#include "v850_sim.h"
#include "simops.h"
+#include <sys/types.h>
+
#ifdef HAVE_UTIME_H
#include <utime.h>
#endif
int i;
for (i = 0; i < trace_num_values; i++)
{
- sprintf (chp, "%*s0x%.8lx", SIZE_VALUES - 10, "", trace_values[i]);
+ sprintf (chp, "%*s0x%.8lx", SIZE_VALUES - 10, "",
+ (long) trace_values[i]);
chp = strchr (chp, '\0');
}
while (i++ < 3)
}
static void
-Multiply64 (boolean sign, unsigned long op0)
+Multiply64 (int sign, unsigned long op0)
{
unsigned long op1;
unsigned long lo;
return 4;
}
-/* divh reg1, reg2 */
-int
-OP_40 ()
-{
- unsigned int op0, op1, result, ov, s, z;
- int temp;
-
- trace_input ("divh", OP_REG_REG, 0);
-
- /* Compute the result. */
- temp = EXTEND16 (State.regs[ OP[0] ]);
- op0 = temp;
- op1 = State.regs[OP[1]];
-
- if (op0 == 0xffffffff && op1 == 0x80000000)
- {
- result = 0x80000000;
- ov = 1;
- }
- else if (op0 != 0)
- {
- result = op1 / op0;
- ov = 0;
- }
- else
- {
- result = 0x0;
- ov = 1;
- }
-
- /* Compute the condition codes. */
- z = (result == 0);
- s = (result & 0x80000000);
-
- /* Store the result and condition codes. */
- State.regs[OP[1]] = result;
- PSW &= ~(PSW_Z | PSW_S | PSW_OV);
- PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
- | (ov ? PSW_OV : 0));
- trace_output (OP_REG_REG);
-
- return 2;
-}
-
/* cmp reg, reg */
int
OP_1E0 ()
&& (op0 & 0x80000000) != (result & 0x80000000));
sat = ov;
+ /* Handle saturated results. */
+ if (sat && s)
+ {
+ /* An overflow that results in a negative result implies that we
+ became too positive. */
+ result = 0x7fffffff;
+ s = 0;
+ }
+ else if (sat)
+ {
+ /* Any other overflow must have thus been too negative. */
+ result = 0x80000000;
+ s = 1;
+ z = 0;
+ }
+
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
| (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
| (sat ? PSW_SAT : 0));
-
- /* Handle saturated results. */
- if (sat && s)
- State.regs[OP[1]] = 0x80000000;
- else if (sat)
- State.regs[OP[1]] = 0x7fffffff;
+
trace_output (OP_REG_REG);
return 2;
&& (op0 & 0x80000000) != (result & 0x80000000));
sat = ov;
+ /* Handle saturated results. */
+ if (sat && s)
+ {
+ /* An overflow that results in a negative result implies that we
+ became too positive. */
+ result = 0x7fffffff;
+ s = 0;
+ }
+ else if (sat)
+ {
+ /* Any other overflow must have thus been too negative. */
+ result = 0x80000000;
+ s = 1;
+ z = 0;
+ }
+
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
PSW |= ((z ? PSW_Z : 0) | (s ? PSW_S : 0)
| (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
| (sat ? PSW_SAT : 0));
-
- /* Handle saturated results. */
- if (sat && s)
- State.regs[OP[1]] = 0x80000000;
- else if (sat)
- State.regs[OP[1]] = 0x7fffffff;
trace_output (OP_IMM_REG);
return 2;
ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
&& (op1 & 0x80000000) != (result & 0x80000000));
sat = ov;
-
+
+ /* Handle saturated results. */
+ if (sat && s)
+ {
+ /* An overflow that results in a negative result implies that we
+ became too positive. */
+ result = 0x7fffffff;
+ s = 0;
+ }
+ else if (sat)
+ {
+ /* Any other overflow must have thus been too negative. */
+ result = 0x80000000;
+ s = 1;
+ z = 0;
+ }
+
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
| (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
| (sat ? PSW_SAT : 0));
- /* Handle saturated results. */
- if (sat && s)
- State.regs[OP[1]] = 0x80000000;
- else if (sat)
- State.regs[OP[1]] = 0x7fffffff;
trace_output (OP_REG_REG);
return 2;
}
&& (op1 & 0x80000000) != (result & 0x80000000));
sat = ov;
+ /* Handle saturated results. */
+ if (sat && s)
+ {
+ /* An overflow that results in a negative result implies that we
+ became too positive. */
+ result = 0x7fffffff;
+ s = 0;
+ }
+ else if (sat)
+ {
+ /* Any other overflow must have thus been too negative. */
+ result = 0x80000000;
+ s = 1;
+ z = 0;
+ }
+
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
PSW &= ~(PSW_Z | PSW_S | PSW_CY | PSW_OV);
| (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
| (sat ? PSW_SAT : 0));
- /* Handle saturated results. */
- if (sat && s)
- State.regs[OP[1]] = 0x80000000;
- else if (sat)
- State.regs[OP[1]] = 0x7fffffff;
trace_output (OP_IMM_REG);
return 4;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (result < op0);
- ov = ((op1 & 0x80000000) != (op0 & 0x80000000)
- && (op1 & 0x80000000) != (result & 0x80000000));
+ cy = (op0 < op1);
+ ov = ((op0 & 0x80000000) != (op1 & 0x80000000)
+ && (op0 & 0x80000000) != (result & 0x80000000));
sat = ov;
+
+ /* Handle saturated results. */
+ if (sat && s)
+ {
+ /* An overflow that results in a negative result implies that we
+ became too positive. */
+ result = 0x7fffffff;
+ s = 0;
+ }
+ else if (sat)
+ {
+ /* Any other overflow must have thus been too negative. */
+ result = 0x80000000;
+ s = 1;
+ z = 0;
+ }
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
| (cy ? PSW_CY : 0) | (ov ? PSW_OV : 0)
| (sat ? PSW_SAT : 0));
- /* Handle saturated results. */
- if (sat && s)
- State.regs[OP[1]] = 0x80000000;
- else if (sat)
- State.regs[OP[1]] = 0x7fffffff;
trace_output (OP_REG_REG);
return 2;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (op0 - 1)));
+ cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
/* Store the result and condition codes. */
State.regs[ OP[1] ] = result;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (op0 - 1)));
+ cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (32 - op0)));
+ cy = op0 ? (op1 & (1 << (32 - op0))) : 0;
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (32 - op0)));
+ cy = op0 ? (op1 & (1 << (32 - op0))) : 0;
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (op0 - 1)));
+ cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
/* Compute the condition codes. */
z = (result == 0);
s = (result & 0x80000000);
- cy = (op1 & (1 << (op0 - 1)));
+ cy = op0 ? (op1 & (1 << (op0 - 1))) : 0;
/* Store the result and condition codes. */
State.regs[OP[1]] = result;
#define MEMPTR(x) (map (x))
+ RETERR = 0;
+
switch (FUNC)
{
#ifdef TARGET_SYS_fork
case TARGET_SYS_fork:
RETVAL = fork ();
+ RETERR = errno;
break;
#endif
#endif
char **argv = fetch_argv (simulator, PARM2);
char **envp = fetch_argv (simulator, PARM3);
RETVAL = execve (path, argv, envp);
- zfree (path);
+ free (path);
freeargv (argv);
freeargv (envp);
+ RETERR = errno;
break;
}
#endif
char *path = fetch_str (simulator, PARM1);
char **argv = fetch_argv (simulator, PARM2);
RETVAL = execv (path, argv);
- zfree (path);
+ free (path);
freeargv (argv);
+ RETERR = errno;
break;
}
#endif
SW (buf, host_fd[0]);
buf += sizeof(uint16);
SW (buf, host_fd[1]);
+ RETERR = errno;
}
break;
#endif
RETVAL = wait (&status);
SW (PARM1, status);
+ RETERR = errno;
}
break;
#endif
char *buf = zalloc (PARM3);
RETVAL = sim_io_read (simulator, PARM1, buf, PARM3);
sim_write (simulator, PARM2, buf, PARM3);
- zfree (buf);
+ free (buf);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
break;
}
#endif
RETVAL = sim_io_write_stdout (simulator, buf, PARM3);
else
RETVAL = sim_io_write (simulator, PARM1, buf, PARM3);
- zfree (buf);
+ free (buf);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
break;
}
#endif
#ifdef TARGET_SYS_lseek
case TARGET_SYS_lseek:
RETVAL = sim_io_lseek (simulator, PARM1, PARM2, PARM3);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
break;
#endif
#ifdef TARGET_SYS_close
case TARGET_SYS_close:
RETVAL = sim_io_close (simulator, PARM1);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
break;
#endif
{
char *buf = fetch_str (simulator, PARM1);
RETVAL = sim_io_open (simulator, buf, PARM2);
- zfree (buf);
+ free (buf);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
break;
}
#endif
break;
#endif
-#if !defined(__GO32__) && !defined(_WIN32)
#ifdef TARGET_SYS_stat
case TARGET_SYS_stat: /* added at hmsi */
/* stat system call */
reg_t buf;
char *path = fetch_str (simulator, PARM1);
- RETVAL = stat (path, &host_stat);
+ RETVAL = sim_io_stat (simulator, path, &host_stat);
- zfree (path);
+ free (path);
buf = PARM2;
/* Just wild-assed guesses. */
store_mem (buf + 20, 4, host_stat.st_atime);
store_mem (buf + 28, 4, host_stat.st_mtime);
store_mem (buf + 36, 4, host_stat.st_ctime);
+
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
}
break;
#endif
+
+#ifdef TARGET_SYS_fstat
+ case TARGET_SYS_fstat:
+ /* fstat system call */
+ {
+ struct stat host_stat;
+ reg_t buf;
+
+ RETVAL = sim_io_fstat (simulator, PARM1, &host_stat);
+
+ buf = PARM2;
+
+ /* Just wild-assed guesses. */
+ store_mem (buf, 2, host_stat.st_dev);
+ store_mem (buf + 2, 2, host_stat.st_ino);
+ store_mem (buf + 4, 4, host_stat.st_mode);
+ store_mem (buf + 8, 2, host_stat.st_nlink);
+ store_mem (buf + 10, 2, host_stat.st_uid);
+ store_mem (buf + 12, 2, host_stat.st_gid);
+ store_mem (buf + 14, 2, host_stat.st_rdev);
+ store_mem (buf + 16, 4, host_stat.st_size);
+ store_mem (buf + 20, 4, host_stat.st_atime);
+ store_mem (buf + 28, 4, host_stat.st_mtime);
+ store_mem (buf + 36, 4, host_stat.st_ctime);
+
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
+ }
+ break;
+#endif
+
+#ifdef TARGET_SYS_rename
+ case TARGET_SYS_rename:
+ {
+ char *oldpath = fetch_str (simulator, PARM1);
+ char *newpath = fetch_str (simulator, PARM2);
+ RETVAL = sim_io_rename (simulator, oldpath, newpath);
+ free (oldpath);
+ free (newpath);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
+ }
+ break;
+#endif
+
+#ifdef TARGET_SYS_unlink
+ case TARGET_SYS_unlink:
+ {
+ char *path = fetch_str (simulator, PARM1);
+ RETVAL = sim_io_unlink (simulator, path);
+ free (path);
+ if ((int) RETVAL < 0)
+ RETERR = sim_io_get_errno (simulator);
+ }
+ break;
#endif
#ifdef HAVE_CHOWN
{
char *path = fetch_str (simulator, PARM1);
RETVAL = chown (path, PARM2, PARM3);
- zfree (path);
+ free (path);
+ RETERR = errno;
}
break;
#endif
{
char *path = fetch_str (simulator, PARM1);
RETVAL = chmod (path, PARM2);
- zfree (path);
+ free (path);
+ RETERR = errno;
}
break;
#endif
time_t now;
RETVAL = time (&now);
store_mem (PARM1, 4, now);
+ RETERR = errno;
}
break;
#endif
store_mem (PARM1 + 4, 4, tms.tms_stime);
store_mem (PARM1 + 8, 4, tms.tms_cutime);
store_mem (PARM1 + 12, 4, tms.tms_cstime);
+ reterr = errno;
break;
}
#endif
store_mem (PARM1 + 4, 4, t.tv_usec);
store_mem (PARM2, 4, tz.tz_minuteswest);
store_mem (PARM2 + 4, 4, tz.tz_dsttime);
+ RETERR = errno;
break;
}
#endif
default:
abort ();
}
- RETERR = errno;
errno = save_errno;
return 4;
ECR |= 0x40 + OP[0];
/* Flag that we are now doing exception processing. */
PSW |= PSW_EP | PSW_ID;
- PC = ((OP[0] < 0x10) ? 0x40 : 0x50) - 4;
+ PC = (OP[0] < 0x10) ? 0x40 : 0x50;
return 0;
}
temp = load_mem (State.regs[ OP[0] ], 1);
PSW &= ~PSW_Z;
- if ((temp & (1 << State.regs[ OP[1] & 0x7 ])) == 0)
+ if ((temp & (1 << (State.regs[ OP[1] ] & 0x7))) == 0)
PSW |= PSW_Z;
trace_output (OP_BIT);
{
trace_input ("mulu", OP_REG_REG_REG, 0);
- Multiply64 (false, State.regs[ OP[0] ]);
+ Multiply64 (0, State.regs[ OP[0] ]);
trace_output (OP_REG_REG_REG);
\
trace_input (name, OP_BIT_CHANGE, 0); \
\
- bit = 1 << State.regs[ OP[1] & 0x7 ]; \
+ bit = 1 << (State.regs[ OP[1] ] & 0x7); \
temp = load_mem (State.regs[ OP[0] ], 1); \
\
PSW &= ~PSW_Z; \
unsigned long int sfi,
unsigned32 /*unsigned long int*/ * quotient_ptr,
unsigned32 /*unsigned long int*/ * remainder_ptr,
- boolean * overflow_ptr
+ int * overflow_ptr
)
{
unsigned long ald = sfi >> (N - 1);
unsigned long int sfi,
signed32 /*signed long int*/ * quotient_ptr,
signed32 /*signed long int*/ * remainder_ptr,
- boolean * overflow_ptr
+ int * overflow_ptr
)
{
unsigned long ald = (signed long) sfi >> (N - 1);
unsigned32 /*unsigned long int*/ remainder;
unsigned long int divide_by;
unsigned long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
unsigned int imm5;
trace_input ("sdivun", OP_IMM_REG_REG_REG, 0);
signed32 /*signed long int*/ remainder;
signed long int divide_by;
signed long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
unsigned int imm5;
trace_input ("sdivn", OP_IMM_REG_REG_REG, 0);
imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
- divide_by = State.regs[ OP[0] ];
- divide_this = State.regs[ OP[1] ] << imm5;
+ divide_by = (signed32) State.regs[ OP[0] ];
+ divide_this = (signed32) (State.regs[ OP[1] ] << imm5);
divn (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
unsigned32 /*unsigned long int*/ remainder;
unsigned long int divide_by;
unsigned long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
unsigned int imm5;
trace_input ("sdivhun", OP_IMM_REG_REG_REG, 0);
signed32 /*signed long int*/ remainder;
signed long int divide_by;
signed long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
unsigned int imm5;
trace_input ("sdivhn", OP_IMM_REG_REG_REG, 0);
imm5 = 32 - ((OP[3] & 0x3c0000) >> 17);
divide_by = EXTEND16 (State.regs[ OP[0] ]);
- divide_this = State.regs[ OP[1] ] << imm5;
+ divide_this = (signed32) (State.regs[ OP[1] ] << imm5);
divn (imm5, divide_by, divide_this, & quotient, & remainder, & overflow);
unsigned long int remainder;
unsigned long int divide_by;
unsigned long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
trace_input ("divu", OP_REG_REG_REG, 0);
if (divide_by == 0)
{
- overflow = true;
- divide_by = 1;
+ PSW |= PSW_OV;
}
+ else
+ {
+ State.regs[ OP[1] ] = quotient = divide_this / divide_by;
+ State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
- State.regs[ OP[1] ] = quotient = divide_this / divide_by;
- State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
-
- /* Set condition codes. */
- PSW &= ~(PSW_Z | PSW_S | PSW_OV);
+ /* Set condition codes. */
+ PSW &= ~(PSW_Z | PSW_S | PSW_OV);
- if (overflow) PSW |= PSW_OV;
- if (quotient == 0) PSW |= PSW_Z;
- if (quotient & 0x80000000) PSW |= PSW_S;
+ if (overflow) PSW |= PSW_OV;
+ if (quotient == 0) PSW |= PSW_Z;
+ if (quotient & 0x80000000) PSW |= PSW_S;
+ }
trace_output (OP_REG_REG_REG);
signed long int remainder;
signed long int divide_by;
signed long int divide_this;
- boolean overflow = false;
trace_input ("div", OP_REG_REG_REG, 0);
/* Compute the result. */
- divide_by = State.regs[ OP[0] ];
+ divide_by = (signed32) State.regs[ OP[0] ];
divide_this = State.regs[ OP[1] ];
- if (divide_by == 0 || (divide_by == -1 && divide_this == (1 << 31)))
+ if (divide_by == 0)
{
- overflow = true;
- divide_by = 1;
+ PSW |= PSW_OV;
+ }
+ else if (divide_by == -1 && divide_this == (1L << 31))
+ {
+ PSW &= ~PSW_Z;
+ PSW |= PSW_OV | PSW_S;
+ State.regs[ OP[1] ] = (1 << 31);
+ State.regs[ OP[2] >> 11 ] = 0;
+ }
+ else
+ {
+ divide_this = (signed32) divide_this;
+ State.regs[ OP[1] ] = quotient = divide_this / divide_by;
+ State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
+
+ /* Set condition codes. */
+ PSW &= ~(PSW_Z | PSW_S | PSW_OV);
+
+ if (quotient == 0) PSW |= PSW_Z;
+ if (quotient < 0) PSW |= PSW_S;
}
-
- State.regs[ OP[1] ] = quotient = divide_this / divide_by;
- State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
-
- /* Set condition codes. */
- PSW &= ~(PSW_Z | PSW_S | PSW_OV);
-
- if (overflow) PSW |= PSW_OV;
- if (quotient == 0) PSW |= PSW_Z;
- if (quotient < 0) PSW |= PSW_S;
trace_output (OP_REG_REG_REG);
unsigned long int remainder;
unsigned long int divide_by;
unsigned long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
trace_input ("divhu", OP_REG_REG_REG, 0);
if (divide_by == 0)
{
- overflow = true;
- divide_by = 1;
+ PSW |= PSW_OV;
}
+ else
+ {
+ State.regs[ OP[1] ] = quotient = divide_this / divide_by;
+ State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
- State.regs[ OP[1] ] = quotient = divide_this / divide_by;
- State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
-
- /* Set condition codes. */
- PSW &= ~(PSW_Z | PSW_S | PSW_OV);
+ /* Set condition codes. */
+ PSW &= ~(PSW_Z | PSW_S | PSW_OV);
- if (overflow) PSW |= PSW_OV;
- if (quotient == 0) PSW |= PSW_Z;
- if (quotient & 0x80000000) PSW |= PSW_S;
+ if (overflow) PSW |= PSW_OV;
+ if (quotient == 0) PSW |= PSW_Z;
+ if (quotient & 0x80000000) PSW |= PSW_S;
+ }
trace_output (OP_REG_REG_REG);
signed long int remainder;
signed long int divide_by;
signed long int divide_this;
- boolean overflow = false;
+ int overflow = 0;
trace_input ("divh", OP_REG_REG_REG, 0);
/* Compute the result. */
- divide_by = State.regs[ OP[0] ];
- divide_this = EXTEND16 (State.regs[ OP[1] ]);
+ divide_by = EXTEND16 (State.regs[ OP[0] ]);
+ divide_this = State.regs[ OP[1] ];
- if (divide_by == 0 || (divide_by == -1 && divide_this == (1 << 31)))
+ if (divide_by == 0)
{
- overflow = true;
- divide_by = 1;
+ PSW |= PSW_OV;
}
+ else if (divide_by == -1 && divide_this == (1L << 31))
+ {
+ PSW &= ~PSW_Z;
+ PSW |= PSW_OV | PSW_S;
+ State.regs[ OP[1] ] = (1 << 31);
+ State.regs[ OP[2] >> 11 ] = 0;
+ }
+ else
+ {
+ divide_this = (signed32) divide_this;
+ State.regs[ OP[1] ] = quotient = divide_this / divide_by;
+ State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
- State.regs[ OP[1] ] = quotient = divide_this / divide_by;
- State.regs[ OP[2] >> 11 ] = remainder = divide_this % divide_by;
+ /* Set condition codes. */
+ PSW &= ~(PSW_Z | PSW_S | PSW_OV);
- /* Set condition codes. */
- PSW &= ~(PSW_Z | PSW_S | PSW_OV);
-
- if (overflow) PSW |= PSW_OV;
- if (quotient == 0) PSW |= PSW_Z;
- if (quotient < 0) PSW |= PSW_S;
+ if (quotient == 0) PSW |= PSW_Z;
+ if (quotient < 0) PSW |= PSW_S;
+ }
trace_output (OP_REG_REG_REG);
{
trace_input ("mulu", OP_IMM_REG_REG, 0);
- Multiply64 (false, (OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0));
+ Multiply64 (0, (OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0));
trace_output (OP_IMM_REG_REG);
{
trace_input ("mul", OP_IMM_REG_REG, 0);
- Multiply64 (true, (OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0));
+ Multiply64 (1, SEXT9 ((OP[3] & 0x1f) | ((OP[3] >> 13) & 0x1e0)));
trace_output (OP_IMM_REG_REG);
{
trace_input ("mul", OP_REG_REG_REG, 0);
- Multiply64 (true, State.regs[ OP[0] ]);
+ Multiply64 (1, State.regs[ OP[0] ]);
trace_output (OP_REG_REG_REG);