NetBSD/gnu/dist/gdb/sh-tdep.c

869 lines
26 KiB
C

/* Target-dependent code for Hitachi Super-H, for GDB.
Copyright (C) 1993, 1994, 1995, 1996 Free Software Foundation, Inc.
This file is part of GDB.
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.
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, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
/*
Contributed by Steve Chamberlain
sac@cygnus.com
*/
#include "defs.h"
#include "frame.h"
#include "obstack.h"
#include "symtab.h"
#include "symfile.h"
#include "gdbtypes.h"
#include "gdbcmd.h"
#include "gdbcore.h"
#include "value.h"
#include "dis-asm.h"
#include "inferior.h" /* for BEFORE_TEXT_END etc. */
#include "gdb_string.h"
extern int remote_write_size; /* in remote.c */
/* A set of original names, to be used when restoring back to generic
registers from a specific set. */
char *sh_generic_reg_names[] = REGISTER_NAMES;
char *sh_reg_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
char *sh3_reg_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"ssr", "spc",
"r0b0", "r1b0", "r2b0", "r3b0", "r4b0", "r5b0", "r6b0", "r7b0",
"r0b1", "r1b1", "r2b1", "r3b1", "r4b1", "r5b1", "r6b1", "r7b1"
};
char *sh3e_reg_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"fpul", "fpscr",
"fr0", "fr1", "fr2", "fr3", "fr4", "fr5", "fr6", "fr7",
"fr8", "fr9", "fr10", "fr11", "fr12", "fr13", "fr14", "fr15",
"ssr", "spc",
"r0b0", "r1b0", "r2b0", "r3b0", "r4b0", "r5b0", "r6b0", "r7b0",
"r0b1", "r1b1", "r2b1", "r3b1", "r4b1", "r5b1", "r6b1", "r7b1",
};
struct {
char **regnames;
int mach;
} sh_processor_type_table[] = {
{ sh_reg_names, bfd_mach_sh },
{ sh3_reg_names, bfd_mach_sh3 },
{ sh3e_reg_names, bfd_mach_sh3e },
{ NULL, 0 }
};
/* Prologue looks like
[mov.l <regs>,@-r15]...
[sts.l pr,@-r15]
[mov.l r14,@-r15]
[mov r15,r14]
*/
#define IS_STS(x) ((x) == 0x4f22)
#define IS_PUSH(x) (((x) & 0xff0f) == 0x2f06)
#define GET_PUSHED_REG(x) (((x) >> 4) & 0xf)
#define IS_MOV_SP_FP(x) ((x) == 0x6ef3)
#define IS_ADD_SP(x) (((x) & 0xff00) == 0x7f00)
#define IS_MOV_R3(x) (((x) & 0xff00) == 0x1a00)
#define IS_SHLL_R3(x) ((x) == 0x4300)
#define IS_ADD_R3SP(x) ((x) == 0x3f3c)
/* Skip any prologue before the guts of a function */
CORE_ADDR
sh_skip_prologue (start_pc)
CORE_ADDR start_pc;
{
int w;
w = read_memory_integer (start_pc, 2);
while (IS_STS (w)
|| IS_PUSH (w)
|| IS_MOV_SP_FP (w)
|| IS_MOV_R3 (w)
|| IS_ADD_R3SP (w)
|| IS_ADD_SP (w)
|| IS_SHLL_R3 (w))
{
start_pc += 2;
w = read_memory_integer (start_pc, 2);
}
return start_pc;
}
/* Disassemble an instruction. */
int
gdb_print_insn_sh (memaddr, info)
bfd_vma memaddr;
disassemble_info *info;
{
if (TARGET_BYTE_ORDER == BIG_ENDIAN)
return print_insn_sh (memaddr, info);
else
return print_insn_shl (memaddr, info);
}
/* Given a GDB frame, determine the address of the calling function's frame.
This will be used to create a new GDB frame struct, and then
INIT_EXTRA_FRAME_INFO and INIT_FRAME_PC will be called for the new frame.
For us, the frame address is its stack pointer value, so we look up
the function prologue to determine the caller's sp value, and return it. */
CORE_ADDR
sh_frame_chain (frame)
struct frame_info *frame;
{
if (PC_IN_CALL_DUMMY (frame->pc, frame->frame, frame->frame))
return frame->frame; /* dummy frame same as caller's frame */
if (!inside_entry_file (frame->pc))
return read_memory_integer (FRAME_FP (frame) + frame->f_offset, 4);
else
return 0;
}
/* Find REGNUM on the stack. Otherwise, it's in an active register. One thing
we might want to do here is to check REGNUM against the clobber mask, and
somehow flag it as invalid if it isn't saved on the stack somewhere. This
would provide a graceful failure mode when trying to get the value of
caller-saves registers for an inner frame. */
CORE_ADDR
sh_find_callers_reg (fi, regnum)
struct frame_info *fi;
int regnum;
{
struct frame_saved_regs fsr;
for (; fi; fi = fi->next)
if (PC_IN_CALL_DUMMY (fi->pc, fi->frame, fi->frame))
/* When the caller requests PR from the dummy frame, we return PC because
that's where the previous routine appears to have done a call from. */
return generic_read_register_dummy (fi->pc, fi->frame, regnum);
else
{
FRAME_FIND_SAVED_REGS(fi, fsr);
if (fsr.regs[regnum] != 0)
return read_memory_integer (fsr.regs[regnum],
REGISTER_RAW_SIZE(regnum));
}
return read_register (regnum);
}
/* Put here the code to store, into a struct frame_saved_regs, the
addresses of the saved registers of frame described by FRAME_INFO.
This includes special registers such as pc and fp saved in special
ways in the stack frame. sp is even more special: the address we
return for it IS the sp for the next frame. */
void
sh_frame_find_saved_regs (fi, fsr)
struct frame_info *fi;
struct frame_saved_regs *fsr;
{
int where[NUM_REGS];
int rn;
int have_fp = 0;
int depth;
int pc;
int opc;
int insn;
int r3_val = 0;
char * dummy_regs = generic_find_dummy_frame (fi->pc, fi->frame);
if (dummy_regs)
{
/* DANGER! This is ONLY going to work if the char buffer format of
the saved registers is byte-for-byte identical to the
CORE_ADDR regs[NUM_REGS] format used by struct frame_saved_regs! */
memcpy (&fsr->regs, dummy_regs, sizeof(fsr));
return;
}
opc = pc = get_pc_function_start (fi->pc);
insn = read_memory_integer (pc, 2);
fi->leaf_function = 1;
fi->f_offset = 0;
for (rn = 0; rn < NUM_REGS; rn++)
where[rn] = -1;
depth = 0;
/* Loop around examining the prologue insns until we find something
that does not appear to be part of the prologue. But give up
after 20 of them, since we're getting silly then. */
while (pc < opc + 20 * 2)
{
/* See where the registers will be saved to */
if (IS_PUSH (insn))
{
pc += 2;
rn = GET_PUSHED_REG (insn);
where[rn] = depth;
insn = read_memory_integer (pc, 2);
depth += 4;
}
else if (IS_STS (insn))
{
pc += 2;
where[PR_REGNUM] = depth;
insn = read_memory_integer (pc, 2);
/* If we're storing the pr then this isn't a leaf */
fi->leaf_function = 0;
depth += 4;
}
else if (IS_MOV_R3 (insn))
{
r3_val = ((insn & 0xff) ^ 0x80) - 0x80;
pc += 2;
insn = read_memory_integer (pc, 2);
}
else if (IS_SHLL_R3 (insn))
{
r3_val <<= 1;
pc += 2;
insn = read_memory_integer (pc, 2);
}
else if (IS_ADD_R3SP (insn))
{
depth += -r3_val;
pc += 2;
insn = read_memory_integer (pc, 2);
}
else if (IS_ADD_SP (insn))
{
pc += 2;
depth -= ((insn & 0xff) ^ 0x80) - 0x80;
insn = read_memory_integer (pc, 2);
}
else
break;
}
/* Now we know how deep things are, we can work out their addresses */
for (rn = 0; rn < NUM_REGS; rn++)
{
if (where[rn] >= 0)
{
if (rn == FP_REGNUM)
have_fp = 1;
fsr->regs[rn] = fi->frame - where[rn] + depth - 4;
}
else
{
fsr->regs[rn] = 0;
}
}
if (have_fp)
{
fsr->regs[SP_REGNUM] = read_memory_integer (fsr->regs[FP_REGNUM], 4);
}
else
{
fsr->regs[SP_REGNUM] = fi->frame - 4;
}
fi->f_offset = depth - where[FP_REGNUM] - 4;
/* Work out the return pc - either from the saved pr or the pr
value */
}
/* initialize the extra info saved in a FRAME */
void
sh_init_extra_frame_info (fromleaf, fi)
int fromleaf;
struct frame_info *fi;
{
struct frame_saved_regs fsr;
if (fi->next)
fi->pc = FRAME_SAVED_PC (fi->next);
if (PC_IN_CALL_DUMMY (fi->pc, fi->frame, fi->frame))
{
/* We need to setup fi->frame here because run_stack_dummy gets it wrong
by assuming it's always FP. */
fi->frame = generic_read_register_dummy (fi->pc, fi->frame,
SP_REGNUM);
fi->return_pc = generic_read_register_dummy (fi->pc, fi->frame,
PC_REGNUM);
fi->f_offset = -(CALL_DUMMY_LENGTH + 4);
fi->leaf_function = 0;
return;
}
else
{
FRAME_FIND_SAVED_REGS (fi, fsr);
fi->return_pc = sh_find_callers_reg (fi, PR_REGNUM);
}
}
/* Discard from the stack the innermost frame,
restoring all saved registers. */
void
sh_pop_frame ()
{
register struct frame_info *frame = get_current_frame ();
register CORE_ADDR fp;
register int regnum;
struct frame_saved_regs fsr;
if (PC_IN_CALL_DUMMY (frame->pc, frame->frame, frame->frame))
generic_pop_dummy_frame ();
else
{
fp = FRAME_FP (frame);
get_frame_saved_regs (frame, &fsr);
/* Copy regs from where they were saved in the frame */
for (regnum = 0; regnum < NUM_REGS; regnum++)
if (fsr.regs[regnum])
write_register (regnum, read_memory_integer (fsr.regs[regnum], 4));
write_register (PC_REGNUM, frame->return_pc);
write_register (SP_REGNUM, fp + 4);
}
flush_cached_frames ();
}
/* Function: push_arguments
Setup the function arguments for calling a function in the inferior.
On the Hitachi SH architecture, there are four registers (R4 to R7)
which are dedicated for passing function arguments. Up to the first
four arguments (depending on size) may go into these registers.
The rest go on the stack.
Arguments that are smaller than 4 bytes will still take up a whole
register or a whole 32-bit word on the stack, and will be
right-justified in the register or the stack word. This includes
chars, shorts, and small aggregate types.
Arguments that are larger than 4 bytes may be split between two or
more registers. If there are not enough registers free, an argument
may be passed partly in a register (or registers), and partly on the
stack. This includes doubles, long longs, and larger aggregates.
As far as I know, there is no upper limit to the size of aggregates
that will be passed in this way; in other words, the convention of
passing a pointer to a large aggregate instead of a copy is not used.
An exceptional case exists for struct arguments (and possibly other
aggregates such as arrays) if the size is larger than 4 bytes but
not a multiple of 4 bytes. In this case the argument is never split
between the registers and the stack, but instead is copied in its
entirety onto the stack, AND also copied into as many registers as
there is room for. In other words, space in registers permitting,
two copies of the same argument are passed in. As far as I can tell,
only the one on the stack is used, although that may be a function
of the level of compiler optimization. I suspect this is a compiler
bug. Arguments of these odd sizes are left-justified within the
word (as opposed to arguments smaller than 4 bytes, which are
right-justified).
If the function is to return an aggregate type such as a struct, it
is either returned in the normal return value register R0 (if its
size is no greater than one byte), or else the caller must allocate
space into which the callee will copy the return value (if the size
is greater than one byte). In this case, a pointer to the return
value location is passed into the callee in register R2, which does
not displace any of the other arguments passed in via registers R4
to R7. */
CORE_ADDR
sh_push_arguments (nargs, args, sp, struct_return, struct_addr)
int nargs;
value_ptr *args;
CORE_ADDR sp;
unsigned char struct_return;
CORE_ADDR struct_addr;
{
int stack_offset, stack_alloc;
int argreg;
int argnum;
struct type *type;
CORE_ADDR regval;
char *val;
char valbuf[4];
int len;
int odd_sized_struct;
/* first force sp to a 4-byte alignment */
sp = sp & ~3;
/* The "struct return pointer" pseudo-argument has its own dedicated
register */
if (struct_return)
write_register (STRUCT_RETURN_REGNUM, struct_addr);
/* Now make sure there's space on the stack */
for (argnum = 0, stack_alloc = 0;
argnum < nargs; argnum++)
stack_alloc += ((TYPE_LENGTH(VALUE_TYPE(args[argnum])) + 3) & ~3);
sp -= stack_alloc; /* make room on stack for args */
/* Now load as many as possible of the first arguments into
registers, and push the rest onto the stack. There are 16 bytes
in four registers available. Loop thru args from first to last. */
argreg = ARG0_REGNUM;
for (argnum = 0, stack_offset = 0; argnum < nargs; argnum++)
{
type = VALUE_TYPE (args[argnum]);
len = TYPE_LENGTH (type);
memset(valbuf, 0, sizeof(valbuf));
if (len < 4)
{ /* value gets right-justified in the register or stack word */
memcpy(valbuf + (4 - len),
(char *) VALUE_CONTENTS (args[argnum]), len);
val = valbuf;
}
else
val = (char *) VALUE_CONTENTS (args[argnum]);
if (len > 4 && (len & 3) != 0)
odd_sized_struct = 1; /* such structs go entirely on stack */
else
odd_sized_struct = 0;
while (len > 0)
{
if (argreg > ARGLAST_REGNUM || odd_sized_struct)
{ /* must go on the stack */
write_memory (sp + stack_offset, val, 4);
stack_offset += 4;
}
/* NOTE WELL!!!!! This is not an "else if" clause!!!
That's because some *&^%$ things get passed on the stack
AND in the registers! */
if (argreg <= ARGLAST_REGNUM)
{ /* there's room in a register */
regval = extract_address (val, REGISTER_RAW_SIZE(argreg));
write_register (argreg++, regval);
}
/* Store the value 4 bytes at a time. This means that things
larger than 4 bytes may go partly in registers and partly
on the stack. */
len -= REGISTER_RAW_SIZE(argreg);
val += REGISTER_RAW_SIZE(argreg);
}
}
return sp;
}
/* Function: push_return_address (pc)
Set up the return address for the inferior function call.
Needed for targets where we don't actually execute a JSR/BSR instruction */
CORE_ADDR
sh_push_return_address (pc, sp)
CORE_ADDR pc;
CORE_ADDR sp;
{
write_register (PR_REGNUM, CALL_DUMMY_ADDRESS ());
return sp;
}
/* Function: fix_call_dummy
Poke the callee function's address into the destination part of
the CALL_DUMMY. The address is actually stored in a data word
following the actualy CALL_DUMMY instructions, which will load
it into a register using PC-relative addressing. This function
expects the CALL_DUMMY to look like this:
mov.w @(2,PC), R8
jsr @R8
nop
trap
<destination>
*/
#if 0
void
sh_fix_call_dummy (dummy, pc, fun, nargs, args, type, gcc_p)
char *dummy;
CORE_ADDR pc;
CORE_ADDR fun;
int nargs;
value_ptr *args;
struct type *type;
int gcc_p;
{
*(unsigned long *) (dummy + 8) = fun;
}
#endif
/* Function: get_saved_register
Just call the generic_get_saved_register function. */
void
get_saved_register (raw_buffer, optimized, addrp, frame, regnum, lval)
char *raw_buffer;
int *optimized;
CORE_ADDR *addrp;
struct frame_info *frame;
int regnum;
enum lval_type *lval;
{
generic_get_saved_register (raw_buffer, optimized, addrp,
frame, regnum, lval);
}
/* Modify the actual processor type. */
int
sh_target_architecture_hook (ap)
const bfd_arch_info_type *ap;
{
int i, j;
if (ap->arch != bfd_arch_sh)
return 0;
for (i = 0; sh_processor_type_table[i].regnames != NULL; i++)
{
if (sh_processor_type_table[i].mach == ap->mach)
{
for (j = 0; j < NUM_REGS; ++j)
reg_names[j] = sh_processor_type_table[i].regnames[j];
return 1;
}
}
fatal ("Architecture `%s' unreconized", ap->printable_name);
}
/* Print the registers in a form similar to the E7000 */
static void
sh_show_regs (args, from_tty)
char *args;
int from_tty;
{
int cpu;
if (target_architecture->arch == bfd_arch_sh)
cpu = target_architecture->mach;
else
cpu = 0;
printf_filtered ("PC=%08x SR=%08x PR=%08x MACH=%08x MACHL=%08x\n",
read_register (PC_REGNUM),
read_register (SR_REGNUM),
read_register (PR_REGNUM),
read_register (MACH_REGNUM),
read_register (MACL_REGNUM));
printf_filtered ("GBR=%08x VBR=%08x",
read_register (GBR_REGNUM),
read_register (VBR_REGNUM));
if (cpu == bfd_mach_sh3 || cpu == bfd_mach_sh3e)
{
printf_filtered (" SSR=%08x SPC=%08x",
read_register (SSR_REGNUM),
read_register (SPC_REGNUM));
if (cpu == bfd_mach_sh3e)
{
printf_filtered (" FPUL=%08x FPSCR=%08x",
read_register (FPUL_REGNUM),
read_register (FPSCR_REGNUM));
}
}
printf_filtered ("\nR0-R7 %08x %08x %08x %08x %08x %08x %08x %08x\n",
read_register (0),
read_register (1),
read_register (2),
read_register (3),
read_register (4),
read_register (5),
read_register (6),
read_register (7));
printf_filtered ("R8-R15 %08x %08x %08x %08x %08x %08x %08x %08x\n",
read_register (8),
read_register (9),
read_register (10),
read_register (11),
read_register (12),
read_register (13),
read_register (14),
read_register (15));
if (cpu == bfd_mach_sh3e)
{
printf_filtered ("FP0-FP7 %08x %08x %08x %08x %08x %08x %08x %08x\n",
read_register (FP0_REGNUM + 0),
read_register (FP0_REGNUM + 1),
read_register (FP0_REGNUM + 2),
read_register (FP0_REGNUM + 3),
read_register (FP0_REGNUM + 4),
read_register (FP0_REGNUM + 5),
read_register (FP0_REGNUM + 6),
read_register (FP0_REGNUM + 7));
printf_filtered ("FP8-FP15 %08x %08x %08x %08x %08x %08x %08x %08x\n",
read_register (FP0_REGNUM + 8),
read_register (FP0_REGNUM + 9),
read_register (FP0_REGNUM + 10),
read_register (FP0_REGNUM + 11),
read_register (FP0_REGNUM + 12),
read_register (FP0_REGNUM + 13),
read_register (FP0_REGNUM + 14),
read_register (FP0_REGNUM + 15));
}
}
/* Function: extract_return_value
Find a function's return value in the appropriate registers (in regbuf),
and copy it into valbuf. */
void
sh_extract_return_value (type, regbuf, valbuf)
struct type *type;
void *regbuf;
void *valbuf;
{
int len = TYPE_LENGTH(type);
if (len <= 4)
memcpy (valbuf, ((char *) regbuf) + 4 - len, len);
else if (len <= 8)
memcpy (valbuf, ((char *) regbuf) + 8 - len, len);
else
error ("bad size for return value");
}
void
_initialize_sh_tdep ()
{
struct cmd_list_element *c;
tm_print_insn = gdb_print_insn_sh;
target_architecture_hook = sh_target_architecture_hook;
add_com ("regs", class_vars, sh_show_regs, "Print all registers");
}
#ifdef NO_SINGLE_STEP
/* Non-zero if we just simulated a single-step ptrace call. This is
needed because we cannot remove the breakpoints in the inferior
process until after the `wait' in `wait_for_inferior'. Used for
4.4bsd for mips, where the kernel does not emulate single-step. */
int one_stepped;
CORE_ADDR target_addr; /* Branch target offset, if we have a
breakpoint there... */
CORE_ADDR step_addr; /* Offset of instruction after instruction
to be stepped, if we have a breakpoint
there. */
long step_cache [3]; /* Cache for instructions wiped out by
step breakpoint(s)... */
/* single_step() is called just before we want to resume the inferior,
if we want to single-step it but there is no hardware or kernel single-step
support (as on NetBSD). We find all the possible targets of the
coming instruction and breakpoint them.
single_step is also called just after the inferior stops. If we had
set up a simulated single-step, we undo our damage. */
/* thoughts:
For the current instruction, check to see if we're in a delay slot.
If we are, the next instruction executed will either be the target of
the branch or jump instruction preceding the current instruction, or
it will be the instruction following the current instruction. If
we are not, then the next instruction executed will either be the
instruction following the current instruction, or the instruction
following that (if the current instruction is a branch likely instruction
and the branch is not taken).
So, if we are in a delay slot then we set a breakpoint for the target
of the preceding instruction. Unless the preceding instruction was
a jump instruction (only jumps are unconditional), we also set a break-
point at the instruction following the current one and the instruction
following that. Setting two breakpoints after the current instruction
is cheaper and easier than figuring out whether the current instruction
is a branch likely instruction. */
#define IS_JMP(x) (((x) & 0xf0ff) == 0x402b)
#define IS_JSR(x) (((x) & 0xf0ff) == 0x400b)
#define IS_RTS(x) ((x) == 0x000b)
#define IS_BRAF(x) (((x) & 0xf0ff) == 0x0023)
#define IS_BSRF(x) (((x) & 0xf0ff) == 0x0003)
#define IS_BSR(x) (((x) & 0xf000) == 0xb000)
#define IS_BRA(x) (((x) & 0xf000) == 0xa000)
#define IS_BTS(x) (((x) & 0xff00) == 0x8d00)
#define IS_BFS(x) (((x) & 0xff00) == 0x8f00)
#define IS_BT(x) (((x) & 0xff00) == 0x8900)
#define IS_BF(x) (((x) & 0xff00) == 0x8b00)
#define IS_PCLOADFROMREG(x) ((IS_JMP(x)) || (IS_JSR(x)))
#define IS_ADDPCBYREG(x) ((IS_BRAF(x)) || (IS_BSRF(x)))
#define IS_ADDPCBYIMM(x) ((IS_BSR(x)) || (IS_BRA(x)) || (IS_BFS(x)) \
|| (IS_BTS(x)))
#define IS_ADDPCBYIMM_ND(x) ((IS_BF(x)) || (IS_BT(x)))
#define IS_DELAYEDBRANCH(x) (IS_PCLOADFROMREG(x) || IS_RTS(x) \
|| IS_ADDPCBYREG(x) || IS_ADDPCBYIMM(x))
#define IS_BRANCH(x) (IS_DELAYEDBRANCH(x) || IS_ADDPCBYIMM_ND(x))
#define M2REG(x) (((x) & 0x0f00) >> 8)
#define GETIMM8(x) ((x) & 0x00ff)
#define IMM8SIGN(x) ((x) & 0x0080)
#define GETIMM12(x) ((x) & 0x0fff)
#define IMM12SIGN(x) ((x) & 0x0800)
void
single_step (ignore)
enum target_signal ignore; /* not used */
{
CORE_ADDR pc;
CORE_ADDR epc;
CORE_ADDR next;
unsigned short delay_instruction;
CORE_ADDR offset;
unsigned short insn;
if (!one_stepped)
{
pc = epc = read_register (PC_REGNUM);
insn = read_memory_integer(pc, sizeof(insn));
if (IS_DELAYEDBRANCH(insn))
pc += 2;
next = pc + 2;
target_addr = 0;
step_addr = next;
if (IS_BRANCH(insn))
{
if (IS_PCLOADFROMREG(insn)) {
target_addr = read_register(M2REG (insn));
step_addr = 0;
} else if (IS_RTS(insn)) {
target_addr = read_register(PR_REGNUM);
step_addr = 0;
} else if (IS_ADDPCBYREG(insn)) {
target_addr = next + read_register(M2REG (insn));
step_addr = 0;
} else if (IS_BT(insn) || IS_BF(insn) || IS_BTS(insn)
|| IS_BFS(insn)) {
target_addr = GETIMM8(insn);
if (IMM8SIGN(insn))
target_addr |= ~(CORE_ADDR)0x00ff;
target_addr = epc + 4 + (target_addr << 1);
} else if (IS_BSR(insn) || IS_BRA(insn)) {
target_addr = GETIMM12(insn);
if (IMM12SIGN(insn))
target_addr |= ~(CORE_ADDR)0x0fff;
target_addr = next + (target_addr << 1);
step_addr = 0;
}
}
/* Don't try to put down two breakpoints in the same spot... */
if (step_addr == target_addr)
target_addr = 0;
if (step_addr)
{
target_insert_breakpoint (step_addr, (char *)&step_cache [0]);
if (step_addr + 2 != target_addr)
target_insert_breakpoint (step_addr + 2, (char *)&step_cache [1]);
}
if (target_addr)
{
target_insert_breakpoint (target_addr, (char *)&step_cache [2]);
}
/* If the breakpoint occurred in a branch instruction,
re-run the branch (the breakpoint instruction should
be gone by now)... */
if (epc != pc)
{
write_register (PC_REGNUM, epc);
}
one_stepped = 1;
return;
}
else
{
pc = epc = read_register(PC_REGNUM);
write_pc(pc -= 2);
insn = read_memory_integer(pc, sizeof(insn));
/* Remove step breakpoints */
if (step_addr)
{
target_remove_breakpoint (step_addr, (char *)&step_cache [0]);
if (step_addr + 2 != target_addr)
target_remove_breakpoint (step_addr + 2, (char *)&step_cache [1]);
}
if (target_addr)
{
target_remove_breakpoint (target_addr, (char *)&step_cache [2]);
target_addr = 0;
}
one_stepped = 0;
}
}
#endif /* NO_SINGLE_STEP */