval[0], dptr->dradix,
dptr->dwidth, PV_RZRO);
fprintf (stream, ")"); } }
fprintf (stream, "\n");
return;
}
/* Unit service for step timeout, originally scheduled by STEP n command
Return step timeout SCP code, will cause simulation to stop
*/
t_stat step_svc (UNIT *uptr)
{
return SCPE_STEP;
}
/* Signal handler for ^C signal
Set stop simulation flag
*/
void int_handler (int sig)
{
stop_cpu = 1;
return;
}
/* Examine/deposit commands
ex[amine] [modifiers] list examine
de[posit] [modifiers] list val deposit
ie[xamine] [modifiers] list interactive examine
id[eposit] [modifiers] list interactive deposit
modifiers
@filename output file
-letter(s) switches
devname'n device name and unit number
[{&|^}value]{=|==|!|!=|>|>=|<|<=} value search specification
list list of addresses and registers
addr[:addr|-addr] address range
ALL all addresses
register[:register|-register] register range
STATE all registers
*/
t_stat exdep_cmd (int32 flag, char *cptr)
{
char gbuf[CBUFSIZE], *gptr, *tptr;
int32 t;
t_bool exd2f;
t_addr low, high;
t_stat reason;
DEVICE *dptr, *tdptr;
UNIT *uptr, *tuptr;
REG *lowr, *highr;
SCHTAB stab, *schptr;
FILE *ofile;
ofile = NULL; /* no output file */
exd2f = FALSE;
sim_switches = 0; /* no switches */
schptr = NULL; /* no search */
stab.logic = SCH_OR; /* default search params */
stab.bool = SCH_GE;
stab.mask = stab.comp = 0;
dptr = sim_devices[0]; /* default device, unit */
uptr = dptr->units;
for (;;) { /* loop through modifiers */
if (*cptr == 0) return SCPE_2FARG; /* must be more */
if (*cptr == '@') { /* output file spec? */
if (flag != EX_E) return SCPE_ARG; /* examine only */
if (exd2f) { /* already got one? */
fclose (ofile); /* one per customer */
return SCPE_ARG; }
cptr = get_glyph_nc (cptr + 1, gbuf, 0);
ofile = FOPEN (gbuf, "a"); /* open for append */
if (ofile == NULL) return SCPE_OPENERR;
exd2f = TRUE;
continue; } /* look for more */
cptr = get_glyph (cptr, gbuf, 0);
if ((t = get_switches (gbuf)) != 0) { /* try for switches */
if (t < 0) return SCPE_INVSW; /* err if bad switch */
sim_switches = sim_switches | t; } /* or in new switches */
else if (get_search (gbuf, dptr, &stab) != NULL) { /* try for search */
schptr = &stab; } /* set search */
else if (((tdptr = find_unit (gbuf, &tuptr)) != NULL) &&
(tuptr != NULL)) { /* try for unit */
dptr = tdptr; /* set as default */
uptr = tuptr; }
else break; } /* not rec, break out */
if (uptr == NULL) return SCPE_NXUN; /* got a unit? */
if ((*cptr == 0) == (flag == 0)) return SCPE_ARG; /* eol if needed? */
if (ofile == NULL) ofile = stdout; /* no file? stdout */
for (gptr = gbuf, reason = SCPE_OK;
(*gptr != 0) && (reason == SCPE_OK); gptr = tptr) {
tdptr = dptr; /* working dptr */
if (strncmp (gptr, "STATE", strlen ("STATE")) == 0) {
tptr = gptr + strlen ("STATE");
if (*tptr && (*tptr++ != ',')) return SCPE_ARG;
if ((lowr = dptr->registers) == NULL) return SCPE_NXREG;
for (highr = lowr; highr->name != NULL; highr++) ;
sim_switches = sim_switches | SIM_SW_HIDE;
reason = exdep_reg_loop (ofile, schptr, flag, cptr,
lowr, --highr, 0, 0);
continue; }
if ((lowr = find_reg (gptr, &tptr, tdptr)) ||
(lowr = find_reg_glob (gptr, &tptr, &tdptr))) {
low = high = 0;
if ((*tptr == '-') || (*tptr == ':')) {
highr = find_reg (tptr + 1, &tptr, tdptr);
if (highr == NULL) return SCPE_NXREG; }
else {
highr = lowr;
if (*tptr == '[') {
if (lowr->depth <= 1) return SCPE_ARG;
tptr = get_range (tptr + 1, &low, &high,
10, lowr->depth - 1, ']');
if (tptr == NULL) return SCPE_ARG; } }
if (*tptr && (*tptr++ != ',')) return SCPE_ARG;
reason = exdep_reg_loop (ofile, schptr, flag, cptr,
lowr, highr, (uint32) low, (uint32) high);
continue; }
tptr = get_range (gptr, &low, &high, dptr->aradix,
(((uptr->capac == 0) || (flag == EX_E))? 0:
uptr->capac - dptr->aincr), 0);
if (tptr == NULL) return SCPE_ARG;
if (*tptr && (*tptr++ != ',')) return SCPE_ARG;
reason = exdep_addr_loop (ofile, schptr, flag, cptr, low, high,
dptr, uptr);
} /* end for */
if (exd2f) fclose (ofile); /* close output file */
return reason;
}
/* Loop controllers for examine/deposit
exdep_reg_loop examine/deposit range of registers
exdep_addr_loop examine/deposit range of addresses
*/
t_stat exdep_reg_loop (FILE *ofile, SCHTAB *schptr, int32 flag, char *cptr,
REG *lowr, REG *highr, uint32 lows, uint32 highs)
{
t_stat reason;
uint32 idx;
t_value val;
REG *rptr;
if ((lowr == NULL) || (highr == NULL)) return SCPE_IERR;
if (lowr > highr) return SCPE_ARG;
for (rptr = lowr; rptr <= highr; rptr++) {
if ((sim_switches & SIM_SW_HIDE) &&
(rptr->flags & REG_HIDDEN)) continue;
for (idx = lows; idx <= highs; idx++) {
if (idx >= rptr->depth) return SCPE_SUB;
val = get_rval (rptr, idx);
if (schptr && !test_search (val, schptr)) continue;
if (flag != EX_D) {
reason = ex_reg (ofile, val, flag, rptr, idx);
if (reason != SCPE_OK) return reason;
if (sim_log && (ofile == stdout))
ex_reg (sim_log, val, flag, rptr, idx); }
if (flag != EX_E) {
reason = dep_reg (flag, cptr, rptr, idx);
if (reason != SCPE_OK) return reason; } } }
return SCPE_OK;
}
t_stat exdep_addr_loop (FILE *ofile, SCHTAB *schptr, int32 flag, char *cptr,
t_addr low, t_addr high, DEVICE *dptr, UNIT *uptr)
{
t_addr i, mask;
t_stat reason;
if (uptr->flags & UNIT_DIS) return SCPE_UDIS; /* disabled? */
mask = (t_addr) width_mask[dptr->awidth];
if ((low > mask) || (high > mask) || (low > high)) return SCPE_ARG;
for (i = low; i <= high; i = i + (dptr->aincr)) {
reason = get_aval (i, dptr, uptr); /* get data */
if (reason != SCPE_OK) return reason; /* return if error */
if (schptr && !test_search (sim_eval[0], schptr)) continue;
if (flag != EX_D) {
reason = ex_addr (ofile, flag, i, dptr, uptr);
if (reason > SCPE_OK) return reason;
if (sim_log && (ofile == stdout))
ex_addr (sim_log, flag, i, dptr, uptr); }
if (flag != EX_E) {
reason = dep_addr (flag, cptr, i, dptr, uptr, reason);
if (reason > SCPE_OK) return reason; }
if (reason < SCPE_OK) i = i + ((-reason) * dptr->aincr); }
return SCPE_OK;
}
/* Examine register routine
Inputs:
ofile = output stream
val = current register value
flag = type of ex/mod command (ex, iex, idep)
rptr = pointer to register descriptor
idx = index
Outputs:
return = error status
*/
t_stat ex_reg (FILE *ofile, t_value val, int32 flag, REG *rptr, uint32 idx)
{
int32 rdx;
if (rptr == NULL) return SCPE_IERR;
if (rptr->depth > 1) fprintf (ofile, "%s[%d]: ", rptr->name, idx);
else fprintf (ofile, "%s: ", rptr->name);
if (!(flag & EX_E)) return SCPE_OK;
GET_RADIX (rdx, rptr->radix);
if (rptr->flags & REG_VMIO)
fprint_sym (ofile, rdx, &val, NULL, REG_VMIO);
else fprint_val (ofile, val, rdx, rptr->width, rptr->flags & REG_FMT);
if (flag & EX_I) fprintf (ofile, " ");
else fprintf (ofile, "\n");
return SCPE_OK;
}
/* Get register value
Inputs:
rptr = pointer to register descriptor
idx = index
Outputs:
return = register value
*/
t_value get_rval (REG *rptr, uint32 idx)
{
size_t sz;
t_value val;
UNIT *uptr;
sz = SZ_R (rptr);
if ((rptr->depth > 1) && (rptr->flags & REG_CIRC)) {
idx = idx + rptr->qptr;
if (idx >= rptr->depth) idx = idx - rptr->depth; }
if ((rptr->depth > 1) && (rptr->flags & REG_UNIT)) {
uptr = ((UNIT *) rptr->loc) + idx;
#if defined (t_int64)
if (sz <= sizeof (uint32)) val = *((uint32 *) uptr);
else val = *((t_uint64 *) uptr); }
#else
val = *((uint32 *) uptr); }
#endif
else if ((rptr->depth > 1) && (sz == sizeof (uint8)))
val = *(((uint8 *) rptr->loc) + idx);
else if ((rptr->depth > 1) && (sz == sizeof (uint16)))
val = *(((uint16 *) rptr->loc) + idx);
#if defined (t_int64)
else if (sz <= sizeof (uint32))
val = *(((uint32 *) rptr->loc) + idx);
else val = *(((t_uint64 *) rptr->loc) + idx);
#else
else val = *(((uint32 *) rptr->loc) + idx);
#endif
val = (val >> rptr->offset) & width_mask[rptr->width];
return val;
}
/* Deposit register routine
Inputs:
flag = type of deposit (normal/interactive)
cptr = pointer to input string
rptr = pointer to register descriptor
idx = index
Outputs:
return = error status
*/
t_stat dep_reg (int32 flag, char *cptr, REG *rptr, uint32 idx)
{
t_stat r;
t_value val, mask;
int32 rdx;
char gbuf[CBUFSIZE];
if ((cptr == NULL) || (rptr == NULL)) return SCPE_IERR;
if (rptr->flags & REG_RO) return SCPE_RO;
if (flag & EX_I) {
cptr = read_line (gbuf, CBUFSIZE, stdin);
if (sim_log) fprintf (sim_log, (cptr? "%s\n": "\n"), cptr);
if (cptr == NULL) return 1; /* force exit */
if (*cptr == 0) return SCPE_OK; } /* success */
mask = width_mask[rptr->width];
GET_RADIX (rdx, rptr->radix);
if (rptr->flags & REG_VMIO)
r = parse_sym (cptr, rdx, NULL, &val, REG_VMIO);
else val = get_uint (cptr, rdx, mask, &r);
if (r != SCPE_OK) return SCPE_ARG;
if ((rptr->flags & REG_NZ) && (val == 0)) return SCPE_ARG;
put_rval (rptr, idx, val);
return SCPE_OK;
}
/* Put register value
Inputs:
rptr = pointer to register descriptor
idx = index
val = new value
mask = mask
Outputs:
none
*/
void put_rval (REG *rptr, uint32 idx, t_value val)
{
size_t sz;
t_value mask;
UNIT *uptr;
#define PUT_RVAL(sz,rp,id,v,m) \
*(((sz *) rp->loc) + id) = \
(*(((sz *) rp->loc) + id) & \
~((m) << (rp)->offset)) | ((v) << (rp)->offset)
if (rptr == sim_PC) sim_brk_npc ();
sz = SZ_R (rptr);
mask = width_mask[rptr->width];
if ((rptr->depth > 1) && (rptr->flags & REG_CIRC)) {
idx = idx + rptr->qptr;
if (idx >= rptr->depth) idx = idx - rptr->depth; }
if ((rptr->depth > 1) && (rptr->flags & REG_UNIT)) {
uptr = ((UNIT *) rptr->loc) + idx;
#if defined (t_int64)
if (sz <= sizeof (uint32))
*((uint32 *) uptr) = (*((uint32 *) uptr) &
~(((uint32) mask) << rptr->offset)) |
(((uint32) val) << rptr->offset);
else *((t_uint64 *) uptr) = (*((t_uint64 *) uptr)
& ~(mask << rptr->offset)) | (val << rptr->offset); }
#else
*((uint32 *) uptr) = (*((uint32 *) uptr) &
~(((uint32) mask) << rptr->offset)) |
(((uint32) val) << rptr->offset); }
#endif
else if ((rptr->depth > 1) && (sz == sizeof (uint8)))
PUT_RVAL (uint8, rptr, idx, (uint32) val, (uint32) mask);
else if ((rptr->depth > 1) && (sz == sizeof (uint16)))
PUT_RVAL (uint16, rptr, idx, (uint32) val, (uint32) mask);
#if defined (t_int64)
else if (sz <= sizeof (uint32))
PUT_RVAL (uint32, rptr, idx, (int32) val, (uint32) mask);
else PUT_RVAL (t_uint64, rptr, idx, val, mask);
#else
else PUT_RVAL (uint32, rptr, idx, val, mask);
#endif
return;
}
/* Examine address routine
Inputs: (sim_eval is an implicit argument)
ofile = output stream
flag = type of ex/mod command (ex, iex, idep)
addr = address to examine
dptr = pointer to device
uptr = pointer to unit
Outputs:
return = if >= 0, error status
if < 0, number of extra words retired
*/
t_stat ex_addr (FILE *ofile, int32 flag, t_addr addr, DEVICE *dptr, UNIT *uptr)
{
t_stat reason;
int32 rdx;
fprint_val (ofile, addr, dptr->aradix, dptr->awidth, PV_LEFT);
fprintf (ofile, ": ");
if (!(flag & EX_E)) return SCPE_OK;
GET_RADIX (rdx, dptr->dradix);
if ((reason = fprint_sym (ofile, addr, sim_eval, uptr, sim_switches)) > 0)
reason = fprint_val (ofile, sim_eval[0], rdx, dptr->dwidth, PV_RZRO);
if (flag & EX_I) fprintf (ofile, " ");
else fprintf (ofile, "\n");
return reason;
}
/* Get address routine
Inputs:
flag = type of ex/mod command (ex, iex, idep)
addr = address to examine
dptr = pointer to device
uptr = pointer to unit
Outputs: (sim_eval is an implicit output)
return = error status
*/
t_stat get_aval (t_addr addr, DEVICE *dptr, UNIT *uptr)
{
int32 i;
t_value mask;
t_addr j, loc;
size_t sz;
t_stat reason = SCPE_OK;
if ((dptr == NULL) || (uptr == NULL)) return SCPE_IERR;
mask = width_mask[dptr->dwidth];
for (i = 0; i < sim_emax; i++) sim_eval[i] = 0;
for (i = 0, j = addr; i < sim_emax; i++, j = j + dptr->aincr) {
if (dptr->examine != NULL) {
reason = dptr->examine (&sim_eval[i], j, uptr, sim_switches);
if (reason != SCPE_OK) break; }
else {
if (!(uptr->flags & UNIT_ATT)) return SCPE_UNATT;
if ((uptr->flags & UNIT_FIX) && (j >= uptr->capac)) {
reason = SCPE_NXM;
break; }
sz = SZ_D (dptr);
loc = j / dptr->aincr;
if (uptr->flags & UNIT_BUF) {
SZ_LOAD (sz, sim_eval[i], uptr->filebuf, loc); }
else {
fseek_ext (uptr->fileref, sz * loc, SEEK_SET);
fxread (&sim_eval[i], sz, 1, uptr->fileref);
if ((feof (uptr->fileref)) &&
!(uptr->flags & UNIT_FIX)) {
reason = SCPE_EOF;
break; }
else if (ferror (uptr->fileref)) {
clearerr (uptr->fileref);
reason = SCPE_IOERR;
break; } } }
sim_eval[i] = sim_eval[i] & mask; }
if ((reason != SCPE_OK) && (i == 0)) return reason;
return SCPE_OK;
}
/* Deposit address routine
Inputs:
flag = type of deposit (normal/interactive)
cptr = pointer to input string
addr = address to examine
dptr = pointer to device
uptr = pointer to unit
dfltinc = value to return on cr input
Outputs:
return = if >= 0, error status
if < 0, number of extra words retired
*/
t_stat dep_addr (int32 flag, char *cptr, t_addr addr, DEVICE *dptr,
UNIT *uptr, int32 dfltinc)
{
int32 i, count, rdx;
t_addr j, loc;
t_stat r, reason;
t_value mask;
size_t sz;
char gbuf[CBUFSIZE];
if (dptr == NULL) return SCPE_IERR;
if (flag & EX_I) {
cptr = read_line (gbuf, CBUFSIZE, stdin);
if (sim_log) fprintf (sim_log, (cptr? "%s\n": "\n"), cptr);
if (cptr == NULL) return 1; /* force exit */
if (*cptr == 0) return dfltinc; } /* success */
if (uptr->flags & UNIT_RO) return SCPE_RO; /* read only? */
mask = width_mask[dptr->dwidth];
GET_RADIX (rdx, dptr->dradix);
if ((reason = parse_sym (cptr, addr, uptr, sim_eval, sim_switches)) > 0) {
sim_eval[0] = get_uint (cptr, rdx, mask, &reason);
if (reason != SCPE_OK) return reason; }
count = 1 - reason;
for (i = 0, j = addr; i < count; i++, j = j + dptr->aincr) {
sim_eval[i] = sim_eval[i] & mask;
if (dptr->deposit != NULL) {
r = dptr->deposit (sim_eval[i], j, uptr, sim_switches);
if (r != SCPE_OK) return r; }
else {
if (!(uptr->flags & UNIT_ATT)) return SCPE_UNATT;
if ((uptr->flags & UNIT_FIX) && (j >= uptr->capac))
return SCPE_NXM;
sz = SZ_D (dptr);
loc = j / dptr->aincr;
if (uptr->flags & UNIT_BUF) {
SZ_STORE (sz, sim_eval[i], uptr->filebuf, loc);
if (loc >= uptr->hwmark) uptr->hwmark = (uint32) loc + 1; }
else {
fseek_ext (uptr->fileref, sz * loc, SEEK_SET);
fxwrite (&sim_eval[i], sz, 1, uptr->fileref);
if (ferror (uptr->fileref)) {
clearerr (uptr->fileref);
return SCPE_IOERR; } } } }
return reason;
}
/* Evaluate command */
t_stat eval_cmd (int32 flg, char *cptr)
{
DEVICE *dptr = sim_devices[0];
int32 i, count, rdx;
t_stat r;
GET_SWITCHES (cptr);
GET_RADIX (rdx, dptr->dradix);
for (i = 0; i < sim_emax; i++) sim_eval[i] = 0;
if (*cptr == 0) return SCPE_2FARG;
if ((r = parse_sym (cptr, 0, dptr->units, sim_eval, sim_switches)) > 0) {
sim_eval[0] = get_uint (cptr, rdx, width_mask[dptr->dwidth], &r);
if (r != SCPE_OK) return r; }
count = 1 - r;
for (i = 0; count > 0; i++, count = count - dptr->aincr) {
printf ("%d:\t", i);
if ((r = fprint_sym (stdout, 0, &sim_eval[i], dptr->units, sim_switches)) > 0)
r = fprint_val (stdout, sim_eval[i], rdx, dptr->dwidth, PV_RZRO);
printf ("\n");
if (sim_log) {
fprintf (sim_log, "%d\t", i);
if ((r = fprint_sym (sim_log, 0, &sim_eval[i], dptr->units, sim_switches)) > 0)
r = fprint_val (sim_log, sim_eval[i], rdx, dptr->dwidth, PV_RZRO);
fprintf (sim_log, "\n"); }
if (r < 0) {
i = i - r;
count = count + (r * dptr->aincr); }
}
return SCPE_OK;
}
/* String processing routines
read_line read line
Inputs:
cptr = pointer to buffer
size = maximum size
stream = pointer to input stream
Outputs:
optr = pointer to first non-blank character
NULL if EOF
*/
char *read_line (char *cptr, int32 size, FILE *stream)
{
char *tptr;
cptr = fgets (cptr, size, stream); /* get cmd line */
if (cptr == NULL) {
clearerr (stream); /* clear error */
return NULL; } /* ignore EOF */
for (tptr = cptr; tptr < (cptr + size); tptr++) /* remove cr or nl */
if ((*tptr == '\n') || (*tptr == '\r')) *tptr = 0;
while (isspace (*cptr)) cptr++; /* absorb spaces */
if (*cptr == ';') *cptr = 0; /* ignore comment */
return cptr;
}
/* get_glyph get next glyph (force upper case)
get_glyph_nc get next glyph (no conversion)
get_glyph_gen get next glyph (general case)
Inputs:
iptr = pointer to input string
optr = pointer to output string
mchar = optional end of glyph character
flag = TRUE for convert to upper case (_gen only)
Outputs
result = pointer to next character in input string
*/
char *get_glyph_gen (char *iptr, char *optr, char mchar, t_bool uc)
{
while ((isspace (*iptr) == 0) && (*iptr != 0) && (*iptr != mchar)) {
if (islower (*iptr) && uc) *optr = toupper (*iptr);
else *optr = *iptr;
iptr++; optr++; }
*optr = 0;
if (mchar && (*iptr == mchar)) iptr++; /* skip terminator */
while (isspace (*iptr)) iptr++; /* absorb spaces */
return iptr;
}
char *get_glyph (char *iptr, char *optr, char mchar)
{
return get_glyph_gen (iptr, optr, mchar, TRUE);
}
char *get_glyph_nc (char *iptr, char *optr, char mchar)
{
return get_glyph_gen (iptr, optr, mchar, FALSE);
}
/* get_yn yes/no question
Inputs:
cptr = pointer to question
deflt = default answer
Outputs:
result = true if yes, false if no
*/
t_stat get_yn (char *ques, t_stat deflt)
{
char cbuf[CBUFSIZE], *cptr;
printf ("%s ", ques);
cptr = read_line (cbuf, CBUFSIZE, stdin);
if ((cptr == NULL) || (*cptr == 0)) return deflt;
if ((*cptr == 'Y') || (*cptr == 'y')) return TRUE;
return FALSE;
}
/* get_uint unsigned number
Inputs:
cptr = pointer to input string
radix = input radix
max = maximum acceptable value
*status = pointer to error status
Outputs:
val = value
*/
t_value get_uint (char *cptr, uint32 radix, t_value max, t_stat *status)
{
t_value val;
char *tptr;
val = strtotv (cptr, &tptr, radix);
if ((cptr == tptr) || (val > max) || (*tptr != 0)) *status = SCPE_ARG;
else *status = SCPE_OK;
return val;
}
/* get_range range specification
Inputs:
cptr = pointer to input string
*lo = pointer to low result
*hi = pointer to high result
aradix = address radix
max = default high value
term = terminating character, 0 if none
Outputs:
tptr = input pointer after processing
NULL if error
*/
char *get_range (char *cptr, t_addr *lo, t_addr *hi, uint32 rdx,
t_addr max, char term)
{
char *tptr;
t_addr hb;
*lo = *hi = hb = 0;
if (max && strncmp (cptr, "ALL", strlen ("ALL")) == 0) { /* ALL? */
tptr = cptr + strlen ("ALL");
*hi = max; }
else { *lo = (t_addr) strtotv (cptr, &tptr, rdx); /* get low */
if (cptr == tptr) return NULL; /* error? */
if ((*tptr == '-') || (*tptr == ':') || (*tptr == '/')) {
if (*tptr == '/') hb = *lo; /* relative? */
cptr = tptr + 1;
*hi = hb + (t_addr) strtotv (cptr, &tptr, rdx); /* get high */
if (cptr == tptr) return NULL;
if (*lo > *hi) return NULL; }
else *hi = *lo; }
if (term && (*tptr++ != term)) return NULL;
return tptr;
}
/* get_ipaddr IP address:port
Inputs:
cptr = pointer to input string
Outputs:
ipa = pointer to IP address (may be NULL), 0 = none
ipp = pointer to IP port (may be NULL)
result = status
*/
t_stat get_ipaddr (char *cptr, uint32 *ipa, uint32 *ipp)
{
char gbuf[CBUFSIZE];
char *addrp, *portp, *octetp;
uint32 i, addr, port, octet;
t_stat r;
if ((cptr == NULL) || (*cptr == 0) || (ipa == NULL) || (ipp == NULL))
return SCPE_ARG;
strncpy (gbuf, cptr, CBUFSIZE);
addrp = gbuf; /* default addr */
if (portp = strchr (gbuf, ':')) *portp++ = '.'; /* x:y? */
else if (strchr (gbuf, '.')) portp = NULL; /* x.y...? */
else { portp = gbuf; /* port only */
addrp = NULL; } /* x is port */
if (portp) { /* port string? */
port = (int32) get_uint (portp, 10, 65535, &r);
if ((r != SCPE_OK) || (port == 0)) return SCPE_ARG;
*ipp = port; }
else *ipp = 0;
if (addrp) {
for (i = addr = 0; i < 4; i++) {
octetp = strchr (addrp, '.');
if (octetp == NULL) return SCPE_ARG;
*octetp++ = 0;
octet = (int32) get_uint (addrp, 10, 255, &r);
if (r != SCPE_OK) return SCPE_ARG;
addr = (addr << 8) | octet;
addrp = octetp; }
if (((addr & 0377) == 0) || ((addr & 0377) == 255))
return SCPE_ARG;
*ipa = addr; }
else *ipa = 0;
return SCPE_OK;
}
/* Find_device find device matching input string
Inputs:
cptr = pointer to input string
Outputs:
result = pointer to device
*/
DEVICE *find_dev (char *cptr)
{
int32 i;
DEVICE *dptr;
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) {
if ((strcmp (cptr, dptr->name) == 0) ||
(dptr->lname &&
(strcmp (cptr, dptr->lname) == 0))) return dptr; }
return NULL;
}
/* Find_unit find unit matching input string
Inputs:
cptr = pointer to input string
uptr = pointer to unit pointer
Outputs:
result = pointer to device (null if no dev)
*iptr = pointer to unit (null if nx unit)
*/
DEVICE *find_unit (char *cptr, UNIT **uptr)
{
uint32 i, u;
char *nptr, *tptr;
t_stat r;
DEVICE *dptr;
if (uptr == NULL) return NULL; /* arg error? */
if (dptr = find_dev (cptr)) { /* exact match? */
if (qdisable (dptr)) return NULL; /* disabled? */
*uptr = dptr->units; /* unit 0 */
return dptr; }
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) { /* base + unit#? */
if (dptr->numunits && /* any units? */
(((nptr = dptr->name) &&
(strncmp (cptr, nptr, strlen (nptr)) == 0)) ||
((nptr = dptr->lname) &&
(strncmp (cptr, nptr, strlen (nptr)) == 0)))) {
tptr = cptr + strlen (nptr);
if (isdigit (*tptr)) {
if (qdisable (dptr)) return NULL; /* disabled? */
u = (uint32) get_uint (tptr, 10, dptr->numunits - 1, &r);
if (r != SCPE_OK) *uptr = NULL; /* error? */
else *uptr = dptr->units + u;
return dptr; } } }
return NULL;
}
/* Find_dev_from_unit find device for unit
Inputs:
uptr = pointer to unit
Outputs:
result = pointer to device
*/
DEVICE *find_dev_from_unit (UNIT *uptr)
{
DEVICE *dptr;
uint32 i, j;
if (uptr == NULL) return NULL;
for (i = 0; (dptr = sim_devices[i]) != NULL; i++) {
for (j = 0; j < dptr->numunits; j++) {
if (uptr == (dptr->units + j)) return dptr; } }
return NULL;
}
/* Test for disabled device */
t_bool qdisable (DEVICE *dptr)
{
return (dptr->flags & DEV_DIS? TRUE: FALSE);
}
/* find_reg_glob find globally unique register
Inputs:
cptr = pointer to input string
optr = pointer to output pointer (can be null)
gdptr = pointer to global device
Outputs:
result = pointer to register, NULL if error
*optr = pointer to next character in input string
*gdptr = pointer to device where found
*/
REG *find_reg_glob (char *cptr, char **optr, DEVICE **gdptr)
{
int32 i;
DEVICE *dptr;
REG *rptr, *srptr = NULL;
for (i = 0; (dptr = sim_devices[i]) != 0; i++) { /* all dev */
if (rptr = find_reg (cptr, optr, dptr)) { /* found? */
if (srptr) return NULL; /* ambig? err */
srptr = rptr; /* save reg */
*gdptr = dptr; } } /* save unit */
return srptr;
}
/* find_reg find register matching input string
Inputs:
cptr = pointer to input string
optr = pointer to output pointer (can be null)
dptr = pointer to device
Outputs:
result = pointer to register, NULL if error
*optr = pointer to next character in input string
*/
REG *find_reg (char *cptr, char **optr, DEVICE *dptr)
{
char *tptr;
REG *rptr;
uint32 slnt;
if ((cptr == NULL) || (dptr == NULL) ||
(dptr->registers == NULL)) return NULL;
tptr = cptr;
do { tptr++; }
while (isalnum (*tptr) || (*tptr == '*') || (*tptr == '_'));
slnt = tptr - cptr;
for (rptr = dptr->registers; rptr->name != NULL; rptr++) {
if ((slnt == strlen (rptr->name)) &&
(strncmp (cptr, rptr->name, slnt) == 0)) {
if (optr != NULL) *optr = tptr;
return rptr; } }
return NULL;
}
/* get_switches get switches from input string
Inputs:
cptr = pointer to input string
Outputs:
sw = switch bit mask
0 if no switches, -1 if error
*/
int32 get_switches (char *cptr)
{
int32 sw;
if (*cptr != '-') return 0;
sw = 0;
for (cptr++; (isspace (*cptr) == 0) && (*cptr != 0); cptr++) {
if (isalpha (*cptr) == 0) return -1;
sw = sw | SWMASK (toupper (*cptr)); }
return sw;
}
/* get_sim_sw accumulate sim_switches
Inputs:
cptr = pointer to input string
Outputs:
ptr = pointer to first non-string glyph
NULL if error
*/
char *get_sim_sw (char *cptr)
{
int32 lsw;
char gbuf[CBUFSIZE];
while (*cptr == '-') { /* while switches */
cptr = get_glyph (cptr, gbuf, 0); /* get switch glyph */
lsw = get_switches (gbuf); /* parse */
if (lsw <= 0) return NULL; /* invalid? */
sim_switches = sim_switches | lsw; } /* accumulate */
return cptr;
}
/* Match file extension
Inputs:
fnam = file name
ext = extension, without period
Outputs:
cp = pointer to final '.' if match, NULL if not
*/
char *match_ext (char *fnam, char *ext)
{
char *pptr, *fptr, *eptr;
if ((fnam == NULL) || (ext == NULL)) return NULL;
pptr = strrchr (fnam, '.');
if (pptr) {
for (fptr = pptr + 1, eptr = ext; *fptr; fptr++, eptr++) {
if (toupper (*fptr) != toupper (*eptr)) return NULL; }
if (*eptr) return NULL; }
return pptr;
}
/* Get search specification
Inputs:
cptr = pointer to input string
dptr = pointer to device
schptr = pointer to search table
Outputs:
return = NULL if error
schptr if valid search specification
*/
SCHTAB *get_search (char *cptr, DEVICE *dptr, SCHTAB *schptr)
{
int32 c, logop, cmpop;
t_value logval, cmpval;
char *sptr, *tptr;
const char logstr[] = "|&^", cmpstr[] = "=!><";
if (*cptr == 0) return NULL; /* check for clause */
for (logop = cmpop = -1; c = *cptr++; ) { /* loop thru clauses */
if (sptr = strchr (logstr, c)) { /* check for mask */
logop = sptr - logstr;
logval = strtotv (cptr, &tptr, dptr->dradix);
if (cptr == tptr) return NULL;
cptr = tptr; }
else if (sptr = strchr (cmpstr, c)) { /* check for bool */
cmpop = sptr - cmpstr;
if (*cptr == '=') {
cmpop = cmpop + strlen (cmpstr);
cptr++; }
cmpval = strtotv (cptr, &tptr, dptr->dradix);
if (cptr == tptr) return NULL;
cptr = tptr; }
else return NULL; } /* end while */
if (logop >= 0) {
schptr->logic = logop;
schptr->mask = logval; }
if (cmpop >= 0) {
schptr->bool = cmpop;
schptr->comp = cmpval; }
return schptr;
}
/* Test value against search specification
Inputs:
val = value to test
schptr = pointer to search table
Outputs:
return = 1 if value passes search criteria, 0 if not
*/
int32 test_search (t_value val, SCHTAB *schptr)
{
if (schptr == NULL) return 0;
switch (schptr->logic) { /* case on logical */
case SCH_OR:
val = val | schptr->mask;
break;
case SCH_AND:
val = val & schptr->mask;
break;
case SCH_XOR:
val = val ^ schptr->mask;
break; }
switch (schptr->bool) { /* case on comparison */
case SCH_E: case SCH_EE:
return (val == schptr->comp);
case SCH_N: case SCH_NE:
return (val != schptr->comp);
case SCH_G:
return (val > schptr->comp);
case SCH_GE:
return (val >= schptr->comp);
case SCH_L:
return (val < schptr->comp);
case SCH_LE:
return (val <= schptr->comp); }
return 0;
}
/* Radix independent input/output package
strtotv - general radix input routine
Inputs:
inptr = string to convert
endptr = pointer to first unconverted character
radix = radix for input
Outputs:
value = converted value
On an error, the endptr will equal the inptr.
*/
t_value strtotv (char *inptr, char **endptr, uint32 radix)
{
int32 nodigit;
t_value val;
uint32 c, digit;
*endptr = inptr; /* assume fails */
if ((radix < 2) || (radix > 36)) return 0;
while (isspace (*inptr)) inptr++; /* bypass white space */
val = 0;
nodigit = 1;
for (c = *inptr; isalnum(c); c = *++inptr) { /* loop through char */
if (islower (c)) c = toupper (c);
if (isdigit (c)) digit = c - (uint32) '0'; /* digit? */
else digit = c + 10 - (uint32) 'A'; /* no, letter */
if (digit >= radix) return 0; /* valid in radix? */
val = (val * radix) + digit; /* add to value */
nodigit = 0; }
if (nodigit) return 0; /* no digits? */
*endptr = inptr; /* result pointer */
return val;
}
/* fprint_val - general radix printing routine
Inputs:
stream = stream designator
val = value to print
radix = radix to print
width = width to print
format = leading zeroes format
Outputs:
status = error status
*/
t_stat fprint_val (FILE *stream, t_value val, uint32 radix,
uint32 width, uint32 format)
{
#define MAX_WIDTH ((int) (CHAR_BIT * sizeof (t_value)))
t_value owtest, wtest;
int32 d, digit, ndigits;
char dbuf[MAX_WIDTH + 1];
for (d = 0; d < MAX_WIDTH; d++) dbuf[d] = (format == PV_RZRO)? '0': ' ';
dbuf[MAX_WIDTH] = 0;
d = MAX_WIDTH;
do { d = d - 1;
digit = (int32) (val % radix);
val = val / radix;
dbuf[d] = (digit <= 9)? '0' + digit: 'A' + (digit - 10);
} while ((d > 0) && (val != 0));
if (format != PV_LEFT) {
wtest = owtest = radix;
ndigits = 1;
while ((wtest < width_mask[width]) && (wtest >= owtest)) {
owtest = wtest;
wtest = wtest * radix;
ndigits = ndigits + 1; }
if ((MAX_WIDTH - ndigits) < d) d = MAX_WIDTH - ndigits; }
if (fputs (&dbuf[d], stream) == EOF) return SCPE_IOERR;
return SCPE_OK;
}
/* Event queue package
sim_activate add entry to event queue
sim_cancel remove entry from event queue
sim_process_event process entries on event queue
sim_is_active see if entry is on event queue
sim_atime return absolute time for an entry
sim_gtime return global time
sim_qcount return event queue entry count
Asynchronous events are set up by queueing a unit data structure
to the event queue with a timeout (in simulator units, relative
to the current time). Each simulator 'times' these events by
counting down interval counter sim_interval. When this reaches
zero the simulator calls sim_process_event to process the event
and to see if further events need to be processed, or sim_interval
reset to count the next one.
The event queue is maintained in clock order; entry timeouts are
RELATIVE to the time in the previous entry.
sim_process_event - process event
Inputs:
none
Outputs:
reason reason code returned by any event processor,
or 0 (SCPE_OK) if no exceptions
*/
t_stat sim_process_event (void)
{
UNIT *uptr;
t_stat reason;
if (stop_cpu) return SCPE_STOP; /* stop CPU? */
if (sim_clock_queue == NULL) { /* queue empty? */
UPDATE_SIM_TIME (noqueue_time); /* update sim time */
sim_interval = noqueue_time = NOQUEUE_WAIT; /* flag queue empty */
return SCPE_OK; }
UPDATE_SIM_TIME (sim_clock_queue->time); /* update sim time */
do { uptr = sim_clock_queue; /* get first */
sim_clock_queue = uptr->next; /* remove first */
uptr->next = NULL; /* hygiene */
uptr->time = 0;
if (sim_clock_queue != NULL) sim_interval = sim_clock_queue->time;
else sim_interval = noqueue_time = NOQUEUE_WAIT;
if (uptr->action != NULL) reason = uptr->action (uptr);
else reason = SCPE_OK;
} while ((reason == SCPE_OK) && (sim_interval == 0));
/* Empty queue forces sim_interval != 0 */
return reason;
}
/* sim_activate - activate (queue) event
Inputs:
uptr = pointer to unit
event_time = relative timeout
Outputs:
reason = result (SCPE_OK if ok)
*/
t_stat sim_activate (UNIT *uptr, int32 event_time)
{
UNIT *cptr, *prvptr;
int32 accum;
if (event_time < 0) return SCPE_IERR;
if (sim_is_active (uptr)) return SCPE_OK; /* already active? */
if (sim_clock_queue == NULL) { UPDATE_SIM_TIME (noqueue_time); }
else { UPDATE_SIM_TIME (sim_clock_queue->time); } /* update sim time */
prvptr = NULL;
accum = 0;
for (cptr = sim_clock_queue; cptr != NULL; cptr = cptr->next) {
if (event_time < (accum + cptr->time)) break;
accum = accum + cptr->time;
prvptr = cptr; }
if (prvptr == NULL) { /* insert at head */
cptr = uptr->next = sim_clock_queue;
sim_clock_queue = uptr; }
else { cptr = uptr->next = prvptr->next; /* insert at prvptr */
prvptr->next = uptr; }
uptr->time = event_time - accum;
if (cptr != NULL) cptr->time = cptr->time - uptr->time;
sim_interval = sim_clock_queue->time;
return SCPE_OK;
}
/* sim_cancel - cancel (dequeue) event
Inputs:
uptr = pointer to unit
Outputs:
reason = result (SCPE_OK if ok)
*/
t_stat sim_cancel (UNIT *uptr)
{
UNIT *cptr, *nptr;
if (sim_clock_queue == NULL) return SCPE_OK;
UPDATE_SIM_TIME (sim_clock_queue->time); /* update sim time */
nptr = NULL;
if (sim_clock_queue == uptr) nptr = sim_clock_queue = uptr->next;
else { for (cptr = sim_clock_queue; cptr != NULL; cptr = cptr->next) {
if (cptr->next == uptr) {
nptr = cptr->next = uptr->next;
break; } } } /* end queue scan */
if (nptr != NULL) nptr->time = nptr->time + uptr->time;
uptr->next = NULL; /* hygiene */
uptr->time = 0;
if (sim_clock_queue != NULL) sim_interval = sim_clock_queue->time;
else sim_interval = noqueue_time = NOQUEUE_WAIT;
return SCPE_OK;
}
/* sim_is_active - test for entry in queue, return activation time
Inputs:
uptr = pointer to unit
Outputs:
result = absolute activation time + 1, 0 if inactive
*/
int32 sim_is_active (UNIT *uptr)
{
UNIT *cptr;
int32 accum;
accum = 0;
for (cptr = sim_clock_queue; cptr != NULL; cptr = cptr->next) {
accum = accum + cptr->time;
if (cptr == uptr) return accum + 1; }
return 0;
}
/* sim_gtime - return global time
sim_grtime - return global time with rollover
Inputs: none
Outputs:
time = global time
*/
double sim_gtime (void)
{
if (sim_clock_queue == NULL) { UPDATE_SIM_TIME (noqueue_time); }
else { UPDATE_SIM_TIME (sim_clock_queue->time); }
return sim_time;
}
uint32 sim_grtime (void)
{
if (sim_clock_queue == NULL) { UPDATE_SIM_TIME (noqueue_time); }
else { UPDATE_SIM_TIME (sim_clock_queue->time); }
return sim_rtime;
}
/* sim_qcount - return queue entry count
Inputs: none
Outputs:
count = number of entries on the queue
*/
int32 sim_qcount (void)
{
int32 cnt;
UNIT *uptr;
cnt = 0;
for (uptr = sim_clock_queue; uptr != NULL; uptr = uptr->next) cnt++;
return cnt;
}
/* Endian independent binary I/O package
For consistency, all binary data read and written by the simulator
is stored in little endian data order. That is, in a multi-byte
data item, the bytes are written out right to left, low order byte
to high order byte. On a big endian host, data is read and written
from high byte to low byte. Consequently, data written on a little
endian system must be byte reversed to be usable on a big endian
system, and vice versa.
These routines are analogs of the standard C runtime routines
fread and fwrite. If the host is little endian, or the data items
are size char, then the calls are passed directly to fread or
fwrite. Otherwise, these routines perform the necessary byte swaps
using an intermediate buffer.
*/
size_t fxread (void *bptr, size_t size, size_t count, FILE *fptr)
{
size_t c, j, nelem, nbuf, lcnt, total;
int32 i, k;
unsigned char *sptr, *dptr;
if (sim_end || (size == sizeof (char)))
return fread (bptr, size, count, fptr);
if ((size == 0) || (count == 0)) return 0;
nelem = FLIP_SIZE / size; /* elements in buffer */
nbuf = count / nelem; /* number buffers */
lcnt = count % nelem; /* count in last buf */
if (lcnt) nbuf = nbuf + 1;
else lcnt = nelem;
total = 0;
dptr = bptr; /* init output ptr */
for (i = nbuf; i > 0; i--) {
c = fread (sim_flip, size, (i == 1? lcnt: nelem), fptr);
if (c == 0) return total;
total = total + c;
for (j = 0, sptr = sim_flip; j < c; j++) {
for (k = size - 1; k >= 0; k--) *(dptr + k) = *sptr++;
dptr = dptr + size; } }
return total;
}
size_t fxwrite (void *bptr, size_t size, size_t count, FILE *fptr)
{
size_t c, j, nelem, nbuf, lcnt, total;
int32 i, k;
unsigned char *sptr, *dptr;
if (sim_end || (size == sizeof (char)))
return fwrite (bptr, size, count, fptr);
if ((size == 0) || (count == 0)) return 0;
nelem = FLIP_SIZE / size; /* elements in buffer */
nbuf = count / nelem; /* number buffers */
lcnt = count % nelem; /* count in last buf */
if (lcnt) nbuf = nbuf + 1;
else lcnt = nelem;
total = 0;
sptr = bptr; /* init input ptr */
for (i = nbuf; i > 0; i--) {
c = (i == 1)? lcnt: nelem;
for (j = 0, dptr = sim_flip; j < c; j++) {
for (k = size - 1; k >= 0; k--) *(dptr + k) = *sptr++;
dptr = dptr + size; }
c = fwrite (sim_flip, size, c, fptr);
if (c == 0) return total;
total = total + c; }
return total;
}
/* Get file size */
uint32 sim_fsize (char *cptr)
{
FILE *fp;
uint32 sz;
fp = fopen (cptr, "rb");
if (fp == NULL) return 0;
fseek (fp, 0, SEEK_END);
sz = ftell (fp);
fclose (fp);
return sz;
}
/* OS independent clock calibration package
sim_rtc_init initialize calibration
sim_rtc_calb calibrate clock
*/
static int32 rtc_ticks[SIM_NTIMERS] = { 0 }; /* ticks */
static uint32 rtc_rtime[SIM_NTIMERS] = { 0 }; /* real time */
static uint32 rtc_vtime[SIM_NTIMERS] = { 0 }; /* virtual time */
static uint32 rtc_nxintv[SIM_NTIMERS] = { 0 }; /* next interval */
static int32 rtc_based[SIM_NTIMERS] = { 0 }; /* base delay */
static int32 rtc_currd[SIM_NTIMERS] = { 0 }; /* current delay */
extern t_bool rtc_avail;
int32 sim_rtcn_init (int32 time, int32 tmr)
{
if (time == 0) time = 1;
if ((tmr < 0) || (tmr >= SIM_NTIMERS)) return time;
rtc_rtime[tmr] = sim_os_msec ();
rtc_vtime[tmr] = rtc_rtime[tmr];
rtc_nxintv[tmr] = 1000;
rtc_ticks[tmr] = 0;
rtc_based[tmr] = time;
rtc_currd[tmr] = time;
return time;
}
int32 sim_rtcn_calb (int32 ticksper, int32 tmr)
{
uint32 new_rtime, delta_rtime;
int32 delta_vtime;
if ((tmr < 0) || (tmr >= SIM_NTIMERS)) return 10000;
rtc_ticks[tmr] = rtc_ticks[tmr] + 1; /* count ticks */
if (rtc_ticks[tmr] < ticksper) return rtc_currd[tmr]; /* 1 sec yet? */
rtc_ticks[tmr] = 0; /* reset ticks */
if (!rtc_avail) return rtc_currd[tmr]; /* no timer? */
new_rtime = sim_os_msec (); /* wall time */
if (new_rtime < rtc_rtime[tmr]) { /* time running backwards? */
rtc_rtime[tmr] = new_rtime; /* reset wall time */
return rtc_currd[tmr]; } /* can't calibrate */
delta_rtime = new_rtime - rtc_rtime[tmr]; /* elapsed wtime */
rtc_rtime[tmr] = new_rtime; /* adv wall time */
if ((delta_rtime == 0) || (delta_rtime > 30000)) /* gap 0 or too big? */
return rtc_currd[tmr]; /* can't calibr */
rtc_based[tmr] = (int32) (((double) rtc_based[tmr] * (double) rtc_nxintv[tmr]) /
((double) delta_rtime)); /* new base rate */
rtc_vtime[tmr] = rtc_vtime[tmr] + 1000; /* adv sim time */
delta_vtime = rtc_vtime[tmr] - rtc_rtime[tmr]; /* gap */
if (delta_vtime > SIM_TMAX) delta_vtime = SIM_TMAX; /* limit gap */
else if (delta_vtime < -SIM_TMAX) delta_vtime = -SIM_TMAX;
rtc_nxintv[tmr] = 1000 + delta_vtime; /* next wtime */
rtc_currd[tmr] = (int32) (((double) rtc_based[tmr] * (double) rtc_nxintv[tmr]) /
1000.0); /* next delay */
if (rtc_currd[tmr] <= 0) rtc_currd[tmr] = 1; /* never negative or zero! */
return rtc_currd[tmr];
}
/* Prior interfaces - default to timer 0 */
int32 sim_rtc_init (int32 time)
{
return sim_rtcn_init (time, 0);
}
int32 sim_rtc_calb (int32 ticksper)
{
return sim_rtcn_calb (ticksper, 0);
}
/* Breakpoint package. This module replaces the VM-implemented one
instruction breakpoint capability.
Breakpoints are stored in table sim_brk_tab, which is ordered by address for
efficient binary searching. A breakpoint consists of a four entry structure:
addr address of the breakpoint
type types of breakpoints set on the address
a bit mask representing letters A-Z
cnt number of iterations before breakp is taken
action pointer command string to be executed
when break is taken
sim_brk_summ is a summary of the types of breakpoints that are currently set (it
is the bitwise OR of all the type fields). A simulator need only check for
a breakpoint of type X if bit SWMASK('X') is set in sim_brk_sum.
The package contains the following public routines:
sim_brk_init initialize
sim_brk_set set breakpoint
sim_brk_clr clear breakpoint
sim_brk_clrall clear all breakpoints
sim_brk_show show breakpoint
sim_brk_showall show all breakpoints
sim_brk_test test for breakpoint
sim_brk_npc PC has been changed
sim_brk_getact get next action
sim_brk_clract clear pending actions
Initialize breakpoint system.
*/
t_stat sim_brk_init (void)
{
sim_brk_lnt = SIM_BRK_INILNT;
sim_brk_tab = calloc (sim_brk_lnt, sizeof (BRKTAB));
if (sim_brk_tab == NULL) return SCPE_MEM;
sim_brk_ent = sim_brk_ins = 0;
sim_brk_pend = FALSE;
sim_brk_act = NULL;
return SCPE_OK;
}
/* Search for a breakpoint in the sorted breakpoint table */
BRKTAB *sim_brk_fnd (t_addr loc)
{
int32 lo, hi, p;
BRKTAB *bp;
if (sim_brk_ent == 0) { /* table empty? */
sim_brk_ins = 0; /* insrt at head */
return NULL; } /* sch fails */
lo = 0; /* initial bounds */
hi = sim_brk_ent - 1;
do { p = (lo + hi) >> 1; /* probe */
bp = sim_brk_tab + p; /* table addr */
if (loc == bp->addr) return bp; /* match? */
else if (loc < bp->addr) hi = p - 1; /* go down? p is upper */
else lo = p + 1; } /* go up? p is lower */
while (lo <= hi);
if (loc < bp->addr) sim_brk_ins = p; /* insrt before or */
else sim_brk_ins = p + 1; /* after last sch */
return NULL;
}
/* Insert a breakpoint */
BRKTAB *sim_brk_new (t_addr loc)
{
int32 i, t;
BRKTAB *bp, *newp;
if (sim_brk_ins < 0) return NULL;
if (sim_brk_ent >= sim_brk_lnt) { /* out of space? */
t = sim_brk_lnt + SIM_BRK_INILNT; /* new size */
newp = calloc (t, sizeof (BRKTAB)); /* new table */
if (newp == NULL) return NULL; /* can't extend */
for (i = 0; i < sim_brk_lnt; i++) /* copy table */
*(newp + i) = *(sim_brk_tab + i);
free (sim_brk_tab); /* free old table */
sim_brk_tab = newp; /* new base, lnt */
sim_brk_lnt = t; }
if (sim_brk_ins != sim_brk_ent) { /* move needed? */
for (bp = sim_brk_tab + sim_brk_ent;
bp > sim_brk_tab + sim_brk_ins; bp--)
*bp = *(bp - 1); }
bp = sim_brk_tab + sim_brk_ins;
bp->addr = loc;
bp->typ = 0;
bp->cnt = 0;
bp->act = NULL;
sim_brk_ent = sim_brk_ent + 1;
return bp;
}
/* Set a breakpoint of type sw */
t_stat sim_brk_set (t_addr loc, int32 sw, int32 ncnt, char *act)
{
BRKTAB *bp;
if (sw == 0) sw = sim_brk_dflt;
if ((sim_brk_types & sw) == 0) return SCPE_NOFNC;
bp = sim_brk_fnd (loc); /* present? */
if (!bp) bp = sim_brk_new (loc); /* no, allocate */
if (!bp) return SCPE_MEM; /* still no? mem err */
bp->typ = sw; /* set type */
bp->cnt = ncnt; /* set count */
if ((bp->act != NULL) && (act != NULL)) { /* replace old action? */
free (bp->act); /* deallocate */
bp->act = NULL; } /* now no action */
if ((act != NULL) && (*act != 0)) { /* new action? */
char *newp = calloc (CBUFSIZE, sizeof (char)); /* allocate buffer */
if (newp == NULL) return SCPE_MEM; /* mem err? */
strncpy (newp, act, CBUFSIZE); /* copy action */
bp->act = newp; } /* set pointer */
sim_brk_summ = sim_brk_summ | sw;
return SCPE_OK;
}
/* Clear a breakpoint */
t_stat sim_brk_clr (t_addr loc, int32 sw)
{
BRKTAB *bp = sim_brk_fnd (loc);
if (!bp) return SCPE_OK; /* not there? ok */
if (sw == 0) sw = SIM_BRK_ALLTYP;
bp->typ = bp->typ & ~sw;
if (bp->typ) return SCPE_OK; /* clear all types? */
if (bp->act != NULL) free (bp->act); /* deallocate action */
for ( ; bp < (sim_brk_tab + sim_brk_ent - 1); bp++) /* erase entry */
*bp = *(bp + 1);
sim_brk_ent = sim_brk_ent - 1; /* decrement count */
sim_brk_summ = 0; /* recalc summary */
for (bp = sim_brk_tab; bp < (sim_brk_tab + sim_brk_ent); bp++)
sim_brk_summ = sim_brk_summ | bp->typ;
return SCPE_OK;
}
/* Clear all breakpoints */
t_stat sim_brk_clrall (int32 sw)
{
BRKTAB *bp;
if (sw == 0) sw = SIM_BRK_ALLTYP;
for (bp = sim_brk_tab; bp < (sim_brk_tab + sim_brk_ent); ) {
if (bp->typ & sw) sim_brk_clr (bp->addr, sw);
else bp++; }
return SCPE_OK;
}
/* Show a breakpoint */
t_stat sim_brk_show (FILE *st, t_addr loc, int32 sw)
{
BRKTAB *bp = sim_brk_fnd (loc);
DEVICE *dptr;
int32 i, any;
if (sw == 0) sw = SIM_BRK_ALLTYP;
if (!bp || (!(bp->typ & sw))) return SCPE_OK;
dptr = sim_devices[0];
if (dptr == NULL) return SCPE_OK;
fprint_val (st, loc, dptr->aradix, dptr->awidth, PV_LEFT);
fprintf (st, ":\t");
for (i = any = 0; i < 26; i++) {
if ((bp->typ >> i) & 1) {
if (any) fprintf (st, ", ");
fputc (i + 'A', st);
any = 1; } }
if (bp->cnt > 0) fprintf (st, " [%d]", bp->cnt);
if (bp->act != NULL) fprintf (st, "; %s", bp->act);
fprintf (st, "\n");
return SCPE_OK;
}
/* Show all breakpoints */
t_stat sim_brk_showall (FILE *st, int32 sw)
{
BRKTAB *bp;
if (sw == 0) sw = SIM_BRK_ALLTYP;
for (bp = sim_brk_tab; bp < (sim_brk_tab + sim_brk_ent); bp++) {
if (bp->typ & sw) sim_brk_show (st, bp->addr, sw); }
return SCPE_OK;
}
/* Test for breakpoint */
t_bool sim_brk_test (t_addr loc, int32 btyp)
{
BRKTAB *bp;
if ((bp = sim_brk_fnd (loc)) && /* entry in table? */
(btyp & bp->typ) && /* type match? */
(!sim_brk_pend || (loc != sim_brk_ploc)) && /* new location? */
(--(bp->cnt) <= 0)) { /* count reach 0? */
bp->cnt = 0; /* reset count */
sim_brk_ploc = loc; /* save location */
sim_brk_act = bp->act; /* set up actions */
sim_brk_pend = TRUE; /* don't do twice */
return TRUE; }
sim_brk_pend = FALSE;
return FALSE;
}
/* Get next pending action, if any */
char *sim_brk_getact (char *buf, int32 size)
{
char *ep;
size_t lnt;
if (sim_brk_act == NULL) return NULL; /* any action? */
while (isspace (*sim_brk_act)) sim_brk_act++; /* skip spaces */
if (*sim_brk_act == 0) return (sim_brk_act = NULL); /* now empty? */
if (ep = strchr (sim_brk_act, ';')) { /* cmd delimiter? */
lnt = ep - sim_brk_act; /* cmd length */
memcpy (buf, sim_brk_act, lnt + 1); /* copy with ; */
buf[lnt] = 0; /* erase ; */
sim_brk_act = sim_brk_act + lnt + 1; } /* adv ptr */
else { strncpy (buf, sim_brk_act, size); /* copy action */
sim_brk_act = NULL; } /* no more */
return buf;
}
/* Clear pending actions */
void sim_brk_clract (void)
{
sim_brk_act = NULL;
}
/* New PC */
void sim_brk_npc (void)
{
sim_brk_pend = FALSE;
return;
}
/* Telnet console package.
The console terminal can be attached to the controlling window
or to a Telnet connection. If attached to a Telnet connection,
the console is described by internal terminal multiplexor
sim_con_tmxr and internal terminal line description sim_con_ldsc.
*/
/* Set console to Telnet port */
t_stat set_telnet (int32 flg, char *cptr)
{
if (*cptr == 0) return SCPE_2FARG; /* too few arguments? */
if (sim_con_tmxr.master) return SCPE_ALATT; /* already open? */
return tmxr_open_master (&sim_con_tmxr, cptr); /* open master socket */
}
/* Close console Telnet port */
t_stat set_notelnet (int32 flag, char *cptr)
{
if (cptr && (*cptr != 0)) return SCPE_2MARG; /* too many arguments? */
if (sim_con_tmxr.master == 0) return SCPE_OK; /* ignore if already closed */
return tmxr_close_master (&sim_con_tmxr); /* close master socket */
}
/* Show console Telnet status */
t_stat show_telnet (FILE *st, int32 flag, char *cptr)
{
if (cptr && (*cptr != 0)) return SCPE_2MARG;
if (sim_con_tmxr.master == 0)
fprintf (st, "Connected to console window\n");
else if (sim_con_ldsc.conn == 0)
fprintf (st, "Listening on port %d\n", sim_con_tmxr.port);
else { fprintf (st, "Listening on port %d, connected to socket %d\n",
sim_con_tmxr.port, sim_con_ldsc.conn);
tmxr_fconns (st, &sim_con_ldsc, -1);
tmxr_fstats (st, &sim_con_ldsc, -1); }
return SCPE_OK;
}
/* Check connection before executing */
t_stat sim_check_console (int32 sec)
{
int32 c, i;
if (sim_con_tmxr.master == 0) return SCPE_OK; /* not Telnet? done */
if (sim_con_ldsc.conn) { /* connected? */
tmxr_poll_rx (&sim_con_tmxr); /* poll (check disconn) */
if (sim_con_ldsc.conn) return SCPE_OK; } /* still connected? */
for (i = 0; i < sec; i++) { /* loop */
if (tmxr_poll_conn (&sim_con_tmxr) >= 0) { /* poll connect */
sim_con_ldsc.rcve = 1; /* rcv enabled */
if (i) { /* if delayed */
printf ("Running\n"); /* print transition */
fflush (stdout); }
return SCPE_OK; } /* ready to proceed */
c = sim_os_poll_kbd (); /* check for stop char */
if ((c == SCPE_STOP) || stop_cpu) return SCPE_STOP;
if ((i % 10) == 0) { /* Status every 10 sec */
printf ("Waiting for console Telnet connnection\n");
fflush (stdout); }
sim_os_sleep (1); /* wait 1 second */
}
return SCPE_TTMO; /* timed out */
}
/* Poll for character */
t_stat sim_poll_kbd (void)
{
int32 c;
c = sim_os_poll_kbd (); /* get character */
if ((c == SCPE_STOP) || (sim_con_tmxr.master == 0)) /* ^E or not Telnet? */
return c; /* in-window */
if (sim_con_ldsc.conn == 0) return SCPE_LOST; /* no Telnet conn? */
tmxr_poll_rx (&sim_con_tmxr); /* poll for input */
if (c = tmxr_getc_ln (&sim_con_ldsc)) /* any char? */
return (c & (SCPE_BREAK | 0377)) | SCPE_KFLAG;
return SCPE_OK;
}
/* Output character */
t_stat sim_putchar (int32 c)
{
if (sim_con_tmxr.master == 0) /* not Telnet? */
return sim_os_putchar (c); /* in-window version */
if (sim_con_ldsc.conn == 0) return SCPE_LOST; /* no Telnet conn? */
tmxr_putc_ln (&sim_con_ldsc, c); /* output char */
tmxr_poll_tx (&sim_con_tmxr); /* poll xmt */
return SCPE_OK;
}
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