/* * Routines providing a simple monitor for use on the PowerMac. * * Copyright (C) 1996 Paul Mackerras. * * 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 * 2 of the License, or (at your option) any later version. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "nonstdio.h" #include "privinst.h" #define scanhex xmon_scanhex #define skipbl xmon_skipbl #ifdef CONFIG_SMP static unsigned long cpus_in_xmon = 0; static unsigned long got_xmon = 0; static volatile int take_xmon = -1; #endif /* CONFIG_SMP */ static unsigned long adrs; static int size = 1; static unsigned long ndump = 64; static unsigned long nidump = 16; static unsigned long ncsum = 4096; static int termch; static u_int bus_error_jmp[100]; #define setjmp xmon_setjmp #define longjmp xmon_longjmp #define memlist_entry list_entry #define memlist_next(x) ((x)->next) #define memlist_prev(x) ((x)->prev) /* Max number of stack frames we are willing to produce on a backtrace. */ #define MAXFRAMECOUNT 50 /* Breakpoint stuff */ struct bpt { unsigned long address; unsigned instr; unsigned long count; unsigned char enabled; char funcname[64]; /* function name for humans */ }; #define NBPTS 16 static struct bpt bpts[NBPTS]; static struct bpt dabr; static struct bpt iabr; static unsigned bpinstr = 0x7fe00008; /* trap */ /* Prototypes */ extern void (*debugger_fault_handler)(struct pt_regs *); static int cmds(struct pt_regs *); static int mread(unsigned long, void *, int); static int mwrite(unsigned long, void *, int); static void handle_fault(struct pt_regs *); static void byterev(unsigned char *, int); static void memex(void); static int bsesc(void); static void dump(void); static void prdump(unsigned long, long); #ifdef __MWERKS__ static void prndump(unsigned, int); static int nvreadb(unsigned); #endif static int ppc_inst_dump(unsigned long, long); void print_address(unsigned long); static int getsp(void); static void dump_hash_table(void); static void backtrace(struct pt_regs *); static void excprint(struct pt_regs *); static void prregs(struct pt_regs *); static void memops(int); static void memlocate(void); static void memzcan(void); static void memdiffs(unsigned char *, unsigned char *, unsigned, unsigned); int skipbl(void); int scanhex(unsigned long *valp); static void scannl(void); static int hexdigit(int); void getstring(char *, int); static void flush_input(void); static int inchar(void); static void take_input(char *); /* static void openforth(void); */ static unsigned long read_spr(int); static void write_spr(int, unsigned long); static void super_regs(void); static void print_sysmap(void); static void remove_bpts(void); static void insert_bpts(void); static struct bpt *at_breakpoint(unsigned long pc); static void bpt_cmds(void); static void cacheflush(void); #ifdef CONFIG_SMP static void cpu_cmd(void); #endif /* CONFIG_SMP */ static void csum(void); static void mem_translate(void); static void mem_check(void); static void mem_find_real(void); static void mem_find_vsid(void); static void mem_check_pagetable_vsids (void); static void mem_map_check_slab(void); static void mem_map_lock_pages(void); static void mem_check_dup_rpn (void); static void debug_trace(void); extern int print_insn_big_powerpc(FILE *, unsigned long, unsigned long); extern void printf(const char *fmt, ...); extern void xmon_vfprintf(void *f, const char *fmt, va_list ap); extern int xmon_putc(int c, void *f); extern int putchar(int ch); extern int xmon_read_poll(void); extern int setjmp(u_int *); extern void longjmp(u_int *, int); extern unsigned long _ASR; pte_t *find_linux_pte(pgd_t *pgdir, unsigned long va); /* from htab.c */ #define GETWORD(v) (((v)[0] << 24) + ((v)[1] << 16) + ((v)[2] << 8) + (v)[3]) static char *help_string = "\ Commands:\n\ b show breakpoints\n\ bd set data breakpoint\n\ bi set instruction breakpoint\n\ bc clear breakpoint\n\ d dump bytes\n\ di dump instructions\n\ df dump float values\n\ dd dump double values\n\ e print exception information\n\ f flush cache\n\ h dump hash table\n\ m examine/change memory\n\ mm move a block of memory\n\ ms set a block of memory\n\ md compare two blocks of memory\n\ ml locate a block of memory\n\ mz zero a block of memory\n\ mx translation information for an effective address\n\ mi show information about memory allocation\n\ M print System.map\n\ p show the task list\n\ r print registers\n\ s single step\n\ S print special registers\n\ t print backtrace\n\ T Enable/Disable PPCDBG flags\n\ x exit monitor\n\ z reboot\n\ Z halt\n\ "; static int xmon_trace[NR_CPUS]; #define SSTEP 1 /* stepping because of 's' command */ #define BRSTEP 2 /* stepping over breakpoint */ /* * Stuff for reading and writing memory safely */ extern inline void sync(void) { asm volatile("sync; isync"); } /* (Ref: 64-bit PowerPC ELF ABI Spplement; Ian Lance Taylor, Zembu Labs). A PPC stack frame looks like this: High Address Back Chain FP reg save area GP reg save area Local var space Parameter save area (SP+48) TOC save area (SP+40) link editor doubleword (SP+32) compiler doubleword (SP+24) LR save (SP+16) CR save (SP+8) Back Chain (SP+0) Note that the LR (ret addr) may not be saved in the current frame if no functions have been called from the current function. */ /* A traceback table typically follows each function. The find_tb_table() func will fill in this struct. Note that the struct is not an exact match with the encoded table defined by the ABI. It is defined here more for programming convenience. */ struct tbtable { unsigned long flags; /* flags: */ #define TBTAB_FLAGSGLOBALLINK (1L<<47) #define TBTAB_FLAGSISEPROL (1L<<46) #define TBTAB_FLAGSHASTBOFF (1L<<45) #define TBTAB_FLAGSINTPROC (1L<<44) #define TBTAB_FLAGSHASCTL (1L<<43) #define TBTAB_FLAGSTOCLESS (1L<<42) #define TBTAB_FLAGSFPPRESENT (1L<<41) #define TBTAB_FLAGSNAMEPRESENT (1L<<38) #define TBTAB_FLAGSUSESALLOCA (1L<<37) #define TBTAB_FLAGSSAVESCR (1L<<33) #define TBTAB_FLAGSSAVESLR (1L<<32) #define TBTAB_FLAGSSTORESBC (1L<<31) #define TBTAB_FLAGSFIXUP (1L<<30) #define TBTAB_FLAGSPARMSONSTK (1L<<0) unsigned char fp_saved; /* num fp regs saved f(32-n)..f31 */ unsigned char gpr_saved; /* num gpr's saved */ unsigned char fixedparms; /* num fixed point parms */ unsigned char floatparms; /* num float parms */ unsigned char parminfo[32]; /* types of args. null terminated */ #define TBTAB_PARMFIXED 1 #define TBTAB_PARMSFLOAT 2 #define TBTAB_PARMDFLOAT 3 unsigned int tb_offset; /* offset from start of func */ unsigned long funcstart; /* addr of start of function */ char name[64]; /* name of function (null terminated)*/ }; static int find_tb_table(unsigned long codeaddr, struct tbtable *tab); void xmon(struct pt_regs *excp) { struct pt_regs regs; int cmd; unsigned long msr; if (excp == NULL) { /* Ok, grab regs as they are now. This won't do a particularily good job because the prologue has already been executed. ToDo: We could reach back into the callers save area to do a better job of representing the caller's state. */ asm volatile ("std 0,0(%0)\n\ std 1,8(%0)\n\ std 2,16(%0)\n\ std 3,24(%0)\n\ std 4,32(%0)\n\ std 5,40(%0)\n\ std 6,48(%0)\n\ std 7,56(%0)\n\ std 8,64(%0)\n\ std 9,72(%0)\n\ std 10,80(%0)\n\ std 11,88(%0)\n\ std 12,96(%0)\n\ std 13,104(%0)\n\ std 14,112(%0)\n\ std 15,120(%0)\n\ std 16,128(%0)\n\ std 17,136(%0)\n\ std 18,144(%0)\n\ std 19,152(%0)\n\ std 20,160(%0)\n\ std 21,168(%0)\n\ std 22,176(%0)\n\ std 23,184(%0)\n\ std 24,192(%0)\n\ std 25,200(%0)\n\ std 26,208(%0)\n\ std 27,216(%0)\n\ std 28,224(%0)\n\ std 29,232(%0)\n\ std 30,240(%0)\n\ std 31,248(%0)" : : "b" (®s)); printf("xmon called\n"); /* Fetch the link reg for this stack frame. NOTE: the prev printf fills in the lr. */ regs.nip = regs.link = ((unsigned long *)(regs.gpr[1]))[2]; regs.msr = get_msr(); regs.ctr = get_ctr(); regs.xer = get_xer(); regs.ccr = get_cr(); regs.trap = 0; excp = ®s; } msr = get_msr(); set_msrd(msr & ~MSR_EE); /* disable interrupts */ excprint(excp); #ifdef CONFIG_SMP if (test_and_set_bit(smp_processor_id(), &cpus_in_xmon)) for (;;) ; while (test_and_set_bit(0, &got_xmon)) { if (take_xmon == smp_processor_id()) { take_xmon = -1; break; } } #endif /* CONFIG_SMP */ remove_bpts(); cmd = cmds(excp); if (cmd == 's') { xmon_trace[smp_processor_id()] = SSTEP; excp->msr |= 0x400; } else if (at_breakpoint(excp->nip)) { xmon_trace[smp_processor_id()] = BRSTEP; excp->msr |= 0x400; } else { xmon_trace[smp_processor_id()] = 0; insert_bpts(); } #ifdef CONFIG_SMP clear_bit(0, &got_xmon); clear_bit(smp_processor_id(), &cpus_in_xmon); #endif /* CONFIG_SMP */ set_msrd(msr); /* restore interrupt enable */ } /* Code can call this to get a backtrace and continue. */ void xmon_backtrace(const char *fmt, ...) { va_list ap; struct pt_regs regs; /* Ok, grab regs as they are now. This won't do a particularily good job because the prologue has already been executed. ToDo: We could reach back into the callers save area to do a better job of representing the caller's state. */ asm volatile ("std 0,0(%0)\n\ std 1,8(%0)\n\ std 2,16(%0)\n\ std 3,24(%0)\n\ std 4,32(%0)\n\ std 5,40(%0)\n\ std 6,48(%0)\n\ std 7,56(%0)\n\ std 8,64(%0)\n\ std 9,72(%0)\n\ std 10,80(%0)\n\ std 11,88(%0)\n\ std 12,96(%0)\n\ std 13,104(%0)\n\ std 14,112(%0)\n\ std 15,120(%0)\n\ std 16,128(%0)\n\ std 17,136(%0)\n\ std 18,144(%0)\n\ std 19,152(%0)\n\ std 20,160(%0)\n\ std 21,168(%0)\n\ std 22,176(%0)\n\ std 23,184(%0)\n\ std 24,192(%0)\n\ std 25,200(%0)\n\ std 26,208(%0)\n\ std 27,216(%0)\n\ std 28,224(%0)\n\ std 29,232(%0)\n\ std 30,240(%0)\n\ std 31,248(%0)" : : "b" (®s)); /* Fetch the link reg for this stack frame. NOTE: the prev printf fills in the lr. */ regs.nip = regs.link = ((unsigned long *)(regs.gpr[1]))[2]; regs.msr = get_msr(); regs.ctr = get_ctr(); regs.xer = get_xer(); regs.ccr = get_cr(); regs.trap = 0; va_start(ap, fmt); xmon_vfprintf(stdout, fmt, ap); xmon_putc('\n', stdout); va_end(ap); take_input("\n"); backtrace(®s); } /* Call this to poll for ^C during busy operations. * Returns true if the user has hit ^C. */ int xmon_interrupted(void) { int ret = xmon_read_poll(); if (ret == 3) { printf("\n^C interrupted.\n"); return 1; } return 0; } void xmon_irq(int irq, void *d, struct pt_regs *regs) { unsigned long flags; __save_flags(flags); __cli(); printf("Keyboard interrupt\n"); xmon(regs); __restore_flags(flags); } int xmon_bpt(struct pt_regs *regs) { struct bpt *bp; bp = at_breakpoint(regs->nip); if (!bp) return 0; if (bp->count) { --bp->count; remove_bpts(); excprint(regs); xmon_trace[smp_processor_id()] = BRSTEP; regs->msr |= 0x400; } else { printf("Stopped at breakpoint %x (%lx %s)\n", (bp - bpts)+1, bp->address, bp->funcname); xmon(regs); } return 1; } int xmon_sstep(struct pt_regs *regs) { if (!xmon_trace[smp_processor_id()]) return 0; if (xmon_trace[smp_processor_id()] == BRSTEP) { xmon_trace[smp_processor_id()] = 0; insert_bpts(); } else { xmon(regs); } return 1; } int xmon_dabr_match(struct pt_regs *regs) { if (dabr.enabled && dabr.count) { --dabr.count; remove_bpts(); excprint(regs); xmon_trace[smp_processor_id()] = BRSTEP; regs->msr |= 0x400; } else { dabr.instr = regs->nip; xmon(regs); } return 1; } int xmon_iabr_match(struct pt_regs *regs) { if (iabr.enabled && iabr.count) { --iabr.count; remove_bpts(); excprint(regs); xmon_trace[smp_processor_id()] = BRSTEP; regs->msr |= 0x400; } else { xmon(regs); } return 1; } static struct bpt * at_breakpoint(unsigned long pc) { int i; struct bpt *bp; if (dabr.enabled && pc == dabr.instr) return &dabr; if (iabr.enabled && pc == iabr.address) return &iabr; bp = bpts; for (i = 0; i < NBPTS; ++i, ++bp) if (bp->enabled && pc == bp->address) return bp; return 0; } static void insert_bpts() { int i; struct bpt *bp; if (naca->platform != PLATFORM_PSERIES) return; bp = bpts; for (i = 0; i < NBPTS; ++i, ++bp) { if (!bp->enabled) continue; if (mread(bp->address, &bp->instr, 4) != 4 || mwrite(bp->address, &bpinstr, 4) != 4) { printf("Couldn't insert breakpoint at %x, disabling\n", bp->address); bp->enabled = 0; } else { store_inst((void *)bp->address); } } if (!__is_processor(PV_POWER4) && !__is_processor(PV_POWER4p)) { if (dabr.enabled) set_dabr(dabr.address); if (iabr.enabled) set_iabr(iabr.address); } } static void remove_bpts() { int i; struct bpt *bp; unsigned instr; if (naca->platform != PLATFORM_PSERIES) return; if (!__is_processor(PV_POWER4) && !__is_processor(PV_POWER4p)) { set_dabr(0); set_iabr(0); } bp = bpts; for (i = 0; i < NBPTS; ++i, ++bp) { if (!bp->enabled) continue; if (mread(bp->address, &instr, 4) == 4 && instr == bpinstr && mwrite(bp->address, &bp->instr, 4) != 4) printf("Couldn't remove breakpoint at %x\n", bp->address); else store_inst((void *)bp->address); } } static char *last_cmd; /* Command interpreting routine */ static int cmds(struct pt_regs *excp) { int cmd; last_cmd = NULL; for(;;) { #ifdef CONFIG_SMP printf("%d:", smp_processor_id()); #endif /* CONFIG_SMP */ printf("mon> "); fflush(stdout); flush_input(); termch = 0; cmd = skipbl(); if( cmd == '\n' ) { if (last_cmd == NULL) continue; take_input(last_cmd); last_cmd = NULL; cmd = inchar(); } switch (cmd) { case 'z': printf("Rebooting machine now..."); machine_restart(NULL); break; case 'Z': printf("Halting machine now..."); machine_halt(); break; case 'm': cmd = inchar(); switch (cmd) { case 'm': case 's': case 'd': memops(cmd); break; case 'l': memlocate(); break; case 'z': memzcan(); break; case 'x': mem_translate(); break; case 'c': mem_check(); break; case 'j': mem_map_check_slab(); break; case 'f': mem_find_real(); break; case 'e': mem_find_vsid(); break; case 'r': mem_check_dup_rpn(); break; case 'i': show_mem(); break; case 'o': mem_check_pagetable_vsids (); break; case 'q': mem_map_lock_pages() ; break; default: termch = cmd; memex(); } break; case 'd': dump(); break; case 'r': if (excp != NULL) prregs(excp); /* print regs */ break; case 'e': if (excp == NULL) printf("No exception information\n"); else excprint(excp); break; case 'M': print_sysmap(); break; case 'S': super_regs(); break; case 't': backtrace(excp); break; case 'f': cacheflush(); break; case 'h': dump_hash_table(); break; case 's': case 'x': case EOF: return cmd; case '?': printf(help_string); break; case 'p': show_state(); break; case 'b': bpt_cmds(); break; case 'C': csum(); break; #ifdef CONFIG_SMP case 'c': cpu_cmd(); break; #endif /* CONFIG_SMP */ case 'T': debug_trace(); break; default: printf("Unrecognized command: "); do { if( ' ' < cmd && cmd <= '~' ) putchar(cmd); else printf("\\x%x", cmd); cmd = inchar(); } while (cmd != '\n'); printf(" (type ? for help)\n"); break; } } } #ifdef CONFIG_SMP static void cpu_cmd(void) { unsigned long cpu; int timeout; int cmd; cmd = inchar(); if (cmd == 'i') { printf("stopping all cpus\n"); /* interrupt other cpu(s) */ cpu = MSG_ALL_BUT_SELF; smp_send_xmon_break(cpu); return; } termch = cmd; if (!scanhex(&cpu)) { /* print cpus waiting or in xmon */ printf("cpus stopped:"); for (cpu = 0; cpu < NR_CPUS; ++cpu) { if (test_bit(cpu, &cpus_in_xmon)) { printf(" %d", cpu); if (cpu == smp_processor_id()) printf("*", cpu); } } printf("\n"); return; } /* try to switch to cpu specified */ take_xmon = cpu; timeout = 10000000; while (take_xmon >= 0) { if (--timeout == 0) { /* yes there's a race here */ take_xmon = -1; printf("cpu %u didn't take control\n", cpu); return; } } /* now have to wait to be given control back */ while (test_and_set_bit(0, &got_xmon)) { if (take_xmon == smp_processor_id()) { take_xmon = -1; break; } } } #endif /* CONFIG_SMP */ static unsigned short fcstab[256] = { 0x0000, 0x1189, 0x2312, 0x329b, 0x4624, 0x57ad, 0x6536, 0x74bf, 0x8c48, 0x9dc1, 0xaf5a, 0xbed3, 0xca6c, 0xdbe5, 0xe97e, 0xf8f7, 0x1081, 0x0108, 0x3393, 0x221a, 0x56a5, 0x472c, 0x75b7, 0x643e, 0x9cc9, 0x8d40, 0xbfdb, 0xae52, 0xdaed, 0xcb64, 0xf9ff, 0xe876, 0x2102, 0x308b, 0x0210, 0x1399, 0x6726, 0x76af, 0x4434, 0x55bd, 0xad4a, 0xbcc3, 0x8e58, 0x9fd1, 0xeb6e, 0xfae7, 0xc87c, 0xd9f5, 0x3183, 0x200a, 0x1291, 0x0318, 0x77a7, 0x662e, 0x54b5, 0x453c, 0xbdcb, 0xac42, 0x9ed9, 0x8f50, 0xfbef, 0xea66, 0xd8fd, 0xc974, 0x4204, 0x538d, 0x6116, 0x709f, 0x0420, 0x15a9, 0x2732, 0x36bb, 0xce4c, 0xdfc5, 0xed5e, 0xfcd7, 0x8868, 0x99e1, 0xab7a, 0xbaf3, 0x5285, 0x430c, 0x7197, 0x601e, 0x14a1, 0x0528, 0x37b3, 0x263a, 0xdecd, 0xcf44, 0xfddf, 0xec56, 0x98e9, 0x8960, 0xbbfb, 0xaa72, 0x6306, 0x728f, 0x4014, 0x519d, 0x2522, 0x34ab, 0x0630, 0x17b9, 0xef4e, 0xfec7, 0xcc5c, 0xddd5, 0xa96a, 0xb8e3, 0x8a78, 0x9bf1, 0x7387, 0x620e, 0x5095, 0x411c, 0x35a3, 0x242a, 0x16b1, 0x0738, 0xffcf, 0xee46, 0xdcdd, 0xcd54, 0xb9eb, 0xa862, 0x9af9, 0x8b70, 0x8408, 0x9581, 0xa71a, 0xb693, 0xc22c, 0xd3a5, 0xe13e, 0xf0b7, 0x0840, 0x19c9, 0x2b52, 0x3adb, 0x4e64, 0x5fed, 0x6d76, 0x7cff, 0x9489, 0x8500, 0xb79b, 0xa612, 0xd2ad, 0xc324, 0xf1bf, 0xe036, 0x18c1, 0x0948, 0x3bd3, 0x2a5a, 0x5ee5, 0x4f6c, 0x7df7, 0x6c7e, 0xa50a, 0xb483, 0x8618, 0x9791, 0xe32e, 0xf2a7, 0xc03c, 0xd1b5, 0x2942, 0x38cb, 0x0a50, 0x1bd9, 0x6f66, 0x7eef, 0x4c74, 0x5dfd, 0xb58b, 0xa402, 0x9699, 0x8710, 0xf3af, 0xe226, 0xd0bd, 0xc134, 0x39c3, 0x284a, 0x1ad1, 0x0b58, 0x7fe7, 0x6e6e, 0x5cf5, 0x4d7c, 0xc60c, 0xd785, 0xe51e, 0xf497, 0x8028, 0x91a1, 0xa33a, 0xb2b3, 0x4a44, 0x5bcd, 0x6956, 0x78df, 0x0c60, 0x1de9, 0x2f72, 0x3efb, 0xd68d, 0xc704, 0xf59f, 0xe416, 0x90a9, 0x8120, 0xb3bb, 0xa232, 0x5ac5, 0x4b4c, 0x79d7, 0x685e, 0x1ce1, 0x0d68, 0x3ff3, 0x2e7a, 0xe70e, 0xf687, 0xc41c, 0xd595, 0xa12a, 0xb0a3, 0x8238, 0x93b1, 0x6b46, 0x7acf, 0x4854, 0x59dd, 0x2d62, 0x3ceb, 0x0e70, 0x1ff9, 0xf78f, 0xe606, 0xd49d, 0xc514, 0xb1ab, 0xa022, 0x92b9, 0x8330, 0x7bc7, 0x6a4e, 0x58d5, 0x495c, 0x3de3, 0x2c6a, 0x1ef1, 0x0f78 }; #define FCS(fcs, c) (((fcs) >> 8) ^ fcstab[((fcs) ^ (c)) & 0xff]) static void csum(void) { unsigned int i; unsigned short fcs; unsigned char v; if (!scanhex(&adrs)) return; if (!scanhex(&ncsum)) return; fcs = 0xffff; for (i = 0; i < ncsum; ++i) { if (mread(adrs+i, &v, 1) == 0) { printf("csum stopped at %x\n", adrs+i); break; } fcs = FCS(fcs, v); } printf("%x\n", fcs); } static char *breakpoint_help_string = "Breakpoint command usage:\n" "b show breakpoints\n" "b [cnt] set breakpoint at given instr addr\n" "bc clear all breakpoints\n" "bc clear breakpoint number n or at addr\n" "bi [cnt] set hardware instr breakpoint (broken?)\n" "bd [cnt] set hardware data breakpoint (broken?)\n" ""; static void bpt_cmds(void) { int cmd; unsigned long a; int mode, i; struct bpt *bp; struct tbtable tab; cmd = inchar(); switch (cmd) { case 'd': /* bd - hardware data breakpoint */ if (__is_processor(PV_POWER4) || __is_processor(PV_POWER4p)) { printf("Not implemented on POWER4\n"); break; } mode = 7; cmd = inchar(); if (cmd == 'r') mode = 5; else if (cmd == 'w') mode = 6; else termch = cmd; dabr.address = 0; dabr.count = 0; dabr.enabled = scanhex(&dabr.address); scanhex(&dabr.count); if (dabr.enabled) dabr.address = (dabr.address & ~7) | mode; break; case 'i': /* bi - hardware instr breakpoint */ if (__is_processor(PV_POWER4) || __is_processor(PV_POWER4p)) { break; } iabr.address = 0; iabr.count = 0; iabr.enabled = scanhex(&iabr.address); if (iabr.enabled) iabr.address |= 3; scanhex(&iabr.count); break; case 'c': if (!scanhex(&a)) { /* clear all breakpoints */ for (i = 0; i < NBPTS; ++i) bpts[i].enabled = 0; iabr.enabled = 0; dabr.enabled = 0; printf("All breakpoints cleared\n"); } else { if (a <= NBPTS && a >= 1) { /* assume a breakpoint number */ --a; /* bp nums are 1 based */ bp = &bpts[a]; } else { /* assume a breakpoint address */ bp = at_breakpoint(a); } if (bp == 0) { printf("No breakpoint at %x\n", a); } else { printf("Cleared breakpoint %x (%lx %s)\n", (bp - bpts)+1, bp->address, bp->funcname); bp->enabled = 0; } } break; case '?': printf(breakpoint_help_string); break; default: termch = cmd; cmd = skipbl(); if (cmd == '?') { printf(breakpoint_help_string); break; } termch = cmd; if (!scanhex(&a)) { /* print all breakpoints */ int bpnum; printf(" type address count\n"); if (dabr.enabled) { printf(" data %.16lx %8x [", dabr.address & ~7, dabr.count); if (dabr.address & 1) printf("r"); if (dabr.address & 2) printf("w"); printf("]\n"); } if (iabr.enabled) printf(" inst %.16lx %8x\n", iabr.address & ~3, iabr.count); for (bp = bpts, bpnum = 1; bp < &bpts[NBPTS]; ++bp, ++bpnum) if (bp->enabled) printf("%2x trap %.16lx %8x %s\n", bpnum, bp->address, bp->count, bp->funcname); break; } bp = at_breakpoint(a); if (bp == 0) { for (bp = bpts; bp < &bpts[NBPTS]; ++bp) if (!bp->enabled) break; if (bp >= &bpts[NBPTS]) { printf("Sorry, no free breakpoints. Please clear one first.\n"); break; } } bp->enabled = 1; bp->address = a; bp->count = 0; scanhex(&bp->count); /* Find the function name just once. */ bp->funcname[0] = '\0'; if (find_tb_table(bp->address, &tab) && tab.name[0]) { /* Got a nice name for it. */ int delta = bp->address - tab.funcstart; sprintf(bp->funcname, "%s+0x%x", tab.name, delta); } printf("Set breakpoint %2x trap %.16lx %8x %s\n", (bp-bpts)+1, bp->address, bp->count, bp->funcname); break; } } /* Very cheap human name for vector lookup. */ static const char *getvecname(unsigned long vec) { char *ret; switch (vec) { case 0x100: ret = "(System Reset)"; break; case 0x200: ret = "(Machine Check)"; break; case 0x300: ret = "(Data Access)"; break; case 0x400: ret = "(Instruction Access)"; break; case 0x500: ret = "(Hardware Interrupt)"; break; case 0x600: ret = "(Alignment)"; break; case 0x700: ret = "(Program Check)"; break; case 0x800: ret = "(FPU Unavailable)"; break; case 0x900: ret = "(Decrementer)"; break; case 0xc00: ret = "(System Call)"; break; case 0xd00: ret = "(Single Step)"; break; case 0xf00: ret = "(Performance Monitor)"; break; default: ret = ""; } return ret; } static void backtrace(struct pt_regs *excp) { unsigned long sp; unsigned long lr; unsigned long stack[3]; struct pt_regs regs; struct tbtable tab; int framecount; char *funcname; /* declare these as raw ptrs so we don't get func descriptors */ extern void *ret_from_except, *ret_from_syscall_1; if (excp != NULL) { lr = excp->link; sp = excp->gpr[1]; } else { /* Use care not to call any function before this point so the saved lr has a chance of being good. */ asm volatile ("mflr %0" : "=r" (lr) :); sp = getsp(); } scanhex(&sp); scannl(); for (framecount = 0; sp != 0 && framecount < MAXFRAMECOUNT; sp = stack[0], framecount++) { if (mread(sp, stack, sizeof(stack)) != sizeof(stack)) break; printf("%.16lx %.16lx", sp, stack[2]); /* TAI -- for now only the ones cast to unsigned long will match. * Need to test the rest... */ if ((stack[2] == (unsigned long)ret_from_except && (funcname = "ret_from_except")) || (stack[2] == (unsigned long)ret_from_syscall_1 && (funcname = "ret_from_syscall_1")) ) { printf(" %s\n", funcname); if (mread(sp+112, ®s, sizeof(regs)) != sizeof(regs)) break; printf("exception: %lx %s regs %lx\n", regs.trap, getvecname(regs.trap), sp+112); printf(" %.16lx", regs.nip); if ((regs.nip & 0xffffffff00000000UL) && find_tb_table(regs.nip, &tab)) { int delta = regs.nip-tab.funcstart; if (delta < 0) printf(" "); else printf(" %s+0x%x", tab.name, delta); } printf("\n"); if (regs.gpr[1] < sp) { printf("\n", regs.gpr[1]); break; } sp = regs.gpr[1]; if (mread(sp, stack, sizeof(stack)) != sizeof(stack)) break; } else { if (stack[2] && find_tb_table(stack[2], &tab)) { int delta = stack[2]-tab.funcstart; if (delta < 0) printf(" "); else printf(" %s+0x%x", tab.name, delta); } printf("\n"); } if (stack[0] && stack[0] <= sp) { if ((stack[0] & 0xffffffff00000000UL) == 0) printf("\n", stack[0]); else printf("\n", stack[0]); break; } } if (framecount >= MAXFRAMECOUNT) printf("\n"); } int getsp() { int x; asm("mr %0,1" : "=r" (x) :); return x; } spinlock_t exception_print_lock = SPIN_LOCK_UNLOCKED; void excprint(struct pt_regs *fp) { struct task_struct *c; struct tbtable tab; unsigned long flags; spin_lock_irqsave(&exception_print_lock, flags); #ifdef CONFIG_SMP printf("cpu %d: ", smp_processor_id()); #endif /* CONFIG_SMP */ printf("Vector: %lx %s at [%lx]\n", fp->trap, getvecname(fp->trap), fp); printf(" pc: %lx", fp->nip); if (find_tb_table(fp->nip, &tab) && tab.name[0]) { /* Got a nice name for it */ int delta = fp->nip - tab.funcstart; printf(" (%s+0x%x)", tab.name, delta); } printf("\n"); printf(" lr: %lx", fp->link); if (find_tb_table(fp->link, &tab) && tab.name[0]) { /* Got a nice name for it */ int delta = fp->link - tab.funcstart; printf(" (%s+0x%x)", tab.name, delta); } printf("\n"); printf(" sp: %lx\n", fp->gpr[1]); printf(" msr: %lx\n", fp->msr); if (fp->trap == 0x300 || fp->trap == 0x600) { printf(" dar: %lx\n", fp->dar); printf(" dsisr: %lx\n", fp->dsisr); } c = current; printf(" current = 0x%lx\n", c); printf(" paca = 0x%lx\n", get_paca()); if (c) { printf(" current = %lx, pid = %ld, comm = %s\n", c, c->pid, c->comm); } spin_unlock_irqrestore(&exception_print_lock, flags); } void prregs(struct pt_regs *fp) { int n; unsigned long base; if (scanhex((void *)&base)) fp = (struct pt_regs *) base; for (n = 0; n < 16; ++n) printf("R%.2ld = %.16lx R%.2ld = %.16lx\n", n, fp->gpr[n], n+16, fp->gpr[n+16]); printf("pc = %.16lx msr = %.16lx\nlr = %.16lx cr = %.16lx\n", fp->nip, fp->msr, fp->link, fp->ccr); printf("ctr = %.16lx xer = %.16lx trap = %8lx\n", fp->ctr, fp->xer, fp->trap); } void cacheflush(void) { int cmd; unsigned long nflush; cmd = inchar(); if (cmd != 'i') termch = cmd; scanhex((void *)&adrs); if (termch != '\n') termch = 0; nflush = 1; scanhex(&nflush); nflush = (nflush + 31) / 32; if (cmd != 'i') { for (; nflush > 0; --nflush, adrs += 0x20) cflush((void *) adrs); } else { for (; nflush > 0; --nflush, adrs += 0x20) cinval((void *) adrs); } } unsigned long read_spr(int n) { unsigned int instrs[2]; unsigned long (*code)(void); unsigned long opd[3]; instrs[0] = 0x7c6002a6 + ((n & 0x1F) << 16) + ((n & 0x3e0) << 6); instrs[1] = 0x4e800020; opd[0] = (unsigned long)instrs; opd[1] = 0; opd[2] = 0; store_inst(instrs); store_inst(instrs+1); code = (unsigned long (*)(void)) opd; return code(); } void write_spr(int n, unsigned long val) { unsigned int instrs[2]; unsigned long (*code)(unsigned long); unsigned long opd[3]; instrs[0] = 0x7c6003a6 + ((n & 0x1F) << 16) + ((n & 0x3e0) << 6); instrs[1] = 0x4e800020; opd[0] = (unsigned long)instrs; opd[1] = 0; opd[2] = 0; store_inst(instrs); store_inst(instrs+1); code = (unsigned long (*)(unsigned long)) opd; code(val); } static unsigned long regno; extern char exc_prolog; extern char dec_exc; void print_sysmap(void) { extern char *sysmap; if ( sysmap ) printf("System.map: \n%s", sysmap); } void super_regs() { int i, cmd; unsigned long val; struct paca_struct* ptrPaca = NULL; struct ItLpPaca* ptrLpPaca = NULL; struct ItLpRegSave* ptrLpRegSave = NULL; cmd = skipbl(); if (cmd == '\n') { unsigned long sp, toc; asm("mr %0,1" : "=r" (sp) :); asm("mr %0,2" : "=r" (toc) :); printf("msr = %.16lx sprg0= %.16lx\n", get_msr(), get_sprg0()); printf("pvr = %.16lx sprg1= %.16lx\n", get_pvr(), get_sprg1()); printf("dec = %.16lx sprg2= %.16lx\n", get_dec(), get_sprg2()); printf("sp = %.16lx sprg3= %.16lx\n", sp, get_sprg3()); printf("toc = %.16lx dar = %.16lx\n", toc, get_dar()); printf("srr0 = %.16lx srr1 = %.16lx\n", get_srr0(), get_srr1()); printf("asr = %.16lx\n", mfasr()); for (i = 0; i < 8; ++i) printf("sr%.2ld = %.16lx sr%.2ld = %.16lx\n", i, get_sr(i), i+8, get_sr(i+8)); // Dump out relevant Paca data areas. printf("Paca: \n"); ptrPaca = get_paca(); printf(" Local Processor Control Area (LpPaca): \n"); ptrLpPaca = ptrPaca->xLpPacaPtr; printf(" Saved Srr0=%.16lx Saved Srr1=%.16lx \n", ptrLpPaca->xSavedSrr0, ptrLpPaca->xSavedSrr1); printf(" Saved Gpr3=%.16lx Saved Gpr4=%.16lx \n", ptrLpPaca->xSavedGpr3, ptrLpPaca->xSavedGpr4); printf(" Saved Gpr5=%.16lx \n", ptrLpPaca->xSavedGpr5); printf(" Local Processor Register Save Area (LpRegSave): \n"); ptrLpRegSave = ptrPaca->xLpRegSavePtr; printf(" Saved Sprg0=%.16lx Saved Sprg1=%.16lx \n", ptrLpRegSave->xSPRG0, ptrLpRegSave->xSPRG0); printf(" Saved Sprg2=%.16lx Saved Sprg3=%.16lx \n", ptrLpRegSave->xSPRG2, ptrLpRegSave->xSPRG3); printf(" Saved Msr =%.16lx Saved Nia =%.16lx \n", ptrLpRegSave->xMSR, ptrLpRegSave->xNIA); return; } scanhex(®no); switch (cmd) { case 'w': val = read_spr(regno); scanhex(&val); write_spr(regno, val); /* fall through */ case 'r': printf("spr %lx = %lx\n", regno, read_spr(regno)); break; case 's': val = get_sr(regno); scanhex(&val); set_sr(regno, val); break; case 'm': val = get_msr(); scanhex(&val); set_msrd(val); break; } scannl(); } #ifndef CONFIG_PPC64BRIDGE static void dump_hash_table_seg(unsigned seg, unsigned start, unsigned end) { extern void *Hash; extern unsigned long Hash_size; unsigned *htab = Hash; unsigned hsize = Hash_size; unsigned v, hmask, va, last_va; int found, last_found, i; unsigned *hg, w1, last_w2, last_va0; last_found = 0; hmask = hsize / 64 - 1; va = start; start = (start >> 12) & 0xffff; end = (end >> 12) & 0xffff; for (v = start; v < end; ++v) { found = 0; hg = htab + (((v ^ seg) & hmask) * 16); w1 = 0x80000000 | (seg << 7) | (v >> 10); for (i = 0; i < 8; ++i, hg += 2) { if (*hg == w1) { found = 1; break; } } if (!found) { w1 ^= 0x40; hg = htab + ((~(v ^ seg) & hmask) * 16); for (i = 0; i < 8; ++i, hg += 2) { if (*hg == w1) { found = 1; break; } } } if (!(last_found && found && (hg[1] & ~0x180) == last_w2 + 4096)) { if (last_found) { if (last_va != last_va0) printf(" ... %x", last_va); printf("\n"); } if (found) { printf("%x to %x", va, hg[1]); last_va0 = va; } last_found = found; } if (found) { last_w2 = hg[1] & ~0x180; last_va = va; } va += 4096; } if (last_found) printf(" ... %x\n", last_va); } #else /* CONFIG_PPC64BRIDGE */ static void dump_hash_table_seg(unsigned seg, unsigned start, unsigned end) { extern void *Hash; extern unsigned long Hash_size; unsigned *htab = Hash; unsigned hsize = Hash_size; unsigned v, hmask, va, last_va; int found, last_found, i; unsigned *hg, w1, last_w2, last_va0; last_found = 0; hmask = hsize / 128 - 1; va = start; start = (start >> 12) & 0xffff; end = (end >> 12) & 0xffff; for (v = start; v < end; ++v) { found = 0; hg = htab + (((v ^ seg) & hmask) * 32); w1 = 1 | (seg << 12) | ((v & 0xf800) >> 4); for (i = 0; i < 8; ++i, hg += 4) { if (hg[1] == w1) { found = 1; break; } } if (!found) { w1 ^= 2; hg = htab + ((~(v ^ seg) & hmask) * 32); for (i = 0; i < 8; ++i, hg += 4) { if (hg[1] == w1) { found = 1; break; } } } if (!(last_found && found && (hg[3] & ~0x180) == last_w2 + 4096)) { if (last_found) { if (last_va != last_va0) printf(" ... %x", last_va); printf("\n"); } if (found) { printf("%x to %x", va, hg[3]); last_va0 = va; } last_found = found; } if (found) { last_w2 = hg[3] & ~0x180; last_va = va; } va += 4096; } if (last_found) printf(" ... %x\n", last_va); } #endif /* CONFIG_PPC64BRIDGE */ static unsigned long hash_ctx; static unsigned long hash_start; static unsigned long hash_end; static void dump_hash_table() { int seg; unsigned seg_start, seg_end; hash_ctx = 0; hash_start = 0; hash_end = 0xfffff000; scanhex(&hash_ctx); scanhex(&hash_start); scanhex(&hash_end); printf("Mappings for context %x\n", hash_ctx); seg_start = hash_start; for (seg = hash_start >> 28; seg <= hash_end >> 28; ++seg) { seg_end = (seg << 28) | 0x0ffff000; if (seg_end > hash_end) seg_end = hash_end; dump_hash_table_seg((hash_ctx << 4) + seg, seg_start, seg_end); seg_start = seg_end + 0x1000; } } int mread(unsigned long adrs, void *buf, int size) { volatile int n; char *p, *q; n = 0; if( setjmp(bus_error_jmp) == 0 ){ debugger_fault_handler = handle_fault; sync(); p = (char *) adrs; q = (char *) buf; switch (size) { case 2: *(short *)q = *(short *)p; break; case 4: *(int *)q = *(int *)p; break; default: for( ; n < size; ++n ) { *q++ = *p++; sync(); } } sync(); /* wait a little while to see if we get a machine check */ __delay(200); n = size; } debugger_fault_handler = 0; return n; } int mwrite(unsigned long adrs, void *buf, int size) { volatile int n; char *p, *q; n = 0; if( setjmp(bus_error_jmp) == 0 ){ debugger_fault_handler = handle_fault; sync(); p = (char *) adrs; q = (char *) buf; switch (size) { case 2: *(short *)p = *(short *)q; break; case 4: *(int *)p = *(int *)q; break; default: for( ; n < size; ++n ) { *p++ = *q++; sync(); } } sync(); /* wait a little while to see if we get a machine check */ __delay(200); n = size; } else { printf("*** Error writing address %x\n", adrs + n); } debugger_fault_handler = 0; return n; } static int fault_type; static char *fault_chars[] = { "--", "**", "##" }; static void handle_fault(struct pt_regs *regs) { fault_type = regs->trap == 0x200? 0: regs->trap == 0x300? 1: 2; longjmp(bus_error_jmp, 1); } #define SWAP(a, b, t) ((t) = (a), (a) = (b), (b) = (t)) void byterev(unsigned char *val, int size) { int t; switch (size) { case 2: SWAP(val[0], val[1], t); break; case 4: SWAP(val[0], val[3], t); SWAP(val[1], val[2], t); break; case 8: /* is there really any use for this? */ SWAP(val[0], val[7], t); SWAP(val[1], val[6], t); SWAP(val[2], val[5], t); SWAP(val[3], val[4], t); break; } } static int brev; static int mnoread; static char *memex_help_string = "Memory examine command usage:\n" "m [addr] [flags] examine/change memory\n" " addr is optional. will start where left off.\n" " flags may include chars from this set:\n" " b modify by bytes (default)\n" " w modify by words (2 byte)\n" " l modify by longs (4 byte)\n" " d modify by doubleword (8 byte)\n" " r toggle reverse byte order mode\n" " n do not read memory (for i/o spaces)\n" " . ok to read (default)\n" "NOTE: flags are saved as defaults\n" ""; static char *memex_subcmd_help_string = "Memory examine subcommands:\n" " hexval write this val to current location\n" " 'string' write chars from string to this location\n" " ' increment address\n" " ^ decrement address\n" " / increment addr by 0x10. //=0x100, ///=0x1000, etc\n" " \\ decrement addr by 0x10. \\\\=0x100, \\\\\\=0x1000, etc\n" " ` clear no-read flag\n" " ; stay at this addr\n" " v change to byte mode\n" " w change to word (2 byte) mode\n" " l change to long (4 byte) mode\n" " u change to doubleword (8 byte) mode\n" " m addr change current addr\n" " n toggle no-read flag\n" " r toggle byte reverse flag\n" " < count back up count bytes\n" " > count skip forward count bytes\n" " x exit this mode\n" ""; void memex() { int cmd, inc, i, nslash; unsigned long n; unsigned char val[16]; scanhex((void *)&adrs); cmd = skipbl(); if (cmd == '?') { printf(memex_help_string); return; } else { termch = cmd; } last_cmd = "m\n"; while ((cmd = skipbl()) != '\n') { switch( cmd ){ case 'b': size = 1; break; case 'w': size = 2; break; case 'l': size = 4; break; case 'd': size = 8; break; case 'r': brev = !brev; break; case 'n': mnoread = 1; break; case '.': mnoread = 0; break; } } if( size <= 0 ) size = 1; else if( size > 8 ) size = 8; for(;;){ if (!mnoread) n = mread(adrs, val, size); printf("%.16x%c", adrs, brev? 'r': ' '); if (!mnoread) { if (brev) byterev(val, size); putchar(' '); for (i = 0; i < n; ++i) printf("%.2x", val[i]); for (; i < size; ++i) printf("%s", fault_chars[fault_type]); } putchar(' '); inc = size; nslash = 0; for(;;){ if( scanhex(&n) ){ for (i = 0; i < size; ++i) val[i] = n >> (i * 8); if (!brev) byterev(val, size); mwrite(adrs, val, size); inc = size; } cmd = skipbl(); if (cmd == '\n') break; inc = 0; switch (cmd) { case '\'': for(;;){ n = inchar(); if( n == '\\' ) n = bsesc(); else if( n == '\'' ) break; for (i = 0; i < size; ++i) val[i] = n >> (i * 8); if (!brev) byterev(val, size); mwrite(adrs, val, size); adrs += size; } adrs -= size; inc = size; break; case ',': adrs += size; break; case '.': mnoread = 0; break; case ';': break; case 'x': case EOF: scannl(); return; case 'b': case 'v': size = 1; break; case 'w': size = 2; break; case 'l': size = 4; break; case 'u': size = 8; break; case '^': adrs -= size; break; break; case '/': if (nslash > 0) adrs -= 1 << nslash; else nslash = 0; nslash += 4; adrs += 1 << nslash; break; case '\\': if (nslash < 0) adrs += 1 << -nslash; else nslash = 0; nslash -= 4; adrs -= 1 << -nslash; break; case 'm': scanhex((void *)&adrs); break; case 'n': mnoread = 1; break; case 'r': brev = !brev; break; case '<': n = size; scanhex(&n); adrs -= n; break; case '>': n = size; scanhex(&n); adrs += n; break; case '?': printf(memex_subcmd_help_string); break; } } adrs += inc; } } int bsesc() { int c; c = inchar(); switch( c ){ case 'n': c = '\n'; break; case 'r': c = '\r'; break; case 'b': c = '\b'; break; case 't': c = '\t'; break; } return c; } #define isxdigit(c) (('0' <= (c) && (c) <= '9') \ || ('a' <= (c) && (c) <= 'f') \ || ('A' <= (c) && (c) <= 'F')) void dump() { int c; c = inchar(); if ((isxdigit(c) && c != 'f' && c != 'd') || c == '\n') termch = c; scanhex((void *)&adrs); if( termch != '\n') termch = 0; if( c == 'i' ){ scanhex(&nidump); if( nidump == 0 ) nidump = 16; adrs += ppc_inst_dump(adrs, nidump); last_cmd = "di\n"; } else { scanhex(&ndump); if( ndump == 0 ) ndump = 64; prdump(adrs, ndump); adrs += ndump; last_cmd = "d\n"; } } void prdump(unsigned long adrs, long ndump) { long n, m, c, r, nr; unsigned char temp[16]; for( n = ndump; n > 0; ){ printf("%.16lx", adrs); putchar(' '); r = n < 16? n: 16; nr = mread(adrs, temp, r); adrs += nr; for( m = 0; m < r; ++m ){ if ((m & 7) == 0 && m > 0) putchar(' '); if( m < nr ) printf("%.2x", temp[m]); else printf("%s", fault_chars[fault_type]); } for(; m < 16; ++m ) printf(" "); printf(" |"); for( m = 0; m < r; ++m ){ if( m < nr ){ c = temp[m]; putchar(' ' <= c && c <= '~'? c: '.'); } else putchar(' '); } n -= r; for(; m < 16; ++m ) putchar(' '); printf("|\n"); if( nr < r ) break; } } int ppc_inst_dump(unsigned long adr, long count) { int nr, dotted; unsigned long first_adr; unsigned long inst, last_inst; unsigned char val[4]; dotted = 0; for (first_adr = adr; count > 0; --count, adr += 4){ nr = mread(adr, val, 4); if( nr == 0 ){ const char *x = fault_chars[fault_type]; printf("%.16lx %s%s%s%s\n", adr, x, x, x, x); break; } inst = GETWORD(val); if (adr > first_adr && inst == last_inst) { if (!dotted) { printf(" ...\n"); dotted = 1; } continue; } dotted = 0; last_inst = inst; printf("%.16lx ", adr); printf("%.8x\t", inst); print_insn_big_powerpc(stdout, inst, adr); /* always returns 4 */ printf("\n"); } return adr - first_adr; } void print_address(unsigned long addr) { printf("0x%lx", addr); } /* * Memory operations - move, set, print differences */ static unsigned long mdest; /* destination address */ static unsigned long msrc; /* source address */ static unsigned long mval; /* byte value to set memory to */ static unsigned long mcount; /* # bytes to affect */ static unsigned long mdiffs; /* max # differences to print */ void memops(int cmd) { scanhex((void *)&mdest); if( termch != '\n' ) termch = 0; scanhex((void *)(cmd == 's'? &mval: &msrc)); if( termch != '\n' ) termch = 0; scanhex((void *)&mcount); switch( cmd ){ case 'm': memmove((void *)mdest, (void *)msrc, mcount); break; case 's': memset((void *)mdest, mval, mcount); break; case 'd': if( termch != '\n' ) termch = 0; scanhex((void *)&mdiffs); memdiffs((unsigned char *)mdest, (unsigned char *)msrc, mcount, mdiffs); break; } } void memdiffs(unsigned char *p1, unsigned char *p2, unsigned nb, unsigned maxpr) { unsigned n, prt; prt = 0; for( n = nb; n > 0; --n ) if( *p1++ != *p2++ ) if( ++prt <= maxpr ) printf("%.16x %.2x # %.16x %.2x\n", p1 - 1, p1[-1], p2 - 1, p2[-1]); if( prt > maxpr ) printf("Total of %d differences\n", prt); } static unsigned mend; static unsigned mask; void memlocate() { unsigned a, n; unsigned char val[4]; last_cmd = "ml"; scanhex((void *)&mdest); if (termch != '\n') { termch = 0; scanhex((void *)&mend); if (termch != '\n') { termch = 0; scanhex((void *)&mval); mask = ~0; if (termch != '\n') termch = 0; scanhex((void *)&mask); } } n = 0; for (a = mdest; a < mend; a += 4) { if (mread(a, val, 4) == 4 && ((GETWORD(val) ^ mval) & mask) == 0) { printf("%.16x: %.16x\n", a, GETWORD(val)); if (++n >= 10) break; } } } static unsigned long mskip = 0x1000; static unsigned long mlim = 0xffffffff; void memzcan() { unsigned char v; unsigned a; int ok, ook; scanhex(&mdest); if (termch != '\n') termch = 0; scanhex(&mskip); if (termch != '\n') termch = 0; scanhex(&mlim); ook = 0; for (a = mdest; a < mlim; a += mskip) { ok = mread(a, &v, 1); if (ok && !ook) { printf("%.8x .. ", a); fflush(stdout); } else if (!ok && ook) printf("%.8x\n", a - mskip); ook = ok; if (a + mskip < a) break; } if (ook) printf("%.8x\n", a - mskip); } /* Input scanning routines */ int skipbl() { int c; if( termch != 0 ){ c = termch; termch = 0; } else c = inchar(); while( c == ' ' || c == '\t' ) c = inchar(); return c; } int scanhex(vp) unsigned long *vp; { int c, d; unsigned long v; c = skipbl(); d = hexdigit(c); if( d == EOF ){ termch = c; return 0; } v = 0; do { v = (v << 4) + d; c = inchar(); d = hexdigit(c); } while( d != EOF ); termch = c; *vp = v; return 1; } void scannl() { int c; c = termch; termch = 0; while( c != '\n' ) c = inchar(); } int hexdigit(int c) { if( '0' <= c && c <= '9' ) return c - '0'; if( 'A' <= c && c <= 'F' ) return c - ('A' - 10); if( 'a' <= c && c <= 'f' ) return c - ('a' - 10); return EOF; } void getstring(char *s, int size) { int c; c = skipbl(); do { if( size > 1 ){ *s++ = c; --size; } c = inchar(); } while( c != ' ' && c != '\t' && c != '\n' ); termch = c; *s = 0; } static char line[256]; static char *lineptr; void flush_input() { lineptr = NULL; } int inchar() { if (lineptr == NULL || *lineptr == 0) { if (fgets(line, sizeof(line), stdin) == NULL) { lineptr = NULL; return EOF; } lineptr = line; } return *lineptr++; } void take_input(str) char *str; { lineptr = str; } /* Starting at codeaddr scan forward for a tbtable and fill in the given table. Return non-zero if successful at doing something. */ static int find_tb_table(unsigned long codeaddr, struct tbtable *tab) { unsigned long codeaddr_max; unsigned long tbtab_start; int nr; int instr; int num_parms; if (tab == NULL) return 0; memset(tab, 0, sizeof(tab)); /* Scan instructions starting at codeaddr for 128k max */ for (codeaddr_max = codeaddr + 128*1024*4; codeaddr < codeaddr_max; codeaddr += 4) { nr = mread(codeaddr, &instr, 4); if (nr != 4) return 0; /* Bad read. Give up promptly. */ if (instr == 0) { /* table should follow. */ int version; unsigned long flags; tbtab_start = codeaddr; /* save it to compute func start addr */ codeaddr += 4; nr = mread(codeaddr, &flags, 8); if (nr != 8) return 0; /* Bad read or no tb table. */ tab->flags = flags; version = (flags >> 56) & 0xff; if (version != 0) continue; /* No tb table here. */ /* Now, like the version, some of the flags are values that are more conveniently extracted... */ tab->fp_saved = (flags >> 24) & 0x3f; tab->gpr_saved = (flags >> 16) & 0x3f; tab->fixedparms = (flags >> 8) & 0xff; tab->floatparms = (flags >> 1) & 0x7f; codeaddr += 8; num_parms = tab->fixedparms + tab->floatparms; if (num_parms) { unsigned int parminfo; int parm; if (num_parms > 32) return 1; /* incomplete */ nr = mread(codeaddr, &parminfo, 4); if (nr != 4) return 1; /* incomplete */ /* decode parminfo...32 bits. A zero means fixed. A one means float and the following bit determines single (0) or double (1). */ for (parm = 0; parm < num_parms; parm++) { if (parminfo & 0x80000000) { parminfo <<= 1; if (parminfo & 0x80000000) tab->parminfo[parm] = TBTAB_PARMDFLOAT; else tab->parminfo[parm] = TBTAB_PARMSFLOAT; } else { tab->parminfo[parm] = TBTAB_PARMFIXED; } parminfo <<= 1; } codeaddr += 4; } if (flags & TBTAB_FLAGSHASTBOFF) { nr = mread(codeaddr, &tab->tb_offset, 4); if (nr != 4) return 1; /* incomplete */ if (tab->tb_offset > 0) { tab->funcstart = tbtab_start - tab->tb_offset; } codeaddr += 4; } /* hand_mask appears to be always be omitted. */ if (flags & TBTAB_FLAGSHASCTL) { /* Assume this will never happen for C or asm */ return 1; /* incomplete */ } if (flags & TBTAB_FLAGSNAMEPRESENT) { short namlen; nr = mread(codeaddr, &namlen, 2); if (nr != 2) return 1; /* incomplete */ if (namlen >= sizeof(tab->name)) namlen = sizeof(tab->name)-1; codeaddr += 2; nr = mread(codeaddr, tab->name, namlen); tab->name[namlen] = '\0'; codeaddr += namlen; } return 1; } } return 0; /* hit max...sorry. */ } void mem_translate() { int c; unsigned long ea, va, vsid, vpn, page, hpteg_slot_primary, hpteg_slot_secondary, primary_hash, i, *steg, esid, stabl; HPTE * hpte; struct mm_struct * mm; pte_t *ptep = NULL; void * pgdir; c = inchar(); if ((isxdigit(c) && c != 'f' && c != 'd') || c == '\n') termch = c; scanhex((void *)&ea); if ((ea >= KRANGE_START) && (ea <= (KRANGE_START + (1UL<<60)))) { ptep = 0; vsid = get_kernel_vsid(ea); va = ( vsid << 28 ) | ( ea & 0x0fffffff ); } else { // if in vmalloc range, use the vmalloc page directory if ( ( ea >= VMALLOC_START ) && ( ea <= VMALLOC_END ) ) { mm = &init_mm; vsid = get_kernel_vsid( ea ); } // if in ioremap range, use the ioremap page directory else if ( ( ea >= IMALLOC_START ) && ( ea <= IMALLOC_END ) ) { mm = &ioremap_mm; vsid = get_kernel_vsid( ea ); } // if in user range, use the current task's page directory else if ( ( ea >= USER_START ) && ( ea <= USER_END ) ) { mm = current->mm; vsid = get_vsid(mm->context, ea ); } pgdir = mm->pgd; va = ( vsid << 28 ) | ( ea & 0x0fffffff ); ptep = find_linux_pte( pgdir, ea ); } vpn = ((vsid << 28) | (((ea) & 0xFFFF000))) >> 12; page = vpn & 0xffff; esid = (ea >> 28) & 0xFFFFFFFFF; // Search the primary group for an available slot primary_hash = ( vsid & 0x7fffffffff ) ^ page; hpteg_slot_primary = ( primary_hash & htab_data.htab_hash_mask ) * HPTES_PER_GROUP; hpteg_slot_secondary = ( ~primary_hash & htab_data.htab_hash_mask ) * HPTES_PER_GROUP; printf("ea : %.16lx\n", ea); printf("esid : %.16lx\n", esid); printf("vsid : %.16lx\n", vsid); printf("\nSoftware Page Table\n-------------------\n"); printf("ptep : %.16lx\n", ((unsigned long *)ptep)); if(ptep) { printf("*ptep : %.16lx\n", *((unsigned long *)ptep)); } hpte = htab_data.htab + hpteg_slot_primary; printf("\nHardware Page Table\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("slot primary : %.16lx\n", hpteg_slot_primary); printf("slot secondary : %.16lx\n", hpteg_slot_secondary); printf("\nPrimary Group\n"); for (i=0; i<8; ++i) { if ( hpte->dw0.dw0.v != 0 ) { printf("%d: (hpte)%.16lx %.16lx\n", i, hpte->dw0.dword0, hpte->dw1.dword1); printf(" vsid: %.13lx api: %.2lx hash: %.1lx\n", (hpte->dw0.dw0.avpn)>>5, (hpte->dw0.dw0.avpn) & 0x1f, (hpte->dw0.dw0.h)); printf(" rpn: %.13lx \n", (hpte->dw1.dw1.rpn)); printf(" pp: %.1lx \n", ((hpte->dw1.dw1.pp0)<<2)|(hpte->dw1.dw1.pp)); printf(" wimgn: %.2lx reference: %.1lx change: %.1lx\n", ((hpte->dw1.dw1.w)<<4)| ((hpte->dw1.dw1.i)<<3)| ((hpte->dw1.dw1.m)<<2)| ((hpte->dw1.dw1.g)<<1)| ((hpte->dw1.dw1.n)<<0), hpte->dw1.dw1.r, hpte->dw1.dw1.c); } hpte++; } printf("\nSecondary Group\n"); // Search the secondary group hpte = htab_data.htab + hpteg_slot_secondary; for (i=0; i<8; ++i) { if(hpte->dw0.dw0.v) { printf("%d: (hpte)%.16lx %.16lx\n", i, hpte->dw0.dword0, hpte->dw1.dword1); printf(" vsid: %.13lx api: %.2lx hash: %.1lx\n", (hpte->dw0.dw0.avpn)>>5, (hpte->dw0.dw0.avpn) & 0x1f, (hpte->dw0.dw0.h)); printf(" rpn: %.13lx \n", (hpte->dw1.dw1.rpn)); printf(" pp: %.1lx \n", ((hpte->dw1.dw1.pp0)<<2)|(hpte->dw1.dw1.pp)); printf(" wimgn: %.2lx reference: %.1lx change: %.1lx\n", ((hpte->dw1.dw1.w)<<4)| ((hpte->dw1.dw1.i)<<3)| ((hpte->dw1.dw1.m)<<2)| ((hpte->dw1.dw1.g)<<1)| ((hpte->dw1.dw1.n)<<0), hpte->dw1.dw1.r, hpte->dw1.dw1.c); } hpte++; } printf("\nHardware Segment Table\n-----------------------\n"); stabl = (unsigned long)(KERNELBASE+(_ASR&0xFFFFFFFFFFFFFFFE)); steg = (unsigned long *)((stabl) | ((esid & 0x1f) << 7)); printf("stab base : %.16lx\n", stabl); printf("slot : %.16lx\n", steg); for (i=0; i<8; ++i) { printf("%d: (ste) %.16lx %.16lx\n", i, *((unsigned long *)(steg+i*2)),*((unsigned long *)(steg+i*2+1)) ); } } void mem_check() { unsigned long htab_size_bytes; unsigned long htab_end; unsigned long last_rpn; HPTE *hpte1, *hpte2; htab_size_bytes = htab_data.htab_num_ptegs * 128; // 128B / PTEG htab_end = (unsigned long)htab_data.htab + htab_size_bytes; // last_rpn = (naca->physicalMemorySize-1) >> PAGE_SHIFT; last_rpn = 0xfffff; printf("\nHardware Page Table Check\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("htab size : %.16lx\n", htab_size_bytes); for(hpte1 = htab_data.htab; hpte1 < (HPTE *)htab_end; hpte1++) { if ( hpte1->dw0.dw0.v != 0 ) { if ( hpte1->dw1.dw1.rpn <= last_rpn ) { for(hpte2 = hpte1+1; hpte2 < (HPTE *)htab_end; hpte2++) { if ( hpte2->dw0.dw0.v != 0 ) { if(hpte1->dw1.dw1.rpn == hpte2->dw1.dw1.rpn) { printf(" Duplicate rpn: %.13lx \n", (hpte1->dw1.dw1.rpn)); printf(" hpte1: %16.16lx *hpte1: %16.16lx %16.16lx\n", hpte1, hpte1->dw0.dword0, hpte1->dw1.dword1); printf(" hpte2: %16.16lx *hpte2: %16.16lx %16.16lx\n", hpte2, hpte2->dw0.dword0, hpte2->dw1.dword1); } } } } else { printf(" Bogus rpn: %.13lx \n", (hpte1->dw1.dw1.rpn)); printf(" hpte: %16.16lx *hpte: %16.16lx %16.16lx\n", hpte1, hpte1->dw0.dword0, hpte1->dw1.dword1); } } } printf("\nDone -------------------\n"); } void mem_find_real() { unsigned long htab_size_bytes; unsigned long htab_end; unsigned long last_rpn; HPTE *hpte1; unsigned long pa, rpn; int c; c = inchar(); if ((isxdigit(c) && c != 'f' && c != 'd') || c == '\n') termch = c; scanhex((void *)&pa); rpn = pa >> 12; htab_size_bytes = htab_data.htab_num_ptegs * 128; // 128B / PTEG htab_end = (unsigned long)htab_data.htab + htab_size_bytes; // last_rpn = (naca->physicalMemorySize-1) >> PAGE_SHIFT; last_rpn = 0xfffff; printf("\nMem Find RPN\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("htab size : %.16lx\n", htab_size_bytes); for(hpte1 = htab_data.htab; hpte1 < (HPTE *)htab_end; hpte1++) { if ( hpte1->dw0.dw0.v != 0 ) { if ( hpte1->dw1.dw1.rpn == rpn ) { printf(" Found rpn: %.13lx \n", (hpte1->dw1.dw1.rpn)); printf(" hpte: %16.16lx *hpte1: %16.16lx %16.16lx\n", hpte1, hpte1->dw0.dword0, hpte1->dw1.dword1); } } } printf("\nDone -------------------\n"); } void mem_find_vsid() { unsigned long htab_size_bytes; unsigned long htab_end; HPTE *hpte1; unsigned long vsid; int c; c = inchar(); if ((isxdigit(c) && c != 'f' && c != 'd') || c == '\n') termch = c; scanhex((void *)&vsid); htab_size_bytes = htab_data.htab_num_ptegs * 128; // 128B / PTEG htab_end = (unsigned long)htab_data.htab + htab_size_bytes; printf("\nMem Find VSID\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("htab size : %.16lx\n", htab_size_bytes); for(hpte1 = htab_data.htab; hpte1 < (HPTE *)htab_end; hpte1++) { if ( hpte1->dw0.dw0.v != 0 ) { if ( ((hpte1->dw0.dw0.avpn)>>5) == vsid ) { printf(" Found vsid: %.16lx \n", ((hpte1->dw0.dw0.avpn) >> 5)); printf(" hpte: %16.16lx *hpte1: %16.16lx %16.16lx\n", hpte1, hpte1->dw0.dword0, hpte1->dw1.dword1); } } } printf("\nDone -------------------\n"); } void mem_map_check_slab() { int i, slab_count; i = max_mapnr; slab_count = 0; while (i-- > 0) { if (PageSlab(mem_map+i)){ printf(" slab entry - mem_map entry =%p \n", mem_map+i); slab_count ++; } } printf(" count of pages for slab = %d \n", slab_count); } void mem_map_lock_pages() { int i, lock_count; i = max_mapnr; lock_count = 0; while (i-- > 0) { if (PageLocked(mem_map+i)){ printf(" locked entry - mem_map entry =%p \n", mem_map+i); lock_count ++; } } printf(" count of locked pages = %d \n", lock_count); } void mem_check_dup_rpn () { unsigned long htab_size_bytes; unsigned long htab_end; unsigned long last_rpn; HPTE *hpte1, *hpte2; int dup_count; struct task_struct *p; unsigned long kernel_vsid_c0,kernel_vsid_c1,kernel_vsid_c2,kernel_vsid_c3; unsigned long kernel_vsid_c4,kernel_vsid_c5,kernel_vsid_d,kernel_vsid_e; unsigned long kernel_vsid_f; unsigned long vsid0,vsid1,vsidB,vsid2; htab_size_bytes = htab_data.htab_num_ptegs * 128; // 128B / PTEG htab_end = (unsigned long)htab_data.htab + htab_size_bytes; // last_rpn = (naca->physicalMemorySize-1) >> PAGE_SHIFT; last_rpn = 0xfffff; printf("\nHardware Page Table Check\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("htab size : %.16lx\n", htab_size_bytes); for(hpte1 = htab_data.htab; hpte1 < (HPTE *)htab_end; hpte1++) { if ( hpte1->dw0.dw0.v != 0 ) { if ( hpte1->dw1.dw1.rpn <= last_rpn ) { dup_count = 0; for(hpte2 = hpte1+1; hpte2 < (HPTE *)htab_end; hpte2++) { if ( hpte2->dw0.dw0.v != 0 ) { if(hpte1->dw1.dw1.rpn == hpte2->dw1.dw1.rpn) { dup_count++; } } } if(dup_count > 5) { printf(" Duplicate rpn: %.13lx \n", (hpte1->dw1.dw1.rpn)); printf(" mem map array entry %p count = %d \n", (mem_map+(hpte1->dw1.dw1.rpn)), (mem_map+(hpte1->dw1.dw1.rpn))->count); for(hpte2 = hpte1+1; hpte2 < (HPTE *)htab_end; hpte2++) { if ( hpte2->dw0.dw0.v != 0 ) { if(hpte1->dw1.dw1.rpn == hpte2->dw1.dw1.rpn) { printf(" hpte2: %16.16lx *hpte2: %16.16lx %16.16lx\n", hpte2, hpte2->dw0.dword0, hpte2->dw1.dword1); } } } } } else { printf(" Bogus rpn: %.13lx \n", (hpte1->dw1.dw1.rpn)); printf(" hpte: %16.16lx *hpte: %16.16lx %16.16lx\n", hpte1, hpte1->dw0.dword0, hpte1->dw1.dword1); } } if (xmon_interrupted()) return; } // print the kernel vsids kernel_vsid_c0 = get_kernel_vsid(0xC000000000000000); kernel_vsid_c1 = get_kernel_vsid(0xC000000010000000); kernel_vsid_c2 = get_kernel_vsid(0xC000000020000000); kernel_vsid_c3 = get_kernel_vsid(0xC000000030000000); kernel_vsid_c4 = get_kernel_vsid(0xC000000040000000); kernel_vsid_c5 = get_kernel_vsid(0xC000000050000000); kernel_vsid_d = get_kernel_vsid(0xD000000000000000); kernel_vsid_e = get_kernel_vsid(0xE000000000000000); kernel_vsid_f = get_kernel_vsid(0xF000000000000000); printf(" kernel vsid - seg c0 = %lx\n", kernel_vsid_c0 ); printf(" kernel vsid - seg c1 = %lx\n", kernel_vsid_c1 ); printf(" kernel vsid - seg c2 = %lx\n", kernel_vsid_c2 ); printf(" kernel vsid - seg c3 = %lx\n", kernel_vsid_c3 ); printf(" kernel vsid - seg c4 = %lx\n", kernel_vsid_c4 ); printf(" kernel vsid - seg c5 = %lx\n", kernel_vsid_c5 ); printf(" kernel vsid - seg d = %lx\n", kernel_vsid_d ); printf(" kernel vsid - seg e = %lx\n", kernel_vsid_e ); printf(" kernel vsid - seg f = %lx\n", kernel_vsid_f ); // print a list of valid vsids for the tasks read_lock(&tasklist_lock); for_each_task(p) if(p->mm) { struct mm_struct *mm = p->mm; printf(" task = %p mm = %lx pgd %lx\n", p, mm, mm->pgd); vsid0 = get_vsid( mm->context, 0 ); vsid1 = get_vsid( mm->context, 0x10000000 ); vsid2 = get_vsid( mm->context, 0x20000000 ); vsidB = get_vsid( mm->context, 0xB0000000 ); printf(" context = %lx vsid seg 0 = %lx\n", mm->context, vsid0 ); printf(" vsid seg 1 = %lx\n", vsid1 ); printf(" vsid seg 2 = %lx\n", vsid2 ); printf(" vsid seg 2 = %lx\n", vsidB ); printf("\n"); }; read_unlock(&tasklist_lock); printf("\nDone -------------------\n"); } void mem_check_pagetable_vsids () { unsigned long htab_size_bytes; unsigned long htab_end; unsigned long last_rpn; struct task_struct *p; unsigned long valid_table_count,invalid_table_count,bogus_rpn_count; int found; unsigned long user_address_table_count,kernel_page_table_count; unsigned long pt_vsid; HPTE *hpte1; htab_size_bytes = htab_data.htab_num_ptegs * 128; // 128B / PTEG htab_end = (unsigned long)htab_data.htab + htab_size_bytes; // last_rpn = (naca->physicalMemorySize-1) >> PAGE_SHIFT; last_rpn = 0xfffff; printf("\nHardware Page Table Check\n-------------------\n"); printf("htab base : %.16lx\n", htab_data.htab); printf("htab size : %.16lx\n", htab_size_bytes); valid_table_count = 0; invalid_table_count = 0; bogus_rpn_count = 0; user_address_table_count = 0; kernel_page_table_count = 0; for(hpte1 = htab_data.htab; hpte1 < (HPTE *)htab_end; hpte1++) { if ( hpte1->dw0.dw0.v != 0 ) { valid_table_count++; if ( hpte1->dw1.dw1.rpn <= last_rpn ) { pt_vsid = (hpte1->dw0.dw0.avpn) >> 5; if ((pt_vsid == get_kernel_vsid(0xC000000000000000)) | (pt_vsid == get_kernel_vsid(0xC000000010000000)) | (pt_vsid == get_kernel_vsid(0xC000000020000000)) | (pt_vsid == get_kernel_vsid(0xC000000030000000)) | (pt_vsid == get_kernel_vsid(0xC000000040000000)) | (pt_vsid == get_kernel_vsid(0xC000000050000000)) | (pt_vsid == get_kernel_vsid(0xD000000000000000)) | (pt_vsid == get_kernel_vsid(0xE000000000000000)) | (pt_vsid == get_kernel_vsid(0xF000000000000000)) ) { kernel_page_table_count ++; } else { read_lock(&tasklist_lock); found = 0; for_each_task(p) { if(p->mm && (found == 0)) { struct mm_struct *mm = p->mm; if ((pt_vsid == get_vsid( mm->context, 0 )) | (pt_vsid == get_vsid( mm->context, 0x10000000 )) | (pt_vsid == get_vsid( mm->context, 0x20000000 )) | (pt_vsid == get_vsid( mm->context, 0x30000000 )) | (pt_vsid == get_vsid( mm->context, 0x40000000 )) | (pt_vsid == get_vsid( mm->context, 0x50000000 )) | (pt_vsid == get_vsid( mm->context, 0x60000000 )) | (pt_vsid == get_vsid( mm->context, 0x70000000 )) | (pt_vsid == get_vsid( mm->context, 0x80000000 )) | (pt_vsid == get_vsid( mm->context, 0x90000000 )) | (pt_vsid == get_vsid( mm->context, 0xA0000000 )) | (pt_vsid == get_vsid( mm->context, 0xB0000000 ))) { user_address_table_count ++; found = 1; } } } read_unlock(&tasklist_lock); if (found == 0) { printf(" vsid not found vsid = %lx, hpte = %p \n", pt_vsid,hpte1); printf(" rpn in entry = %lx \n", hpte1->dw1.dw1.rpn); printf(" mem map address = %lx \n", mem_map + (hpte1->dw1.dw1.rpn)); } else // found { } } // good rpn } else { bogus_rpn_count ++; } } else { invalid_table_count++; } } printf(" page table valid counts - valid entries = %lx invalid entries = %lx \n", valid_table_count, invalid_table_count); printf(" bogus rpn entries ( probably io) = %lx \n", bogus_rpn_count); printf(" page table counts - kernel entries = %lx user entries = %lx \n", kernel_page_table_count, user_address_table_count); printf("\nDone -------------------\n"); } static void debug_trace(void) { unsigned long val, cmd, on; cmd = skipbl(); if (cmd == '\n') { /* show current state */ unsigned long i; printf("naca->debug_switch = 0x%lx\n", naca->debug_switch); for (i = 0; i < PPCDBG_NUM_FLAGS ;i++) { on = PPCDBG_BITVAL(i) & naca->debug_switch; printf("%02x %s %12s ", i, on ? "on " : "off", trace_names[i] ? trace_names[i] : ""); if (((i+1) % 3) == 0) printf("\n"); } printf("\n"); return; } while (cmd != '\n') { on = 1; /* default if no sign given */ while (cmd == '+' || cmd == '-') { on = (cmd == '+'); cmd = inchar(); if (cmd == ' ' || cmd == '\n') { /* Turn on or off based on + or - */ naca->debug_switch = on ? PPCDBG_ALL:PPCDBG_NONE; printf("Setting all values to %s...\n", on ? "on" : "off"); if (cmd == '\n') return; else cmd = skipbl(); } else termch = cmd; } termch = cmd; /* not +/- ... let scanhex see it */ scanhex((void *)&val); if (val >= 64) { printf("Value %x out of range:\n", val); return; } if (on) { naca->debug_switch |= PPCDBG_BITVAL(val); printf("enable debug %x %s\n", val, trace_names[val] ? trace_names[val] : ""); } else { naca->debug_switch &= ~PPCDBG_BITVAL(val); printf("disable debug %x %s\n", val, trace_names[val] ? trace_names[val] : ""); } cmd = skipbl(); } }