/* armos.c -- ARMulator OS interface: ARM6 Instruction Emulator. Copyright (C) 1994 Advanced RISC Machines Ltd. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, see . */ /* This file contains a model of Demon, ARM Ltd's Debug Monitor, including all the SWI's required to support the C library. The code in it is not really for the faint-hearted (especially the abort handling code), but it is a complete example. Defining NOOS will disable all the fun, and definign VAILDATE will define SWI 1 to enter SVC mode, and SWI 0x11 to halt the emulator. */ /* This must come before any other includes. */ #include "defs.h" #include "ansidecl.h" #include "libiberty.h" #include #include #include #include #include "targ-vals.h" #ifndef TARGET_O_BINARY #define TARGET_O_BINARY 0 #endif #ifdef HAVE_UNISTD_H #include /* For SEEK_SET etc. */ #endif #include "armdefs.h" #include "armos.h" #include "armemu.h" #ifndef NOOS #ifndef VALIDATE /* #ifndef ASIM */ #include "armfpe.h" /* #endif */ #endif #endif /* For RDIError_BreakpointReached. */ #include "dbg_rdi.h" #include "sim/callback.h" extern host_callback *sim_callback; extern unsigned ARMul_OSInit (ARMul_State *); extern unsigned ARMul_OSHandleSWI (ARMul_State *, ARMword); #ifndef FOPEN_MAX #define FOPEN_MAX 64 #endif #ifndef PATH_MAX #define PATH_MAX 1024 #endif /* OS private Information. */ struct OSblock { ARMword ErrorNo; }; /* Bit mask of enabled SWI implementations. */ unsigned int swi_mask = -1; static ARMword softvectorcode[] = { /* Installed instructions: swi tidyexception + event; mov lr, pc; ldmia fp, {fp, pc}; swi generateexception + event. */ 0xef000090, 0xe1a0e00f, 0xe89b8800, 0xef000080, /* Reset */ 0xef000091, 0xe1a0e00f, 0xe89b8800, 0xef000081, /* Undef */ 0xef000092, 0xe1a0e00f, 0xe89b8800, 0xef000082, /* SWI */ 0xef000093, 0xe1a0e00f, 0xe89b8800, 0xef000083, /* Prefetch abort */ 0xef000094, 0xe1a0e00f, 0xe89b8800, 0xef000084, /* Data abort */ 0xef000095, 0xe1a0e00f, 0xe89b8800, 0xef000085, /* Address exception */ 0xef000096, 0xe1a0e00f, 0xe89b8800, 0xef000086, /* IRQ */ 0xef000097, 0xe1a0e00f, 0xe89b8800, 0xef000087, /* FIQ */ 0xef000098, 0xe1a0e00f, 0xe89b8800, 0xef000088, /* Error */ 0xe1a0f00e /* Default handler */ }; /* Time for the Operating System to initialise itself. */ unsigned ARMul_OSInit (ARMul_State * state) { #ifndef NOOS #ifndef VALIDATE ARMword instr, i, j; struct OSblock *OSptr = (struct OSblock *) state->OSptr; if (state->OSptr == NULL) { state->OSptr = (unsigned char *) malloc (sizeof (struct OSblock)); if (state->OSptr == NULL) { perror ("OS Memory"); exit (15); } } OSptr = (struct OSblock *) state->OSptr; state->Reg[13] = ADDRSUPERSTACK; /* Set up a stack for the current mode... */ ARMul_SetReg (state, SVC32MODE, 13, ADDRSUPERSTACK);/* ...and for supervisor mode... */ ARMul_SetReg (state, ABORT32MODE, 13, ADDRSUPERSTACK);/* ...and for abort 32 mode... */ ARMul_SetReg (state, UNDEF32MODE, 13, ADDRSUPERSTACK);/* ...and for undef 32 mode... */ ARMul_SetReg (state, SYSTEMMODE, 13, ADDRSUPERSTACK);/* ...and for system mode. */ instr = 0xe59ff000 | (ADDRSOFTVECTORS - 8); /* Load pc from soft vector */ for (i = ARMul_ResetV; i <= ARMFIQV; i += 4) /* Write hardware vectors. */ ARMul_WriteWord (state, i, instr); SWI_vector_installed = 0; for (i = ARMul_ResetV; i <= ARMFIQV + 4; i += 4) { ARMul_WriteWord (state, ADDRSOFTVECTORS + i, SOFTVECTORCODE + i * 4); ARMul_WriteWord (state, ADDRSOFHANDLERS + 2 * i + 4L, SOFTVECTORCODE + sizeof (softvectorcode) - 4L); } for (i = 0; i < sizeof (softvectorcode); i += 4) ARMul_WriteWord (state, SOFTVECTORCODE + i, softvectorcode[i / 4]); ARMul_ConsolePrint (state, ", Demon 1.01"); /* #ifndef ASIM */ /* Install FPE. */ for (i = 0; i < fpesize; i += 4) /* Copy the code. */ ARMul_WriteWord (state, FPESTART + i, fpecode[i >> 2]); /* Scan backwards from the end of the code. */ for (i = FPESTART + fpesize;; i -= 4) { /* When we reach the marker value, break out of the loop, leaving i pointing at the maker. */ if ((j = ARMul_ReadWord (state, i)) == 0xffffffff) break; /* If necessary, reverse the error strings. */ if (state->bigendSig && j < 0x80000000) { /* It's part of the string so swap it. */ j = ((j >> 0x18) & 0x000000ff) | ((j >> 0x08) & 0x0000ff00) | ((j << 0x08) & 0x00ff0000) | ((j << 0x18) & 0xff000000); ARMul_WriteWord (state, i, j); } } /* Copy old illegal instr vector. */ ARMul_WriteWord (state, FPEOLDVECT, ARMul_ReadWord (state, ARMUndefinedInstrV)); /* Install new vector. */ ARMul_WriteWord (state, ARMUndefinedInstrV, FPENEWVECT (ARMul_ReadWord (state, i - 4))); ARMul_ConsolePrint (state, ", FPE"); /* #endif ASIM */ #endif /* VALIDATE */ #endif /* NOOS */ /* Intel do not want DEMON SWI support. */ if (state->is_XScale) swi_mask = SWI_MASK_ANGEL; return TRUE; } static int translate_open_mode[] = { TARGET_O_RDONLY, /* "r" */ TARGET_O_RDONLY + TARGET_O_BINARY, /* "rb" */ TARGET_O_RDWR, /* "r+" */ TARGET_O_RDWR + TARGET_O_BINARY, /* "r+b" */ TARGET_O_WRONLY + TARGET_O_CREAT + TARGET_O_TRUNC, /* "w" */ TARGET_O_WRONLY + TARGET_O_BINARY + TARGET_O_CREAT + TARGET_O_TRUNC, /* "wb" */ TARGET_O_RDWR + TARGET_O_CREAT + TARGET_O_TRUNC, /* "w+" */ TARGET_O_RDWR + TARGET_O_BINARY + TARGET_O_CREAT + TARGET_O_TRUNC, /* "w+b" */ TARGET_O_WRONLY + TARGET_O_APPEND + TARGET_O_CREAT, /* "a" */ TARGET_O_WRONLY + TARGET_O_BINARY + TARGET_O_APPEND + TARGET_O_CREAT, /* "ab" */ TARGET_O_RDWR + TARGET_O_APPEND + TARGET_O_CREAT, /* "a+" */ TARGET_O_RDWR + TARGET_O_BINARY + TARGET_O_APPEND + TARGET_O_CREAT /* "a+b" */ }; static void SWIWrite0 (ARMul_State * state, ARMword addr) { ARMword temp; struct OSblock *OSptr = (struct OSblock *) state->OSptr; while ((temp = ARMul_SafeReadByte (state, addr++)) != 0) { char buffer = temp; /* Note - we cannot just cast 'temp' to a (char *) here, since on a big-endian host the byte value will end up in the wrong place and a nul character will be printed. */ (void) sim_callback->write_stdout (sim_callback, & buffer, 1); } OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } static void WriteCommandLineTo (ARMul_State * state, ARMword addr) { ARMword temp; char *cptr = state->CommandLine; if (cptr == NULL) cptr = "\0"; do { temp = (ARMword) * cptr++; ARMul_SafeWriteByte (state, addr++, temp); } while (temp != 0); } static int ReadFileName (ARMul_State * state, char *buf, ARMword src, size_t n) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; char *p = buf; while (n--) if ((*p++ = ARMul_SafeReadByte (state, src++)) == '\0') return 0; OSptr->ErrorNo = cb_host_to_target_errno (sim_callback, ENAMETOOLONG); state->Reg[0] = -1; return -1; } static void SWIopen (ARMul_State * state, ARMword name, ARMword SWIflags) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; char buf[PATH_MAX]; int flags; if (ReadFileName (state, buf, name, sizeof buf) == -1) return; /* Now we need to decode the Demon open mode. */ if (SWIflags >= ARRAY_SIZE (translate_open_mode)) flags = 0; else flags = translate_open_mode[SWIflags]; /* Filename ":tt" is special: it denotes stdin/out. */ if (strcmp (buf, ":tt") == 0) { if (flags == TARGET_O_RDONLY) /* opening tty "r" */ state->Reg[0] = 0; /* stdin */ else state->Reg[0] = 1; /* stdout */ } else { state->Reg[0] = sim_callback->open (sim_callback, buf, flags); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } } static void SWIread (ARMul_State * state, ARMword f, ARMword ptr, ARMword len) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; int res; int i; char *local = malloc (len); if (local == NULL) { sim_callback->printf_filtered (sim_callback, "sim: Unable to read 0x%lx bytes - out of memory\n", (long)len); return; } res = sim_callback->read (sim_callback, f, local, len); if (res > 0) for (i = 0; i < res; i++) ARMul_SafeWriteByte (state, ptr + i, local[i]); free (local); state->Reg[0] = res == -1 ? -1 : len - res; OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } static void SWIwrite (ARMul_State * state, ARMword f, ARMword ptr, ARMword len) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; int res; ARMword i; char *local = malloc (len); if (local == NULL) { sim_callback->printf_filtered (sim_callback, "sim: Unable to write 0x%lx bytes - out of memory\n", (long) len); return; } for (i = 0; i < len; i++) local[i] = ARMul_SafeReadByte (state, ptr + i); res = sim_callback->write (sim_callback, f, local, len); state->Reg[0] = res == -1 ? -1 : len - res; free (local); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } static void SWIflen (ARMul_State * state, ARMword fh) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; ARMword addr; if (fh > FOPEN_MAX) { OSptr->ErrorNo = EBADF; state->Reg[0] = -1L; return; } addr = sim_callback->lseek (sim_callback, fh, 0, SEEK_CUR); state->Reg[0] = sim_callback->lseek (sim_callback, fh, 0L, SEEK_END); (void) sim_callback->lseek (sim_callback, fh, addr, SEEK_SET); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } static void SWIremove (ARMul_State * state, ARMword path) { char buf[PATH_MAX]; if (ReadFileName (state, buf, path, sizeof buf) != -1) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; state->Reg[0] = sim_callback->unlink (sim_callback, buf); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } } static void SWIrename (ARMul_State * state, ARMword old, ARMword new) { char oldbuf[PATH_MAX], newbuf[PATH_MAX]; if (ReadFileName (state, oldbuf, old, sizeof oldbuf) != -1 && ReadFileName (state, newbuf, new, sizeof newbuf) != -1) { struct OSblock *OSptr = (struct OSblock *) state->OSptr; state->Reg[0] = sim_callback->rename (sim_callback, oldbuf, newbuf); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } } /* The emulator calls this routine when a SWI instruction is encuntered. The parameter passed is the SWI number (lower 24 bits of the instruction). */ unsigned ARMul_OSHandleSWI (ARMul_State * state, ARMword number) { struct OSblock * OSptr = (struct OSblock *) state->OSptr; int unhandled = FALSE; switch (number) { case SWI_Read: if (swi_mask & SWI_MASK_DEMON) SWIread (state, state->Reg[0], state->Reg[1], state->Reg[2]); else unhandled = TRUE; break; case SWI_Write: if (swi_mask & SWI_MASK_DEMON) SWIwrite (state, state->Reg[0], state->Reg[1], state->Reg[2]); else unhandled = TRUE; break; case SWI_Open: if (swi_mask & SWI_MASK_DEMON) SWIopen (state, state->Reg[0], state->Reg[1]); else unhandled = TRUE; break; case SWI_Clock: if (swi_mask & SWI_MASK_DEMON) { /* Return number of centi-seconds. */ state->Reg[0] = #ifdef CLOCKS_PER_SEC (CLOCKS_PER_SEC >= 100) ? (ARMword) (clock () / (CLOCKS_PER_SEC / 100)) : (ARMword) ((clock () * 100) / CLOCKS_PER_SEC); #else /* Presume unix... clock() returns microseconds. */ (ARMword) (clock () / 10000); #endif OSptr->ErrorNo = errno; } else unhandled = TRUE; break; case SWI_Time: if (swi_mask & SWI_MASK_DEMON) { state->Reg[0] = (ARMword) sim_callback->time (sim_callback); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } else unhandled = TRUE; break; case SWI_Close: if (swi_mask & SWI_MASK_DEMON) { state->Reg[0] = sim_callback->close (sim_callback, state->Reg[0]); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } else unhandled = TRUE; break; case SWI_Flen: if (swi_mask & SWI_MASK_DEMON) SWIflen (state, state->Reg[0]); else unhandled = TRUE; break; case SWI_Exit: if (swi_mask & SWI_MASK_DEMON) state->Emulate = FALSE; else unhandled = TRUE; break; case SWI_Seek: if (swi_mask & SWI_MASK_DEMON) { /* We must return non-zero for failure. */ state->Reg[0] = -1 >= sim_callback->lseek (sim_callback, state->Reg[0], state->Reg[1], SEEK_SET); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } else unhandled = TRUE; break; case SWI_WriteC: if (swi_mask & SWI_MASK_DEMON) { char tmp = state->Reg[0]; (void) sim_callback->write_stdout (sim_callback, &tmp, 1); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } else unhandled = TRUE; break; case SWI_Write0: if (swi_mask & SWI_MASK_DEMON) SWIWrite0 (state, state->Reg[0]); else unhandled = TRUE; break; case SWI_GetErrno: if (swi_mask & SWI_MASK_DEMON) state->Reg[0] = OSptr->ErrorNo; else unhandled = TRUE; break; case SWI_GetEnv: if (swi_mask & SWI_MASK_DEMON) { state->Reg[0] = ADDRCMDLINE; if (state->MemSize) state->Reg[1] = state->MemSize; else state->Reg[1] = ADDRUSERSTACK; WriteCommandLineTo (state, state->Reg[0]); } else unhandled = TRUE; break; case SWI_Breakpoint: state->EndCondition = RDIError_BreakpointReached; state->Emulate = FALSE; break; case SWI_Remove: if (swi_mask & SWI_MASK_DEMON) SWIremove (state, state->Reg[0]); else unhandled = TRUE; break; case SWI_Rename: if (swi_mask & SWI_MASK_DEMON) SWIrename (state, state->Reg[0], state->Reg[1]); else unhandled = TRUE; break; case SWI_IsTTY: if (swi_mask & SWI_MASK_DEMON) { state->Reg[0] = sim_callback->isatty (sim_callback, state->Reg[0]); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); } else unhandled = TRUE; break; /* Handle Angel SWIs as well as Demon ones. */ case AngelSWI_ARM: case AngelSWI_Thumb: if (swi_mask & SWI_MASK_ANGEL) { ARMword addr; ARMword temp; /* R1 is almost always a parameter block. */ addr = state->Reg[1]; /* R0 is a reason code. */ switch (state->Reg[0]) { case -1: /* This can happen when a SWI is interrupted (eg receiving a ctrl-C whilst processing SWIRead()). The SWI will complete returning -1 in r0 to the caller. If GDB is then used to resume the system call the reason code will now be -1. */ return TRUE; /* Unimplemented reason codes. */ case AngelSWI_Reason_ReadC: case AngelSWI_Reason_TmpNam: case AngelSWI_Reason_System: case AngelSWI_Reason_EnterSVC: default: state->Emulate = FALSE; return FALSE; case AngelSWI_Reason_Clock: /* Return number of centi-seconds. */ state->Reg[0] = #ifdef CLOCKS_PER_SEC (CLOCKS_PER_SEC >= 100) ? (ARMword) (clock () / (CLOCKS_PER_SEC / 100)) : (ARMword) ((clock () * 100) / CLOCKS_PER_SEC); #else /* Presume unix... clock() returns microseconds. */ (ARMword) (clock () / 10000); #endif OSptr->ErrorNo = errno; break; case AngelSWI_Reason_Time: state->Reg[0] = (ARMword) sim_callback->time (sim_callback); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case AngelSWI_Reason_WriteC: { char tmp = ARMul_SafeReadByte (state, addr); (void) sim_callback->write_stdout (sim_callback, &tmp, 1); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; } case AngelSWI_Reason_Write0: SWIWrite0 (state, addr); break; case AngelSWI_Reason_Close: state->Reg[0] = sim_callback->close (sim_callback, ARMul_ReadWord (state, addr)); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case AngelSWI_Reason_Seek: state->Reg[0] = -1 >= sim_callback->lseek (sim_callback, ARMul_ReadWord (state, addr), ARMul_ReadWord (state, addr + 4), SEEK_SET); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case AngelSWI_Reason_FLen: SWIflen (state, ARMul_ReadWord (state, addr)); break; case AngelSWI_Reason_GetCmdLine: WriteCommandLineTo (state, ARMul_ReadWord (state, addr)); break; case AngelSWI_Reason_HeapInfo: /* R1 is a pointer to a pointer. */ addr = ARMul_ReadWord (state, addr); /* Pick up the right memory limit. */ if (state->MemSize) temp = state->MemSize; else temp = ADDRUSERSTACK; ARMul_WriteWord (state, addr, 0); /* Heap base. */ ARMul_WriteWord (state, addr + 4, temp); /* Heap limit. */ ARMul_WriteWord (state, addr + 8, temp); /* Stack base. */ ARMul_WriteWord (state, addr + 12, temp); /* Stack limit. */ break; case AngelSWI_Reason_ReportException: if (state->Reg[1] == ADP_Stopped_ApplicationExit) state->Reg[0] = 0; else state->Reg[0] = -1; state->Emulate = FALSE; break; case ADP_Stopped_ApplicationExit: state->Reg[0] = 0; state->Emulate = FALSE; break; case ADP_Stopped_RunTimeError: state->Reg[0] = -1; state->Emulate = FALSE; break; case AngelSWI_Reason_Errno: state->Reg[0] = OSptr->ErrorNo; break; case AngelSWI_Reason_Open: SWIopen (state, ARMul_ReadWord (state, addr), ARMul_ReadWord (state, addr + 4)); break; case AngelSWI_Reason_Read: SWIread (state, ARMul_ReadWord (state, addr), ARMul_ReadWord (state, addr + 4), ARMul_ReadWord (state, addr + 8)); break; case AngelSWI_Reason_Write: SWIwrite (state, ARMul_ReadWord (state, addr), ARMul_ReadWord (state, addr + 4), ARMul_ReadWord (state, addr + 8)); break; case AngelSWI_Reason_IsTTY: state->Reg[0] = sim_callback->isatty (sim_callback, ARMul_ReadWord (state, addr)); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case AngelSWI_Reason_Remove: SWIremove (state, ARMul_ReadWord (state, addr)); case AngelSWI_Reason_Rename: SWIrename (state, ARMul_ReadWord (state, addr), ARMul_ReadWord (state, addr + 4)); } } else unhandled = TRUE; break; /* The following SWIs are generated by the softvectorcode[] installed by default by the simulator. */ case 0x91: /* Undefined Instruction. */ { ARMword addr = state->RegBank[UNDEFBANK][14] - 4; sim_callback->printf_filtered (sim_callback, "sim: exception: Unhandled Instruction '0x%08x' at 0x%08x. Stopping.\n", ARMul_ReadWord (state, addr), addr); state->EndCondition = RDIError_SoftwareInterrupt; state->Emulate = FALSE; return FALSE; } case 0x90: /* Reset. */ case 0x92: /* SWI. */ /* These two can be safely ignored. */ break; case 0x93: /* Prefetch Abort. */ case 0x94: /* Data Abort. */ case 0x95: /* Address Exception. */ case 0x96: /* IRQ. */ case 0x97: /* FIQ. */ case 0x98: /* Error. */ unhandled = TRUE; break; case -1: /* This can happen when a SWI is interrupted (eg receiving a ctrl-C whilst processing SWIRead()). The SWI will complete returning -1 in r0 to the caller. If GDB is then used to resume the system call the reason code will now be -1. */ return TRUE; case 0x180001: /* RedBoot's Syscall SWI in ARM mode. */ if (swi_mask & SWI_MASK_REDBOOT) { switch (state->Reg[0]) { /* These numbers are defined in libgloss/syscall.h but the simulator should not be dependend upon libgloss being installed. */ case 1: /* Exit. */ state->Emulate = FALSE; /* Copy exit code into r0. */ state->Reg[0] = state->Reg[1]; break; case 2: /* Open. */ SWIopen (state, state->Reg[1], state->Reg[2]); break; case 3: /* Close. */ state->Reg[0] = sim_callback->close (sim_callback, state->Reg[1]); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case 4: /* Read. */ SWIread (state, state->Reg[1], state->Reg[2], state->Reg[3]); break; case 5: /* Write. */ SWIwrite (state, state->Reg[1], state->Reg[2], state->Reg[3]); break; case 6: /* Lseek. */ state->Reg[0] = sim_callback->lseek (sim_callback, state->Reg[1], state->Reg[2], state->Reg[3]); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case 17: /* Utime. */ state->Reg[0] = state->Reg[1] = (ARMword) sim_callback->time (sim_callback); OSptr->ErrorNo = sim_callback->get_errno (sim_callback); break; case 7: /* Unlink. */ case 8: /* Getpid. */ case 9: /* Kill. */ case 10: /* Fstat. */ case 11: /* Sbrk. */ case 12: /* Argvlen. */ case 13: /* Argv. */ case 14: /* ChDir. */ case 15: /* Stat. */ case 16: /* Chmod. */ case 18: /* Time. */ sim_callback->printf_filtered (sim_callback, "sim: unhandled RedBoot syscall `%d' encountered - " "returning ENOSYS\n", state->Reg[0]); state->Reg[0] = -1; OSptr->ErrorNo = cb_host_to_target_errno (sim_callback, ENOSYS); break; case 1001: /* Meminfo. */ { ARMword totmem = state->Reg[1], topmem = state->Reg[2]; ARMword stack = state->MemSize > 0 ? state->MemSize : ADDRUSERSTACK; if (totmem != 0) ARMul_WriteWord (state, totmem, stack); if (topmem != 0) ARMul_WriteWord (state, topmem, stack); state->Reg[0] = 0; break; } default: sim_callback->printf_filtered (sim_callback, "sim: unknown RedBoot syscall '%d' encountered - ignoring\n", state->Reg[0]); return FALSE; } break; } default: unhandled = TRUE; } if (unhandled) { if (SWI_vector_installed) { ARMword cpsr; ARMword i_size; cpsr = ARMul_GetCPSR (state); i_size = INSN_SIZE; ARMul_SetSPSR (state, SVC32MODE, cpsr); cpsr &= ~0xbf; cpsr |= SVC32MODE | 0x80; ARMul_SetCPSR (state, cpsr); state->RegBank[SVCBANK][14] = state->Reg[14] = state->Reg[15] - i_size; state->NextInstr = RESUME; state->Reg[15] = state->pc = ARMSWIV; FLUSHPIPE; } else { sim_callback->printf_filtered (sim_callback, "sim: unknown SWI encountered - %x - ignoring\n", number); return FALSE; } } return TRUE; }