arm/arm32/db_interface.c

1.63     skrll /*	$NetBSD: db_interface.c,v 1.63 2020/12/03 07:45:52 skrll Exp $	*/
 1.1      matt
1.50     skrll /*
 1.1      matt  * Copyright (c) 1996 Scott K. Stevens
 1.1      matt  *
 1.1      matt  * Mach Operating System
 1.1      matt  * Copyright (c) 1991,1990 Carnegie Mellon University
 1.1      matt  * All Rights Reserved.
1.50     skrll  *
 1.1      matt  * Permission to use, copy, modify and distribute this software and its
 1.1      matt  * documentation is hereby granted, provided that both the copyright
 1.1      matt  * notice and this permission notice appear in all copies of the
 1.1      matt  * software, derivative works or modified versions, and any portions
 1.1      matt  * thereof, and that both notices appear in supporting documentation.
1.50     skrll  *
 1.1      matt  * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
 1.1      matt  * CONDITION.  CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
 1.1      matt  * ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
1.50     skrll  *
 1.1      matt  * Carnegie Mellon requests users of this software to return to
1.50     skrll  *
 1.1      matt  *  Software Distribution Coordinator  or  Software.Distribution (at) CS.CMU.EDU
 1.1      matt  *  School of Computer Science
 1.1      matt  *  Carnegie Mellon University
 1.1      matt  *  Pittsburgh PA 15213-3890
1.50     skrll  *
 1.1      matt  * any improvements or extensions that they make and grant Carnegie the
 1.1      matt  * rights to redistribute these changes.
 1.1      matt  *
 1.1      matt  *	From: db_interface.c,v 2.4 1991/02/05 17:11:13 mrt (CMU)
 1.1      matt  */
 1.1      matt
 1.1      matt /*
 1.1      matt  * Interface to new debugger.
 1.1      matt  */
1.32     lukem
1.32     lukem #include <sys/cdefs.h>
1.63     skrll __KERNEL_RCSID(0, "$NetBSD: db_interface.c,v 1.63 2020/12/03 07:45:52 skrll Exp $");
1.32     lukem
 1.1      matt #include "opt_ddb.h"
1.24    briggs #include "opt_kgdb.h"
1.54     skrll #include "opt_multiprocessor.h"
 1.1      matt
 1.1      matt #include <sys/param.h>
1.60     skrll
1.60     skrll #include <sys/atomic.h>
1.60     skrll #include <sys/exec.h>
1.60     skrll #include <sys/intr.h>
 1.1      matt #include <sys/proc.h>
 1.1      matt #include <sys/reboot.h>
 1.1      matt #include <sys/systm.h>	/* just for boothowto */
 1.1      matt
 1.1      matt #include <uvm/uvm_extern.h>
 1.1      matt
1.13     chris #include <arm/arm32/db_machdep.h>
1.11   thorpej #include <arm/undefined.h>
1.13     chris #include <ddb/db_access.h>
 1.1      matt #include <ddb/db_command.h>
 1.1      matt #include <ddb/db_output.h>
 1.1      matt #include <ddb/db_variables.h>
 1.1      matt #include <ddb/db_sym.h>
 1.1      matt #include <ddb/db_extern.h>
 1.1      matt #include <ddb/db_interface.h>
 1.1      matt #include <dev/cons.h>
 1.1      matt
1.24    briggs #if defined(KGDB) || !defined(DDB)
1.24    briggs #define db_printf	printf
1.24    briggs #endif
1.24    briggs
1.46       dsl u_int db_fetch_reg(int, db_regs_t *);
 1.1      matt
1.46       dsl int db_trapper(u_int, u_int, trapframe_t *, int);
1.13     chris
 1.1      matt int	db_active = 0;
1.52     skrll db_regs_t ddb_regs;	/* register state */
1.52     skrll db_regs_t *ddb_regp;
1.52     skrll
1.51      matt #ifdef MULTIPROCESSOR
1.51      matt volatile struct cpu_info *db_onproc;
1.51      matt volatile struct cpu_info *db_newcpu;
1.51      matt #endif
1.51      matt
1.51      matt
 1.1      matt
 1.1      matt
1.24    briggs #ifdef DDB
 1.1      matt /*
 1.1      matt  *  kdb_trap - field a TRACE or BPT trap
 1.1      matt  */
 1.1      matt int
1.15   thorpej kdb_trap(int type, db_regs_t *regs)
 1.1      matt {
1.51      matt 	struct cpu_info * const ci = curcpu();
1.52     skrll 	db_regs_t dbreg;
 1.1      matt 	int s;
 1.1      matt
 1.1      matt 	switch (type) {
 1.1      matt 	case T_BREAKPOINT:	/* breakpoint */
 1.1      matt 	case -1:		/* keyboard interrupt */
 1.1      matt 		break;
1.51      matt #ifdef MULTIPROCESSOR
1.51      matt 	case -2:
1.51      matt 		/*
1.51      matt 		 * We called to enter ddb from another process but by the time
1.51      matt 		 * we got here, no one was in ddb.  So ignore the request.
1.51      matt 		 */
1.51      matt 		if (db_onproc == NULL)
1.51      matt 			return 1;
1.51      matt 		break;
1.51      matt #endif
 1.1      matt 	default:
 1.1      matt 		if (db_recover != 0) {
1.31   thorpej 			/* This will longjmp back into db_command_loop() */
 1.1      matt 			db_error("Faulted in DDB; continuing...\n");
 1.1      matt 			/*NOTREACHED*/
 1.1      matt 		}
 1.1      matt 	}
 1.1      matt
 1.1      matt 	/* Should switch to kdb`s own stack here. */
 1.1      matt
1.51      matt #ifdef MULTIPROCESSOR
1.51      matt 	const bool is_mp_p = ncpu > 1;
1.51      matt 	if (is_mp_p) {
1.51      matt 		/*
1.51      matt 		 * Try to take ownership of DDB.  If we do, tell all other
1.51      matt 		 * CPUs to enter DDB too.
1.51      matt 		 */
1.51      matt 		if (atomic_cas_ptr(&db_onproc, NULL, ci) == NULL) {
1.51      matt 			intr_ipi_send(NULL, IPI_DDB);
1.51      matt 		}
1.51      matt 	}
1.51      matt 	for (;;) {
1.51      matt 		if (is_mp_p) {
1.51      matt 			/*
1.51      matt 			 * While we aren't the master, wait until the master
1.51      matt 			 * gives control to us or exits.  If it exited, we
1.55     skrll 			 * just exit too.  Otherwise this cpu will enter DDB.
1.51      matt 			 */
1.51      matt 			membar_consumer();
1.51      matt 			while (db_onproc != ci) {
1.51      matt 				if (db_onproc == NULL)
1.51      matt 					return 1;
1.51      matt #ifdef _ARM_ARCH_6
1.51      matt 				__asm __volatile("wfe");
1.51      matt 				membar_consumer();
1.51      matt #endif
1.51      matt 				if (db_onproc == ci) {
1.51      matt 					printf("%s: switching to %s\n",
1.51      matt 					    __func__, ci->ci_cpuname);
1.51      matt 				}
1.51      matt 			}
1.51      matt 		}
1.51      matt #endif
 1.1      matt
1.51      matt 		s = splhigh();
1.52     skrll 		ci->ci_ddb_regs = &dbreg;
1.52     skrll 		ddb_regp = &dbreg;
1.52     skrll 		ddb_regs = *regs;
1.52     skrll
1.51      matt 		atomic_inc_32(&db_active);
1.51      matt 		cnpollc(true);
1.51      matt 		db_trap(type, 0/*code*/);
1.51      matt 		cnpollc(false);
1.51      matt 		atomic_dec_32(&db_active);
1.52     skrll
1.51      matt 		ci->ci_ddb_regs = NULL;
1.52     skrll 		ddb_regp = &dbreg;
1.52     skrll 		*regs = ddb_regs;
1.51      matt 		splx(s);
1.51      matt
1.51      matt #ifdef MULTIPROCESSOR
1.51      matt 		if (is_mp_p && db_newcpu != NULL) {
1.51      matt 			db_onproc = db_newcpu;
1.51      matt 			db_newcpu = NULL;
1.63     skrll 			dsb(ishst);
1.63     skrll 			sev();
1.51      matt 			continue;
1.51      matt 		}
1.51      matt 		break;
1.51      matt 	}
 1.1      matt
1.51      matt 	if (is_mp_p) {
1.51      matt 		/*
1.51      matt 		 * We are exiting DDB so there is noone onproc.  Tell
1.51      matt 		 * the other CPUs to exit.
1.51      matt 		 */
1.51      matt 		db_onproc = NULL;
1.63     skrll 		dsb(ishst);
1.63     skrll 		sev();
1.51      matt 	}
1.51      matt #endif
 1.1      matt
1.56     skrll 	return 1;
 1.1      matt }
1.24    briggs #endif
 1.1      matt
1.24    briggs int
1.15   thorpej db_validate_address(vaddr_t addr)
 1.1      matt {
 1.1      matt 	struct proc *p = curproc;
1.14   thorpej 	struct pmap *pmap;
 1.1      matt
1.23       scw 	if (!p || !p->p_vmspace || !p->p_vmspace->vm_map.pmap ||
1.29   thorpej 	    addr >= VM_MIN_KERNEL_ADDRESS
1.29   thorpej 	   )
1.14   thorpej 		pmap = pmap_kernel();
 1.1      matt 	else
1.14   thorpej 		pmap = p->p_vmspace->vm_map.pmap;
 1.1      matt
1.61     skrll 	return pmap_extract(pmap, addr, NULL) == false;
 1.1      matt }
 1.1      matt
 1.1      matt /*
 1.1      matt  * Read bytes from kernel address space for debugger.
 1.1      matt  */
 1.1      matt void
1.47       dsl db_read_bytes(vaddr_t addr, size_t size, char *data)
 1.1      matt {
1.30       scw 	char	*src = (char *)addr;
 1.1      matt
1.30       scw 	if (db_validate_address((u_int)src)) {
1.30       scw 		db_printf("address %p is invalid\n", src);
1.30       scw 		return;
1.30       scw 	}
1.30       scw
1.30       scw 	if (size == 4 && (addr & 3) == 0 && ((uintptr_t)data & 3) == 0) {
1.30       scw 		*((int*)data) = *((int*)src);
1.30       scw 		return;
1.30       scw 	}
1.30       scw
1.30       scw 	if (size == 2 && (addr & 1) == 0 && ((uintptr_t)data & 1) == 0) {
1.30       scw 		*((short*)data) = *((short*)src);
1.30       scw 		return;
1.30       scw 	}
1.14   thorpej
1.14   thorpej 	while (size-- > 0) {
 1.1      matt 		if (db_validate_address((u_int)src)) {
 1.1      matt 			db_printf("address %p is invalid\n", src);
 1.1      matt 			return;
 1.1      matt 		}
 1.1      matt 		*data++ = *src++;
 1.1      matt 	}
 1.1      matt }
 1.1      matt
 1.1      matt static void
1.37       uwe db_write_text(vaddr_t addr, size_t size, const char *data)
1.50     skrll {
 1.1      matt
1.58       chs 	ktext_write((void *)addr, data, size);
 1.1      matt }
 1.1      matt
 1.1      matt /*
 1.1      matt  * Write bytes to kernel address space for debugger.
 1.1      matt  */
 1.1      matt void
1.37       uwe db_write_bytes(vaddr_t addr, size_t size, const char *data)
 1.1      matt {
1.27   thorpej 	extern char kernel_text[];
1.15   thorpej 	extern char etext[];
1.15   thorpej 	char *dst;
1.15   thorpej 	size_t loop;
1.15   thorpej
1.15   thorpej 	/* If any part is in kernel text, use db_write_text() */
1.27   thorpej 	if (addr >= (vaddr_t) kernel_text && addr < (vaddr_t) etext) {
1.15   thorpej 		db_write_text(addr, size, data);
1.15   thorpej 		return;
1.15   thorpej 	}
 1.1      matt
 1.1      matt 	dst = (char *)addr;
1.30       scw 	if (db_validate_address((u_int)dst)) {
1.30       scw 		db_printf("address %p is invalid\n", dst);
1.30       scw 		return;
1.30       scw 	}
1.30       scw
1.30       scw 	if (size == 4 && (addr & 3) == 0 && ((uintptr_t)data & 3) == 0)
1.37       uwe 		*((int*)dst) = *((const int *)data);
1.30       scw 	else
1.30       scw 	if (size == 2 && (addr & 1) == 0 && ((uintptr_t)data & 1) == 0)
1.37       uwe 		*((short*)dst) = *((const short *)data);
1.30       scw 	else {
1.30       scw 		loop = size;
1.30       scw 		while (loop-- > 0) {
1.30       scw 			if (db_validate_address((u_int)dst)) {
1.30       scw 				db_printf("address %p is invalid\n", dst);
1.30       scw 				return;
1.30       scw 			}
1.30       scw 			*dst++ = *data++;
 1.1      matt 		}
 1.1      matt 	}
1.30       scw
 1.1      matt 	/* make sure the caches and memory are in sync */
1.17   thorpej 	cpu_icache_sync_range(addr, size);
 1.1      matt
 1.1      matt 	/* In case the current page tables have been modified ... */
 1.1      matt 	cpu_tlb_flushID();
1.16   thorpej 	cpu_cpwait();
 1.1      matt }
 1.1      matt
1.28       bsh #ifdef DDB
 1.1      matt void
1.15   thorpej cpu_Debugger(void)
 1.1      matt {
1.62       rin #ifdef _ARM_ARCH_BE8
1.62       rin 	__asm(".word	0xffffffe7");
1.62       rin #else
1.39     perry 	__asm(".word	0xe7ffffff");
1.59       rin #endif
 1.1      matt }
 1.1      matt
 1.1      matt int
1.15   thorpej db_trapper(u_int addr, u_int inst, trapframe_t *frame, int fault_code)
 1.1      matt {
1.15   thorpej
 1.1      matt 	if (fault_code == 0) {
 1.1      matt 		if ((inst & ~INSN_COND_MASK) == (BKPT_INST & ~INSN_COND_MASK))
 1.1      matt 			kdb_trap(T_BREAKPOINT, frame);
 1.1      matt 		else
 1.1      matt 			kdb_trap(-1, frame);
 1.1      matt 	} else
1.56     skrll 		return 1;
1.56     skrll 	return 0;
 1.1      matt }
 1.1      matt
 1.1      matt extern u_int esym;
 1.1      matt extern u_int end;
 1.1      matt
 1.3     bjh21 static struct undefined_handler db_uh;
 1.3     bjh21
 1.1      matt void
1.15   thorpej db_machine_init(void)
 1.1      matt {
 1.1      matt
 1.3     bjh21 	/*
 1.3     bjh21 	 * We get called before malloc() is available, so supply a static
 1.3     bjh21 	 * struct undefined_handler.
 1.3     bjh21 	 */
 1.3     bjh21 	db_uh.uh_handler = db_trapper;
1.35  rearnsha 	install_coproc_handler_static(CORE_UNKNOWN_HANDLER, &db_uh);
 1.1      matt }
1.24    briggs #endif
 1.1      matt
 1.1      matt u_int
1.36        he db_fetch_reg(int reg, db_regs_t *regs)
 1.1      matt {
 1.1      matt
 1.1      matt 	switch (reg) {
 1.1      matt 	case 0:
1.56     skrll 		return regs->tf_r0;
 1.1      matt 	case 1:
1.56     skrll 		return regs->tf_r1;
 1.1      matt 	case 2:
1.56     skrll 		return regs->tf_r2;
 1.1      matt 	case 3:
1.56     skrll 		return regs->tf_r3;
 1.1      matt 	case 4:
1.56     skrll 		return regs->tf_r4;
 1.1      matt 	case 5:
1.56     skrll 		return regs->tf_r5;
 1.1      matt 	case 6:
1.56     skrll 		return regs->tf_r6;
 1.1      matt 	case 7:
1.56     skrll 		return regs->tf_r7;
 1.1      matt 	case 8:
1.56     skrll 		return regs->tf_r8;
 1.1      matt 	case 9:
1.56     skrll 		return regs->tf_r9;
 1.1      matt 	case 10:
1.56     skrll 		return regs->tf_r10;
 1.1      matt 	case 11:
1.56     skrll 		return regs->tf_r11;
 1.1      matt 	case 12:
1.56     skrll 		return regs->tf_r12;
 1.1      matt 	case 13:
1.56     skrll 		return regs->tf_svc_sp;
 1.1      matt 	case 14:
1.56     skrll 		return regs->tf_svc_lr;
 1.1      matt 	case 15:
1.56     skrll 		return regs->tf_pc;
 1.1      matt 	default:
 1.1      matt 		panic("db_fetch_reg: botch");
 1.1      matt 	}
 1.1      matt }
 1.1      matt
 1.1      matt u_int
1.36        he branch_taken(u_int insn, u_int pc, db_regs_t *regs)
 1.1      matt {
 1.1      matt 	u_int addr, nregs;
 1.1      matt
 1.1      matt 	switch ((insn >> 24) & 0xf) {
 1.1      matt 	case 0xa:	/* b ... */
 1.1      matt 	case 0xb:	/* bl ... */
 1.1      matt 		addr = ((insn << 2) & 0x03ffffff);
 1.1      matt 		if (addr & 0x02000000)
 1.1      matt 			addr |= 0xfc000000;
1.56     skrll 		return pc + 8 + addr;
 1.1      matt 	case 0x7:	/* ldr pc, [pc, reg, lsl #2] */
1.36        he 		addr = db_fetch_reg(insn & 0xf, regs);
 1.1      matt 		addr = pc + 8 + (addr << 2);
 1.1      matt 		db_read_bytes(addr, 4, (char *)&addr);
1.56     skrll 		return addr;
1.41  christos 	case 0x5:	/* ldr pc, [reg] */
1.41  christos 		addr = db_fetch_reg((insn >> 16) & 0xf, regs);
1.41  christos 		db_read_bytes(addr, 4, (char *)&addr);
1.56     skrll 		return addr;
 1.1      matt 	case 0x1:	/* mov pc, reg */
1.36        he 		addr = db_fetch_reg(insn & 0xf, regs);
1.56     skrll 		return addr;
 1.1      matt 	case 0x8:	/* ldmxx reg, {..., pc} */
 1.1      matt 	case 0x9:
1.36        he 		addr = db_fetch_reg((insn >> 16) & 0xf, regs);
 1.1      matt 		nregs = (insn  & 0x5555) + ((insn  >> 1) & 0x5555);
 1.1      matt 		nregs = (nregs & 0x3333) + ((nregs >> 2) & 0x3333);
 1.1      matt 		nregs = (nregs + (nregs >> 4)) & 0x0f0f;
 1.1      matt 		nregs = (nregs + (nregs >> 8)) & 0x001f;
 1.1      matt 		switch ((insn >> 23) & 0x3) {
 1.1      matt 		case 0x0:	/* ldmda */
 1.1      matt 			addr = addr - 0;
 1.1      matt 			break;
 1.1      matt 		case 0x1:	/* ldmia */
 1.1      matt 			addr = addr + 0 + ((nregs - 1) << 2);
 1.1      matt 			break;
 1.1      matt 		case 0x2:	/* ldmdb */
 1.1      matt 			addr = addr - 4;
 1.1      matt 			break;
 1.1      matt 		case 0x3:	/* ldmib */
 1.1      matt 			addr = addr + 4 + ((nregs - 1) << 2);
 1.1      matt 			break;
 1.1      matt 		}
 1.1      matt 		db_read_bytes(addr, 4, (char *)&addr);
1.56     skrll 		return addr;
 1.1      matt 	default:
 1.1      matt 		panic("branch_taken: botch");
 1.1      matt 	}
 1.1      matt }