SSEM/ssem_sys.c - emulators/simh - Rivoreo Source Code Repositories

 /* ssem_sys.c: Manchester University SSEM (Small Scale Experimental Machine)
                          simulator interface

    Based on the SIMH package written by Robert M Supnik

    Copyright (c) 2006-2013 Gerardo Ospina

    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
    THE AUTHOR 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 the author shall not be
    used in advertising or otherwise to promote the sale, use or other dealings
    in this Software without prior written authorization from the author.

    This is not a supported product, but the author welcomes bug reports and fixes.
    Mail to ngospina@gmail.com
 */

 #include <ctype.h>
 #include "ssem_defs.h"

 extern uint32 S[];
 extern uint32 C[];
 extern int32  A[];

 extern DEVICE cpu_dev;
 extern REG cpu_reg[];

 /* SCP data structures and interface routines

    sim_name             simulator name string
    sim_PC               pointer to saved PC register descriptor
    sim_emax             maximum number of words for examine/deposit
    sim_devices          array of pointers to simulated devices
    sim_stop_messages    array of pointers to stop messages
    sim_load             binary loader

    fprint_sym           memory examine
    parser_sym           memory deposit
 */

 char sim_name[] = "SSEM";

 REG *sim_PC = &cpu_reg[0];

 int32 sim_emax = 1;

 DEVICE *sim_devices[] = {
     &cpu_dev,
     NULL
     };

 const char *sim_stop_messages[] = {
     "Unknown error",
     "Stop",
     "Breakpoint",
     };

 /* SSEM binary dump */

 t_stat ssem_dump (FILE *fi)
 {
 if (sim_fwrite(A, sizeof(int32), 1, fi) != 1 ||
     sim_fwrite(C, sizeof(uint32), 1, fi) != 1 ||
     sim_fwrite(S, sizeof(uint32), MEMSIZE, fi) != MEMSIZE) {
     return SCPE_IOERR;
     }
 return SCPE_OK;
 }

 /* SSEM binary loader */

 t_stat ssem_load_dmp (FILE *fi)
 {
 C[1] = 0;
 if (sim_fread(A, sizeof(int32), 1, fi) != 1 ||
     sim_fread(C, sizeof(uint32), 1, fi) != 1 ||
     sim_fread(S, sizeof(uint32), MEMSIZE, fi) != MEMSIZE) {
     return SCPE_IOERR;
     }
 return SCPE_OK;
 }

 /* Loader

    Inputs:
         *fi     =       input stream
         *cptr   =       VM-specific arguments
         *fnam   =       file name
         flag    =       1 = dump, 0 = load
    Outputs:
         return  =       status code
 */

 t_stat sim_load (FILE *fi, char *cptr, char *fnam, int flag)
 {
 size_t len;

 len = strlen(fnam);
 if (len <= 3 || strcmp(fnam + (len - 3), ".st") != 0) return SCPE_ARG;

 if (flag == 1) return ssem_dump(fi);
 return ssem_load_dmp(fi);
 }

 /* Use scp.c provided fprintf function */
 #define fprintf Fprintf
 #define fputs(_s,f) Fprintf(f,"%s",_s)
 #define fputc(_c,f) Fprintf(f,"%c",_c)

 /* Utility routine - prints number in decimal */

 t_stat ssem_fprint_decimal (FILE *of, uint32 inst)
 {
 if (inst & SMASK)
     fprintf (of, "%d [%u]", inst, inst);
 else
     fprintf (of, "%d", inst);
 return SCPE_OK;
 }

 /* Utility routine - prints number in backward binary */

 t_stat ssem_fprint_binary_number (FILE *of, uint32 inst, uint8 nbits)
 {
 int i;
 uint32 n;

 n = inst;
 for (i = 0; i < nbits; i++) {
     fprintf(of, "%d", n & 1 ? 1 : 0);
     n >>= 1;
     }
 return SCPE_OK;
 }

 /* Utility routine - prints instruction in backward binary */

 t_stat ssem_fprint_binary (FILE *of, uint32 inst, int flag)
 {
 uint32 op, ea;

 if (!flag) return ssem_fprint_binary_number(of, inst, 32);

 op = I_GETOP (inst);
 if (op != OP_TEST && op != OP_STOP)  {
     ea = I_GETEA (inst);
     ssem_fprint_binary_number(of, ea, 5);
     fprintf (of, " ");
     }
 ssem_fprint_binary_number(of, op, 3);

 return SCPE_OK;
 }

 /* Utility routine

    prints instruction in the mnemomic style used in the 1998
    competition reference manual:
    "The Manchester University Small Scale Experimental Machine
     Programmer's Reference manual"
     http://www.computer50.org/mark1/prog98/ssemref.html
 */

 t_stat ssem_fprint_competition_mnemonic (FILE *of, uint32 inst)
 {
 uint32 op, ea;

 op = I_GETOP (inst);
 switch (op) {
     case OP_JUMP_INDIRECT:            /* JMP  */
         ea = I_GETEA (inst);
         fprintf (of, "JMP %d", ea);
         break;

     case OP_JUMP_INDIRECT_RELATIVE:    /* JRP  */
         ea = I_GETEA (inst);
         fprintf (of, "JRP %d", ea);
         break;

     case OP_LOAD_NEGATED:            /* LDN  */
         ea = I_GETEA (inst);
         fprintf (of, "LDN %d", ea);
         break;

     case OP_STORE:                    /* STO  */
         ea = I_GETEA (inst);
         fprintf (of, "STO %d", ea);
         break;

     case OP_SUBSTRACT:                /* SUB  */
         ea = I_GETEA (inst);
         fprintf (of, "SUB %d", ea);
         break;

     case OP_UNDOCUMENTED:            /* invalid instruction */
         return SCPE_ARG;

     case OP_TEST:                    /* CMP  */
         fprintf (of, "CMP");
         break;

     case OP_STOP:                    /* STOP */
         fprintf (of, "STOP");
         break;                        /* end switch */
     }

 return SCPE_OK;
 }

 /* Symbolic decode

    Inputs:
         *of     =       output stream
         addr    =       current PC
         *val    =       pointer to data
         *uptr   =       pointer to unit
         sw      =       switches
    Outputs:
         return  =       status code
 */

 t_stat fprint_sym (FILE *of, t_addr addr, t_value *val,
     UNIT *uptr, int32 sw)
 {
 uint32 inst;

 if (sw & SWMASK ('H')) return SCPE_ARG;    /* hexadecimal? */

 inst = val[0];

 if (sw & SWMASK ('D'))                    /* decimal? */
     return ssem_fprint_decimal(of, inst);

 if (sw & SWMASK ('M')) {                /* mnemomic? */
     return ssem_fprint_competition_mnemonic(of, inst);
     }

 return ssem_fprint_binary(of, inst, sw & SWMASK ('I') || sw & SWMASK ('M'));
 }

 static const char *opcode[] = {
     "JMP", "JRP", "LDN",
     "STO", "SUB", "",
     "CMP", "STOP",
     NULL
 };

 /* Utility function - parses decimal number. */

 t_stat parse_sym_d (char *cptr, t_value *val)
 {
 char *start;
 int n;

 start = cptr;
 if (*cptr == '-') cptr++;    /* skip sign */
 n = 0;
 while (*cptr >= '0' && *cptr <= '9') {
     n = (n * 10) + (*cptr - '0');
     cptr++;
     }
 if (*start == '-') n = -n;
 if (*start) *start = 'x';

 if (*cptr) return SCPE_ARG;    /* junk at end? */

 *val = n;
 return SCPE_OK;
 }

 /* Utility function

    Parses mnemonic instruction.

    It accepts the mnemonics used in the 1998 competition reference
    manual:
    "The Manchester University Small Scale Experimental Machine
     Programmer's Reference manual"
     http://www.computer50.org/mark1/prog98/ssemref.html
 */

 t_stat parse_sym_m (char *cptr, t_value *val)
 {
 char *start;
 uint32 n,a;
 char gbuf[CBUFSIZE];

 start = cptr;
 cptr = get_glyph(cptr, gbuf, 0);
 if (*start) *start = 'x';

 for (n = 0; opcode[n] != NULL && strcmp(opcode[n], gbuf) != 0; n++) ;
 if (opcode[n] == NULL) return SCPE_ARG;                /* invalid mnemonic? */

 if (!(*cptr) && n > OP_UNDOCUMENTED && n <= OP_STOP) {
     *val = n << I_V_OP; return SCPE_OK;
     }

 while (isspace (*cptr)) cptr++;                        /* absorb spaces */

 if (*cptr < '0' || *cptr > '9')  return SCPE_ARG;    /* address expected */

 a = 0;
 while (*cptr >= '0' && *cptr <= '9') {
     a = (a * 10) + (*cptr - '0');
     cptr++;
     }

 if (a >= MEMSIZE) return SCPE_ARG;                    /* invalid address? */

 if (*cptr) return SCPE_ARG;                            /* junk at end? */

 *val = (n << I_V_OP) + a;
 return SCPE_OK;
 }

 /* Utility function - parses binary backward number. */

 t_stat parse_sym_b (char *cptr, t_value *val)
 {
 char *start;
 int count;
 t_value n;

 start = cptr;
 count = 0;
 n = 0;
 while (*cptr == '0' || *cptr == '1') {
     n = n + ((*cptr - '0') << count);
     count++;
     cptr++;
     }
 if (*start) *start = 'x';

 if (*cptr) return SCPE_ARG;    /* junk at end? */

 *val = n;
 return SCPE_OK;
 }

 /* Utility function - parses binary backward instruccion. */

 t_stat parse_sym_i (char *cptr, t_value *val)
 {
 char *start;
 int count;
 t_value a,n;

 start = cptr;
 count = 0;
 n = 0;
 while (*cptr == '0' || *cptr == '1') {
     n = n + ((*cptr - '0') << count);
     count++;
     cptr++;
     }
 if (*start) *start = 'x';

 if (!(*cptr) && n > OP_UNDOCUMENTED && n <= OP_STOP) {
     *val = n << I_V_OP; return SCPE_OK;
     }

 a = n;
 if (a >= MEMSIZE) return SCPE_ARG;                    /* invalid addresss */

 while (isspace (*cptr)) cptr++;                        /* absorb spaces */

 if (*cptr != '0' && *cptr != '1') return SCPE_ARG;    /* instruction expected */

 count = 0;
 n = 0;
 while (*cptr == '0' || *cptr == '1') {
     n = n + ((*cptr - '0') << count);
     count++;
     cptr++;
     }
 if (n >= OP_UNDOCUMENTED) return SCPE_ARG;            /* invalid instruction? */

 if (*cptr) return SCPE_ARG;                            /* junk at end? */

 *val = (n << I_V_OP) + a;
 return SCPE_OK;
 }

 /* Symbolic input

    Inputs:
         *cptr   =       pointer to input string
         addr    =       current PC
         *uptr   =       pointer to unit
         *val    =       pointer to output values
         sw      =       switches
    Outputs:
         status  =       error status
 */

 t_stat parse_sym (char *cptr, t_addr addr, UNIT *uptr, t_value *val, int32 sw)
 {

 if (sw & SWMASK ('H')) return SCPE_ARG;    /* hexadecimal? */

 while (isspace (*cptr)) cptr++;            /* absorb spaces */

 if (sw & SWMASK ('D')) {                 /* decimal? */
     return parse_sym_d (cptr, val);
     }

 if (sw & SWMASK ('I')) {                 /* backward binary instruction? */
     return parse_sym_i (cptr, val);
     }

 if (sw & SWMASK ('M')) {                 /* mnemonic? */
     return parse_sym_m (cptr, val);
     }

 return parse_sym_b(cptr, val);            /* backward binary number */
 }
	/* ssem_sys.c: Manchester University SSEM (Small Scale Experimental Machine)
	simulator interface

	Based on the SIMH package written by Robert M Supnik

	Copyright (c) 2006-2013 Gerardo Ospina

	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
	THE AUTHOR 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 the author shall not be
	used in advertising or otherwise to promote the sale, use or other dealings
	in this Software without prior written authorization from the author.

	This is not a supported product, but the author welcomes bug reports and fixes.
	Mail to ngospina@gmail.com
	*/

	#include <ctype.h>
	#include "ssem_defs.h"

	extern uint32 S[];
	extern uint32 C[];
	extern int32 A[];

	extern DEVICE cpu_dev;
	extern REG cpu_reg[];

	/* SCP data structures and interface routines

	sim_name simulator name string
	sim_PC pointer to saved PC register descriptor
	sim_emax maximum number of words for examine/deposit
	sim_devices array of pointers to simulated devices
	sim_stop_messages array of pointers to stop messages
	sim_load binary loader

	fprint_sym memory examine
	parser_sym memory deposit
	*/

	char sim_name[] = "SSEM";

	REG *sim_PC = &cpu_reg[0];

	int32 sim_emax = 1;

	DEVICE *sim_devices[] = {
	&cpu_dev,
	NULL
	};

	const char *sim_stop_messages[] = {
	"Unknown error",
	"Stop",
	"Breakpoint",
	};

	/* SSEM binary dump */

	t_stat ssem_dump (FILE *fi)
	{
	if (sim_fwrite(A, sizeof(int32), 1, fi) != 1 \|\|
	sim_fwrite(C, sizeof(uint32), 1, fi) != 1 \|\|
	sim_fwrite(S, sizeof(uint32), MEMSIZE, fi) != MEMSIZE) {
	return SCPE_IOERR;
	}
	return SCPE_OK;
	}

	/* SSEM binary loader */

	t_stat ssem_load_dmp (FILE *fi)
	{
	C[1] = 0;
	if (sim_fread(A, sizeof(int32), 1, fi) != 1 \|\|
	sim_fread(C, sizeof(uint32), 1, fi) != 1 \|\|
	sim_fread(S, sizeof(uint32), MEMSIZE, fi) != MEMSIZE) {
	return SCPE_IOERR;
	}
	return SCPE_OK;
	}

	/* Loader

	Inputs:
	*fi = input stream
	*cptr = VM-specific arguments
	*fnam = file name
	flag = 1 = dump, 0 = load
	Outputs:
	return = status code
	*/

	t_stat sim_load (FILE fi, char cptr, char *fnam, int flag)
	{
	size_t len;

	len = strlen(fnam);
	if (len <= 3 \|\| strcmp(fnam + (len - 3), ".st") != 0) return SCPE_ARG;

	if (flag == 1) return ssem_dump(fi);
	return ssem_load_dmp(fi);
	}

	/* Use scp.c provided fprintf function */
	#define fprintf Fprintf
	#define fputs(_s,f) Fprintf(f,"%s",_s)
	#define fputc(_c,f) Fprintf(f,"%c",_c)

	/* Utility routine - prints number in decimal */

	t_stat ssem_fprint_decimal (FILE *of, uint32 inst)
	{
	if (inst & SMASK)
	fprintf (of, "%d [%u]", inst, inst);
	else
	fprintf (of, "%d", inst);
	return SCPE_OK;
	}

	/* Utility routine - prints number in backward binary */

	t_stat ssem_fprint_binary_number (FILE *of, uint32 inst, uint8 nbits)
	{
	int i;
	uint32 n;

	n = inst;
	for (i = 0; i < nbits; i++) {
	fprintf(of, "%d", n & 1 ? 1 : 0);
	n >>= 1;
	}
	return SCPE_OK;
	}

	/* Utility routine - prints instruction in backward binary */

	t_stat ssem_fprint_binary (FILE *of, uint32 inst, int flag)
	{
	uint32 op, ea;

	if (!flag) return ssem_fprint_binary_number(of, inst, 32);

	op = I_GETOP (inst);
	if (op != OP_TEST && op != OP_STOP) {
	ea = I_GETEA (inst);
	ssem_fprint_binary_number(of, ea, 5);
	fprintf (of, " ");
	}
	ssem_fprint_binary_number(of, op, 3);

	return SCPE_OK;
	}

	/* Utility routine

	prints instruction in the mnemomic style used in the 1998
	competition reference manual:
	"The Manchester University Small Scale Experimental Machine
	Programmer's Reference manual"
	http://www.computer50.org/mark1/prog98/ssemref.html
	*/

	t_stat ssem_fprint_competition_mnemonic (FILE *of, uint32 inst)
	{
	uint32 op, ea;

	op = I_GETOP (inst);
	switch (op) {
	case OP_JUMP_INDIRECT: /* JMP */
	ea = I_GETEA (inst);
	fprintf (of, "JMP %d", ea);
	break;

	case OP_JUMP_INDIRECT_RELATIVE: /* JRP */
	ea = I_GETEA (inst);
	fprintf (of, "JRP %d", ea);
	break;

	case OP_LOAD_NEGATED: /* LDN */
	ea = I_GETEA (inst);
	fprintf (of, "LDN %d", ea);
	break;

	case OP_STORE: /* STO */
	ea = I_GETEA (inst);
	fprintf (of, "STO %d", ea);
	break;

	case OP_SUBSTRACT: /* SUB */
	ea = I_GETEA (inst);
	fprintf (of, "SUB %d", ea);
	break;

	case OP_UNDOCUMENTED: /* invalid instruction */
	return SCPE_ARG;

	case OP_TEST: /* CMP */
	fprintf (of, "CMP");
	break;

	case OP_STOP: /* STOP */
	fprintf (of, "STOP");
	break; /* end switch */
	}

	return SCPE_OK;
	}

	/* Symbolic decode

	Inputs:
	*of = output stream
	addr = current PC
	*val = pointer to data
	*uptr = pointer to unit
	sw = switches
	Outputs:
	return = status code
	*/

	t_stat fprint_sym (FILE of, t_addr addr, t_value val,
	UNIT *uptr, int32 sw)
	{
	uint32 inst;

	if (sw & SWMASK ('H')) return SCPE_ARG; /* hexadecimal? */

	inst = val[0];

	if (sw & SWMASK ('D')) /* decimal? */
	return ssem_fprint_decimal(of, inst);

	if (sw & SWMASK ('M')) { /* mnemomic? */
	return ssem_fprint_competition_mnemonic(of, inst);
	}

	return ssem_fprint_binary(of, inst, sw & SWMASK ('I') \|\| sw & SWMASK ('M'));
	}

	static const char *opcode[] = {
	"JMP", "JRP", "LDN",
	"STO", "SUB", "",
	"CMP", "STOP",
	NULL
	};

	/* Utility function - parses decimal number. */

	t_stat parse_sym_d (char cptr, t_value val)
	{
	char *start;
	int n;

	start = cptr;
	if (cptr == '-') cptr++; / skip sign */
	n = 0;
	while (cptr >= '0' && cptr <= '9') {
	n = (n * 10) + (*cptr - '0');
	cptr++;
	}
	if (*start == '-') n = -n;
	if (start) start = 'x';

	if (cptr) return SCPE_ARG; / junk at end? */

	*val = n;
	return SCPE_OK;
	}

	/* Utility function

	Parses mnemonic instruction.

	It accepts the mnemonics used in the 1998 competition reference
	manual:
	"The Manchester University Small Scale Experimental Machine
	Programmer's Reference manual"
	http://www.computer50.org/mark1/prog98/ssemref.html
	*/

	t_stat parse_sym_m (char cptr, t_value val)
	{
	char *start;
	uint32 n,a;
	char gbuf[CBUFSIZE];

	start = cptr;
	cptr = get_glyph(cptr, gbuf, 0);
	if (start) start = 'x';

	for (n = 0; opcode[n] != NULL && strcmp(opcode[n], gbuf) != 0; n++) ;
	if (opcode[n] == NULL) return SCPE_ARG; /* invalid mnemonic? */

	if (!(*cptr) && n > OP_UNDOCUMENTED && n <= OP_STOP) {
	*val = n << I_V_OP; return SCPE_OK;
	}

	while (isspace (cptr)) cptr++; / absorb spaces */

	if (cptr < '0' \|\| cptr > '9') return SCPE_ARG; /* address expected */

	a = 0;
	while (cptr >= '0' && cptr <= '9') {
	a = (a * 10) + (*cptr - '0');
	cptr++;
	}

	if (a >= MEMSIZE) return SCPE_ARG; /* invalid address? */

	if (cptr) return SCPE_ARG; / junk at end? */

	*val = (n << I_V_OP) + a;
	return SCPE_OK;
	}

	/* Utility function - parses binary backward number. */

	t_stat parse_sym_b (char cptr, t_value val)
	{
	char *start;
	int count;
	t_value n;

	start = cptr;
	count = 0;
	n = 0;
	while (cptr == '0' \|\| cptr == '1') {
	n = n + ((*cptr - '0') << count);
	count++;
	cptr++;
	}
	if (start) start = 'x';

	if (cptr) return SCPE_ARG; / junk at end? */

	*val = n;
	return SCPE_OK;
	}

	/* Utility function - parses binary backward instruccion. */

	t_stat parse_sym_i (char cptr, t_value val)
	{
	char *start;
	int count;
	t_value a,n;

	start = cptr;
	count = 0;
	n = 0;
	while (cptr == '0' \|\| cptr == '1') {
	n = n + ((*cptr - '0') << count);
	count++;
	cptr++;
	}
	if (start) start = 'x';

	if (!(*cptr) && n > OP_UNDOCUMENTED && n <= OP_STOP) {
	*val = n << I_V_OP; return SCPE_OK;
	}

	a = n;
	if (a >= MEMSIZE) return SCPE_ARG; /* invalid addresss */

	while (isspace (cptr)) cptr++; / absorb spaces */

	if (cptr != '0' && cptr != '1') return SCPE_ARG; /* instruction expected */

	count = 0;
	n = 0;
	while (cptr == '0' \|\| cptr == '1') {
	n = n + ((*cptr - '0') << count);
	count++;
	cptr++;
	}
	if (n >= OP_UNDOCUMENTED) return SCPE_ARG; /* invalid instruction? */

	if (cptr) return SCPE_ARG; / junk at end? */

	*val = (n << I_V_OP) + a;
	return SCPE_OK;
	}

	/* Symbolic input

	Inputs:
	*cptr = pointer to input string
	addr = current PC
	*uptr = pointer to unit
	*val = pointer to output values
	sw = switches
	Outputs:
	status = error status
	*/

	t_stat parse_sym (char cptr, t_addr addr, UNIT uptr, t_value *val, int32 sw)
	{

	if (sw & SWMASK ('H')) return SCPE_ARG; /* hexadecimal? */

	while (isspace (cptr)) cptr++; / absorb spaces */

	if (sw & SWMASK ('D')) { /* decimal? */
	return parse_sym_d (cptr, val);
	}

	if (sw & SWMASK ('I')) { /* backward binary instruction? */
	return parse_sym_i (cptr, val);
	}

	if (sw & SWMASK ('M')) { /* mnemonic? */
	return parse_sym_m (cptr, val);
	}

	return parse_sym_b(cptr, val); /* backward binary number */
	}