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zephyr/arch/arm/core/gdbstub.c
Marek Vedral 93a4287115 arm: debug: Add GDB stub for aarch32 
This commit adds implementation of GDB stub for 32-bit ARM. It has been
tested only on the Zynq-7000 SoC and I would like to get any feedback
from others.

The stub still has these issues:

- To implement single stepping, it uses instruction address mismatch
  breakpoint, as recommended in ARMv7 reference. The breakpoint control
  register is configured (the state control fields) for the "PL0,
  Supervisor and System modes only" option. Otherwise the breakpoint
  would also halt the processor in abort mode, in which the stub loop
  runs. Zephyr kernel runs in the system mode. This works well until the
  kernel enables interrupts, as interrupt handlers typically run in
  Supervisor mode. Single stepping therefore sometimes "catches" a
  handler instead of the next application instruction. I have not tried
  User mode, because Cortex-A SoCs do not appear to have the
  ARCH_HAS_USERSPACE flag.

Cc: Michal Sojka <michal.sojka@cvut.cz>
Signed-off-by: Marek Vedral <marek.vedral@gmail.com>
2023-12-18 09:31:42 +01:00

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/*
* Copyright (c) 2023 Marek Vedral <vedrama5@fel.cvut.cz>
*
* SPDX-License-Identifier: Apache-2.0
*/
#include <zephyr/kernel.h>
#include <kernel_internal.h>
#include <zephyr/arch/arm/gdbstub.h>
#include <zephyr/debug/gdbstub.h>
/* Position of each register in the packet - n-th register in the ctx.registers array needs to be
* the packet_pos[n]-th byte of the g (read all registers) packet. See struct arm_register_names in
* GDB file gdb/arm-tdep.c, which defines these positions.
*/
static const int packet_pos[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 41};
/* Required struct */
static struct gdb_ctx ctx;
/* Return true if BKPT instruction caused the current entry */
static int is_bkpt(unsigned int exc_cause)
{
int ret = 0;
if (exc_cause == GDB_EXCEPTION_BREAKPOINT) {
/* Get the instruction */
unsigned int instr = sys_read32(ctx.registers[PC]);
/* Try to check the instruction encoding */
int ist = ((ctx.registers[SPSR] & BIT(SPSR_J)) >> (SPSR_J - 1)) |
((ctx.registers[SPSR] & BIT(SPSR_T)) >> SPSR_T);
if (ist == SPSR_ISETSTATE_ARM) {
/* ARM instruction set state */
ret = ((instr & 0xFF00000) == 0x1200000) && ((instr & 0xF0) == 0x70);
} else if (ist != SPSR_ISETSTATE_JAZELLE) {
/* Thumb or ThumbEE encoding */
ret = ((instr & 0xFF00) == 0xBE00);
}
}
return ret;
}
/* Wrapper function to save and restore execution c */
void z_gdb_entry(z_arch_esf_t *esf, unsigned int exc_cause)
{
/* Disable the hardware breakpoint in case it was set */
__asm__ volatile("mcr p14, 0, %0, c0, c0, 5" ::"r"(0x0) :);
ctx.exception = exc_cause;
/* save the registers */
ctx.registers[R0] = esf->basic.r0;
ctx.registers[R1] = esf->basic.r1;
ctx.registers[R2] = esf->basic.r2;
ctx.registers[R3] = esf->basic.r3;
/* The EXTRA_EXCEPTION_INFO kernel option ensures these regs are set */
ctx.registers[R4] = esf->extra_info.callee->v1;
ctx.registers[R5] = esf->extra_info.callee->v2;
ctx.registers[R6] = esf->extra_info.callee->v3;
ctx.registers[R7] = esf->extra_info.callee->v4;
ctx.registers[R8] = esf->extra_info.callee->v5;
ctx.registers[R9] = esf->extra_info.callee->v6;
ctx.registers[R10] = esf->extra_info.callee->v7;
ctx.registers[R11] = esf->extra_info.callee->v8;
ctx.registers[R13] = esf->extra_info.callee->psp;
ctx.registers[R12] = esf->basic.r12;
ctx.registers[LR] = esf->basic.lr;
ctx.registers[PC] = esf->basic.pc;
ctx.registers[SPSR] = esf->basic.xpsr;
/* True if entering after a BKPT instruction */
const int bkpt_entry = is_bkpt(exc_cause);
z_gdb_main_loop(&ctx);
/* The registers part of EXTRA_EXCEPTION_INFO are read-only - the excpetion return code
* does not restore them, thus we don't need to do so here
*/
esf->basic.r0 = ctx.registers[R0];
esf->basic.r1 = ctx.registers[R1];
esf->basic.r2 = ctx.registers[R2];
esf->basic.r3 = ctx.registers[R3];
esf->basic.r12 = ctx.registers[R12];
esf->basic.lr = ctx.registers[LR];
esf->basic.pc = ctx.registers[PC];
esf->basic.xpsr = ctx.registers[SPSR];
/* TODO: restore regs from extra exc. info */
if (bkpt_entry) {
/* Apply this offset, so that the process won't be affected by the
* BKPT instruction
*/
esf->basic.pc += 0x4;
}
esf->basic.xpsr = ctx.registers[SPSR];
}
void arch_gdb_init(void)
{
uint32_t reg_val;
/* Enable the monitor debug mode */
__asm__ volatile("mrc p14, 0, %0, c0, c2, 2" : "=r"(reg_val)::);
reg_val |= DBGDSCR_MONITOR_MODE_EN;
__asm__ volatile("mcr p14, 0, %0, c0, c2, 2" ::"r"(reg_val) :);
/* Generate the Prefetch abort exception */
__asm__ volatile("BKPT");
}
void arch_gdb_continue(void)
{
/* No need to do anything, return to the code. */
}
void arch_gdb_step(void)
{
/* Set the hardware breakpoint */
uint32_t reg_val = ctx.registers[PC];
/* set BVR (Breakpoint value register) to PC, make sure it is word aligned */
reg_val &= ~(0x3);
__asm__ volatile("mcr p14, 0, %0, c0, c0, 4" ::"r"(reg_val) :);
reg_val = 0;
/* Address mismatch */
reg_val |= (DBGDBCR_MEANING_ADDR_MISMATCH & DBGDBCR_MEANING_MASK) << DBGDBCR_MEANING_SHIFT;
/* Match any other instruction */
reg_val |= (0xF & DBGDBCR_BYTE_ADDR_MASK) << DBGDBCR_BYTE_ADDR_SHIFT;
/* Breakpoint enable */
reg_val |= DBGDBCR_BRK_EN_MASK;
__asm__ volatile("mcr p14, 0, %0, c0, c0, 5" ::"r"(reg_val) :);
}
size_t arch_gdb_reg_readall(struct gdb_ctx *c, uint8_t *buf, size_t buflen)
{
int ret = 0;
/* All other registers are not supported */
memset(buf, 'x', buflen);
for (int i = 0; i < GDB_NUM_REGS; i++) {
/* offset inside the packet */
int pos = packet_pos[i] * 8;
int r = bin2hex((const uint8_t *)(c->registers + i), 4, buf + pos, buflen - pos);
/* remove the newline character placed by the bin2hex function */
buf[pos + 8] = 'x';
if (r == 0) {
ret = 0;
break;
}
ret += r;
}
if (ret) {
/* Since we don't support some floating point registers, set the packet size
* manually
*/
ret = GDB_READALL_PACKET_SIZE;
}
return ret;
}
size_t arch_gdb_reg_writeall(struct gdb_ctx *c, uint8_t *hex, size_t hexlen)
{
int ret = 0;
for (unsigned int i = 0; i < hexlen; i += 8) {
if (hex[i] != 'x') {
/* check if the stub supports this register */
for (unsigned int j = 0; j < GDB_NUM_REGS; j++) {
if (packet_pos[j] != i) {
continue;
}
int r = hex2bin(hex + i * 8, 8, (uint8_t *)(c->registers + j), 4);
if (r == 0) {
return 0;
}
ret += r;
}
}
}
return ret;
}
size_t arch_gdb_reg_readone(struct gdb_ctx *c, uint8_t *buf, size_t buflen, uint32_t regno)
{
/* Reading four bytes (could be any return value except 0, which would indicate an error) */
int ret = 4;
/* Fill the buffer with 'x' in case the stub does not support the required register */
memset(buf, 'x', 8);
if (regno == SPSR_REG_IDX) {
/* The SPSR register is at the end, we have to check separately */
ret = bin2hex((uint8_t *)(c->registers + GDB_NUM_REGS - 1), 4, buf, buflen);
} else {
/* Check which of our registers corresponds to regnum */
for (int i = 0; i < GDB_NUM_REGS; i++) {
if (packet_pos[i] == regno) {
ret = bin2hex((uint8_t *)(c->registers + i), 4, buf, buflen);
break;
}
}
}
return ret;
}
size_t arch_gdb_reg_writeone(struct gdb_ctx *c, uint8_t *hex, size_t hexlen, uint32_t regno)
{
int ret = 0;
/* Set the value of a register */
if (hexlen != 8) {
return ret;
}
if (regno < (GDB_NUM_REGS - 1)) {
/* Again, check the corresponding register index */
for (int i = 0; i < GDB_NUM_REGS; i++) {
if (packet_pos[i] == regno) {
ret = hex2bin(hex, hexlen, (uint8_t *)(c->registers + i), 4);
break;
}
}
} else if (regno == SPSR_REG_IDX) {
ret = hex2bin(hex, hexlen, (uint8_t *)(c->registers + GDB_NUM_REGS - 1), 4);
}
return ret;
}
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