/* Target-dependent code for Renesas Super-H, for GDB.
Copyright (C) 1993-2020 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 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see . */
/* Contributed by Steve Chamberlain
sac@cygnus.com. */
#include "defs.h"
#include "frame.h"
#include "frame-base.h"
#include "frame-unwind.h"
#include "dwarf2/frame.h"
#include "symtab.h"
#include "gdbtypes.h"
#include "gdbcmd.h"
#include "gdbcore.h"
#include "value.h"
#include "dis-asm.h"
#include "inferior.h"
#include "arch-utils.h"
#include "regcache.h"
#include "target-float.h"
#include "osabi.h"
#include "reggroups.h"
#include "regset.h"
#include "objfiles.h"
#include "sh-tdep.h"
#include "elf-bfd.h"
#include "solib-svr4.h"
/* sh flags */
#include "elf/sh.h"
#include "dwarf2.h"
/* registers numbers shared with the simulator. */
#include "gdb/sim-sh.h"
#include
/* List of "set sh ..." and "show sh ..." commands. */
static struct cmd_list_element *setshcmdlist = NULL;
static struct cmd_list_element *showshcmdlist = NULL;
static const char sh_cc_gcc[] = "gcc";
static const char sh_cc_renesas[] = "renesas";
static const char *const sh_cc_enum[] = {
sh_cc_gcc,
sh_cc_renesas,
NULL
};
static const char *sh_active_calling_convention = sh_cc_gcc;
#define SH_NUM_REGS 67
struct sh_frame_cache
{
/* Base address. */
CORE_ADDR base;
LONGEST sp_offset;
CORE_ADDR pc;
/* Flag showing that a frame has been created in the prologue code. */
int uses_fp;
/* Saved registers. */
CORE_ADDR saved_regs[SH_NUM_REGS];
CORE_ADDR saved_sp;
};
static int
sh_is_renesas_calling_convention (struct type *func_type)
{
int val = 0;
if (func_type)
{
func_type = check_typedef (func_type);
if (func_type->code () == TYPE_CODE_PTR)
func_type = check_typedef (TYPE_TARGET_TYPE (func_type));
if (func_type->code () == TYPE_CODE_FUNC
&& TYPE_CALLING_CONVENTION (func_type) == DW_CC_GNU_renesas_sh)
val = 1;
}
if (sh_active_calling_convention == sh_cc_renesas)
val = 1;
return val;
}
static const char *
sh_sh_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh3_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_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"
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh3e_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_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",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh2e_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_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",
"", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh2a_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
/* general registers 0-15 */
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
/* 16 - 22 */
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
/* 23, 24 */
"fpul", "fpscr",
/* floating point registers 25 - 40 */
"fr0", "fr1", "fr2", "fr3", "fr4", "fr5", "fr6", "fr7",
"fr8", "fr9", "fr10", "fr11", "fr12", "fr13", "fr14", "fr15",
/* 41, 42 */
"", "",
/* 43 - 62. Banked registers. The bank number used is determined by
the bank register (63). */
"r0b", "r1b", "r2b", "r3b", "r4b", "r5b", "r6b", "r7b",
"r8b", "r9b", "r10b", "r11b", "r12b", "r13b", "r14b",
"machb", "ivnb", "prb", "gbrb", "maclb",
/* 63: register bank number, not a real register but used to
communicate the register bank currently get/set. This register
is hidden to the user, who manipulates it using the pseudo
register called "bank" (67). See below. */
"",
/* 64 - 66 */
"ibcr", "ibnr", "tbr",
/* 67: register bank number, the user visible pseudo register. */
"bank",
/* double precision (pseudo) 68 - 75 */
"dr0", "dr2", "dr4", "dr6", "dr8", "dr10", "dr12", "dr14",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh2a_nofpu_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
/* general registers 0-15 */
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
/* 16 - 22 */
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
/* 23, 24 */
"", "",
/* floating point registers 25 - 40 */
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
/* 41, 42 */
"", "",
/* 43 - 62. Banked registers. The bank number used is determined by
the bank register (63). */
"r0b", "r1b", "r2b", "r3b", "r4b", "r5b", "r6b", "r7b",
"r8b", "r9b", "r10b", "r11b", "r12b", "r13b", "r14b",
"machb", "ivnb", "prb", "gbrb", "maclb",
/* 63: register bank number, not a real register but used to
communicate the register bank currently get/set. This register
is hidden to the user, who manipulates it using the pseudo
register called "bank" (67). See below. */
"",
/* 64 - 66 */
"ibcr", "ibnr", "tbr",
/* 67: register bank number, the user visible pseudo register. */
"bank",
/* double precision (pseudo) 68 - 75 */
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh_dsp_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "dsr",
"a0g", "a0", "a1g", "a1", "m0", "m1", "x0", "x1",
"y0", "y1", "", "", "", "", "", "mod",
"", "",
"rs", "re", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh3_dsp_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "dsr",
"a0g", "a0", "a1g", "a1", "m0", "m1", "x0", "x1",
"y0", "y1", "", "", "", "", "", "mod",
"ssr", "spc",
"rs", "re", "", "", "", "", "", "",
"r0b", "r1b", "r2b", "r3b", "r4b", "r5b", "r6b", "r7b",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh4_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
/* general registers 0-15 */
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
/* 16 - 22 */
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
/* 23, 24 */
"fpul", "fpscr",
/* floating point registers 25 - 40 */
"fr0", "fr1", "fr2", "fr3", "fr4", "fr5", "fr6", "fr7",
"fr8", "fr9", "fr10", "fr11", "fr12", "fr13", "fr14", "fr15",
/* 41, 42 */
"ssr", "spc",
/* bank 0 43 - 50 */
"r0b0", "r1b0", "r2b0", "r3b0", "r4b0", "r5b0", "r6b0", "r7b0",
/* bank 1 51 - 58 */
"r0b1", "r1b1", "r2b1", "r3b1", "r4b1", "r5b1", "r6b1", "r7b1",
/* 59 - 66 */
"", "", "", "", "", "", "", "",
/* pseudo bank register. */
"",
/* double precision (pseudo) 68 - 75 */
"dr0", "dr2", "dr4", "dr6", "dr8", "dr10", "dr12", "dr14",
/* vectors (pseudo) 76 - 79 */
"fv0", "fv4", "fv8", "fv12",
/* FIXME: missing XF */
/* FIXME: missing XD */
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh4_nofpu_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
/* general registers 0-15 */
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
/* 16 - 22 */
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
/* 23, 24 */
"", "",
/* floating point registers 25 - 40 -- not for nofpu target */
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
/* 41, 42 */
"ssr", "spc",
/* bank 0 43 - 50 */
"r0b0", "r1b0", "r2b0", "r3b0", "r4b0", "r5b0", "r6b0", "r7b0",
/* bank 1 51 - 58 */
"r0b1", "r1b1", "r2b1", "r3b1", "r4b1", "r5b1", "r6b1", "r7b1",
/* 59 - 66 */
"", "", "", "", "", "", "", "",
/* pseudo bank register. */
"",
/* double precision (pseudo) 68 - 75 -- not for nofpu target */
"", "", "", "", "", "", "", "",
/* vectors (pseudo) 76 - 79 -- not for nofpu target */
"", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
static const char *
sh_sh4al_dsp_register_name (struct gdbarch *gdbarch, int reg_nr)
{
static const char *register_names[] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"pc", "pr", "gbr", "vbr", "mach", "macl", "sr",
"", "dsr",
"a0g", "a0", "a1g", "a1", "m0", "m1", "x0", "x1",
"y0", "y1", "", "", "", "", "", "mod",
"ssr", "spc",
"rs", "re", "", "", "", "", "", "",
"r0b", "r1b", "r2b", "r3b", "r4b", "r5b", "r6b", "r7b",
"", "", "", "", "", "", "", "",
"", "", "", "", "", "", "", "",
};
if (reg_nr < 0)
return NULL;
if (reg_nr >= (sizeof (register_names) / sizeof (*register_names)))
return NULL;
return register_names[reg_nr];
}
/* Implement the breakpoint_kind_from_pc gdbarch method. */
static int
sh_breakpoint_kind_from_pc (struct gdbarch *gdbarch, CORE_ADDR *pcptr)
{
return 2;
}
/* Implement the sw_breakpoint_from_kind gdbarch method. */
static const gdb_byte *
sh_sw_breakpoint_from_kind (struct gdbarch *gdbarch, int kind, int *size)
{
*size = kind;
/* For remote stub targets, trapa #20 is used. */
if (strcmp (target_shortname, "remote") == 0)
{
static unsigned char big_remote_breakpoint[] = { 0xc3, 0x20 };
static unsigned char little_remote_breakpoint[] = { 0x20, 0xc3 };
if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG)
return big_remote_breakpoint;
else
return little_remote_breakpoint;
}
else
{
/* 0xc3c3 is trapa #c3, and it works in big and little endian
modes. */
static unsigned char breakpoint[] = { 0xc3, 0xc3 };
return breakpoint;
}
}
/* Prologue looks like
mov.l r14,@-r15
sts.l pr,@-r15
mov.l ,@-r15
sub ,r15
mov r15,r14
Actually it can be more complicated than this but that's it, basically. */
#define GET_SOURCE_REG(x) (((x) >> 4) & 0xf)
#define GET_TARGET_REG(x) (((x) >> 8) & 0xf)
/* JSR @Rm 0100mmmm00001011 */
#define IS_JSR(x) (((x) & 0xf0ff) == 0x400b)
/* STS.L PR,@-r15 0100111100100010
r15-4-->r15, PR-->(r15) */
#define IS_STS(x) ((x) == 0x4f22)
/* STS.L MACL,@-r15 0100111100010010
r15-4-->r15, MACL-->(r15) */
#define IS_MACL_STS(x) ((x) == 0x4f12)
/* MOV.L Rm,@-r15 00101111mmmm0110
r15-4-->r15, Rm-->(R15) */
#define IS_PUSH(x) (((x) & 0xff0f) == 0x2f06)
/* MOV r15,r14 0110111011110011
r15-->r14 */
#define IS_MOV_SP_FP(x) ((x) == 0x6ef3)
/* ADD #imm,r15 01111111iiiiiiii
r15+imm-->r15 */
#define IS_ADD_IMM_SP(x) (((x) & 0xff00) == 0x7f00)
#define IS_MOV_R3(x) (((x) & 0xff00) == 0x1a00)
#define IS_SHLL_R3(x) ((x) == 0x4300)
/* ADD r3,r15 0011111100111100
r15+r3-->r15 */
#define IS_ADD_R3SP(x) ((x) == 0x3f3c)
/* FMOV.S FRm,@-Rn Rn-4-->Rn, FRm-->(Rn) 1111nnnnmmmm1011
FMOV DRm,@-Rn Rn-8-->Rn, DRm-->(Rn) 1111nnnnmmm01011
FMOV XDm,@-Rn Rn-8-->Rn, XDm-->(Rn) 1111nnnnmmm11011 */
/* CV, 2003-08-28: Only suitable with Rn == SP, therefore name changed to
make this entirely clear. */
/* #define IS_FMOV(x) (((x) & 0xf00f) == 0xf00b) */
#define IS_FPUSH(x) (((x) & 0xff0f) == 0xff0b)
/* MOV Rm,Rn Rm-->Rn 0110nnnnmmmm0011 4 <= m <= 7 */
#define IS_MOV_ARG_TO_REG(x) \
(((x) & 0xf00f) == 0x6003 && \
((x) & 0x00f0) >= 0x0040 && \
((x) & 0x00f0) <= 0x0070)
/* MOV.L Rm,@Rn 0010nnnnmmmm0010 n = 14, 4 <= m <= 7 */
#define IS_MOV_ARG_TO_IND_R14(x) \
(((x) & 0xff0f) == 0x2e02 && \
((x) & 0x00f0) >= 0x0040 && \
((x) & 0x00f0) <= 0x0070)
/* MOV.L Rm,@(disp*4,Rn) 00011110mmmmdddd n = 14, 4 <= m <= 7 */
#define IS_MOV_ARG_TO_IND_R14_WITH_DISP(x) \
(((x) & 0xff00) == 0x1e00 && \
((x) & 0x00f0) >= 0x0040 && \
((x) & 0x00f0) <= 0x0070)
/* MOV.W @(disp*2,PC),Rn 1001nnnndddddddd */
#define IS_MOVW_PCREL_TO_REG(x) (((x) & 0xf000) == 0x9000)
/* MOV.L @(disp*4,PC),Rn 1101nnnndddddddd */
#define IS_MOVL_PCREL_TO_REG(x) (((x) & 0xf000) == 0xd000)
/* MOVI20 #imm20,Rn 0000nnnniiii0000 */
#define IS_MOVI20(x) (((x) & 0xf00f) == 0x0000)
/* SUB Rn,R15 00111111nnnn1000 */
#define IS_SUB_REG_FROM_SP(x) (((x) & 0xff0f) == 0x3f08)
#define FPSCR_SZ (1 << 20)
/* The following instructions are used for epilogue testing. */
#define IS_RESTORE_FP(x) ((x) == 0x6ef6)
#define IS_RTS(x) ((x) == 0x000b)
#define IS_LDS(x) ((x) == 0x4f26)
#define IS_MACL_LDS(x) ((x) == 0x4f16)
#define IS_MOV_FP_SP(x) ((x) == 0x6fe3)
#define IS_ADD_REG_TO_FP(x) (((x) & 0xff0f) == 0x3e0c)
#define IS_ADD_IMM_FP(x) (((x) & 0xff00) == 0x7e00)
static CORE_ADDR
sh_analyze_prologue (struct gdbarch *gdbarch,
CORE_ADDR pc, CORE_ADDR limit_pc,
struct sh_frame_cache *cache, ULONGEST fpscr)
{
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
ULONGEST inst;
int offset;
int sav_offset = 0;
int r3_val = 0;
int reg, sav_reg = -1;
cache->uses_fp = 0;
for (; pc < limit_pc; pc += 2)
{
inst = read_memory_unsigned_integer (pc, 2, byte_order);
/* See where the registers will be saved to. */
if (IS_PUSH (inst))
{
cache->saved_regs[GET_SOURCE_REG (inst)] = cache->sp_offset;
cache->sp_offset += 4;
}
else if (IS_STS (inst))
{
cache->saved_regs[PR_REGNUM] = cache->sp_offset;
cache->sp_offset += 4;
}
else if (IS_MACL_STS (inst))
{
cache->saved_regs[MACL_REGNUM] = cache->sp_offset;
cache->sp_offset += 4;
}
else if (IS_MOV_R3 (inst))
{
r3_val = ((inst & 0xff) ^ 0x80) - 0x80;
}
else if (IS_SHLL_R3 (inst))
{
r3_val <<= 1;
}
else if (IS_ADD_R3SP (inst))
{
cache->sp_offset += -r3_val;
}
else if (IS_ADD_IMM_SP (inst))
{
offset = ((inst & 0xff) ^ 0x80) - 0x80;
cache->sp_offset -= offset;
}
else if (IS_MOVW_PCREL_TO_REG (inst))
{
if (sav_reg < 0)
{
reg = GET_TARGET_REG (inst);
if (reg < 14)
{
sav_reg = reg;
offset = (inst & 0xff) << 1;
sav_offset =
read_memory_integer ((pc + 4) + offset, 2, byte_order);
}
}
}
else if (IS_MOVL_PCREL_TO_REG (inst))
{
if (sav_reg < 0)
{
reg = GET_TARGET_REG (inst);
if (reg < 14)
{
sav_reg = reg;
offset = (inst & 0xff) << 2;
sav_offset =
read_memory_integer (((pc & 0xfffffffc) + 4) + offset,
4, byte_order);
}
}
}
else if (IS_MOVI20 (inst)
&& (pc + 2 < limit_pc))
{
if (sav_reg < 0)
{
reg = GET_TARGET_REG (inst);
if (reg < 14)
{
sav_reg = reg;
sav_offset = GET_SOURCE_REG (inst) << 16;
/* MOVI20 is a 32 bit instruction! */
pc += 2;
sav_offset
|= read_memory_unsigned_integer (pc, 2, byte_order);
/* Now sav_offset contains an unsigned 20 bit value.
It must still get sign extended. */
if (sav_offset & 0x00080000)
sav_offset |= 0xfff00000;
}
}
}
else if (IS_SUB_REG_FROM_SP (inst))
{
reg = GET_SOURCE_REG (inst);
if (sav_reg > 0 && reg == sav_reg)
{
sav_reg = -1;
}
cache->sp_offset += sav_offset;
}
else if (IS_FPUSH (inst))
{
if (fpscr & FPSCR_SZ)
{
cache->sp_offset += 8;
}
else
{
cache->sp_offset += 4;
}
}
else if (IS_MOV_SP_FP (inst))
{
pc += 2;
/* Don't go any further than six more instructions. */
limit_pc = std::min (limit_pc, pc + (2 * 6));
cache->uses_fp = 1;
/* At this point, only allow argument register moves to other
registers or argument register moves to @(X,fp) which are
moving the register arguments onto the stack area allocated
by a former add somenumber to SP call. Don't allow moving
to an fp indirect address above fp + cache->sp_offset. */
for (; pc < limit_pc; pc += 2)
{
inst = read_memory_integer (pc, 2, byte_order);
if (IS_MOV_ARG_TO_IND_R14 (inst))
{
reg = GET_SOURCE_REG (inst);
if (cache->sp_offset > 0)
cache->saved_regs[reg] = cache->sp_offset;
}
else if (IS_MOV_ARG_TO_IND_R14_WITH_DISP (inst))
{
reg = GET_SOURCE_REG (inst);
offset = (inst & 0xf) * 4;
if (cache->sp_offset > offset)
cache->saved_regs[reg] = cache->sp_offset - offset;
}
else if (IS_MOV_ARG_TO_REG (inst))
continue;
else
break;
}
break;
}
else if (IS_JSR (inst))
{
/* We have found a jsr that has been scheduled into the prologue.
If we continue the scan and return a pc someplace after this,
then setting a breakpoint on this function will cause it to
appear to be called after the function it is calling via the
jsr, which will be very confusing. Most likely the next
instruction is going to be IS_MOV_SP_FP in the delay slot. If
so, note that before returning the current pc. */
if (pc + 2 < limit_pc)
{
inst = read_memory_integer (pc + 2, 2, byte_order);
if (IS_MOV_SP_FP (inst))
cache->uses_fp = 1;
}
break;
}
#if 0 /* This used to just stop when it found an instruction
that was not considered part of the prologue. Now,
we just keep going looking for likely
instructions. */
else
break;
#endif
}
return pc;
}
/* Skip any prologue before the guts of a function. */
static CORE_ADDR
sh_skip_prologue (struct gdbarch *gdbarch, CORE_ADDR pc)
{
CORE_ADDR post_prologue_pc, func_addr, func_end_addr, limit_pc;
struct sh_frame_cache cache;
/* See if we can determine the end of the prologue via the symbol table.
If so, then return either PC, or the PC after the prologue, whichever
is greater. */
if (find_pc_partial_function (pc, NULL, &func_addr, &func_end_addr))
{
post_prologue_pc = skip_prologue_using_sal (gdbarch, func_addr);
if (post_prologue_pc != 0)
return std::max (pc, post_prologue_pc);
}
/* Can't determine prologue from the symbol table, need to examine
instructions. */
/* Find an upper limit on the function prologue using the debug
information. If the debug information could not be used to provide
that bound, then use an arbitrary large number as the upper bound. */
limit_pc = skip_prologue_using_sal (gdbarch, pc);
if (limit_pc == 0)
/* Don't go any further than 28 instructions. */
limit_pc = pc + (2 * 28);
/* Do not allow limit_pc to be past the function end, if we know
where that end is... */
if (func_end_addr != 0)
limit_pc = std::min (limit_pc, func_end_addr);
cache.sp_offset = -4;
post_prologue_pc = sh_analyze_prologue (gdbarch, pc, limit_pc, &cache, 0);
if (cache.uses_fp)
pc = post_prologue_pc;
return pc;
}
/* The ABI says:
Aggregate types not bigger than 8 bytes that have the same size and
alignment as one of the integer scalar types are returned in the
same registers as the integer type they match.
For example, a 2-byte aligned structure with size 2 bytes has the
same size and alignment as a short int, and will be returned in R0.
A 4-byte aligned structure with size 8 bytes has the same size and
alignment as a long long int, and will be returned in R0 and R1.
When an aggregate type is returned in R0 and R1, R0 contains the
first four bytes of the aggregate, and R1 contains the
remainder. If the size of the aggregate type is not a multiple of 4
bytes, the aggregate is tail-padded up to a multiple of 4
bytes. The value of the padding is undefined. For little-endian
targets the padding will appear at the most significant end of the
last element, for big-endian targets the padding appears at the
least significant end of the last element.
All other aggregate types are returned by address. The caller
function passes the address of an area large enough to hold the
aggregate value in R2. The called function stores the result in
this location.
To reiterate, structs smaller than 8 bytes could also be returned
in memory, if they don't pass the "same size and alignment as an
integer type" rule.
For example, in
struct s { char c[3]; } wibble;
struct s foo(void) { return wibble; }
the return value from foo() will be in memory, not
in R0, because there is no 3-byte integer type.
Similarly, in
struct s { char c[2]; } wibble;
struct s foo(void) { return wibble; }
because a struct containing two chars has alignment 1, that matches
type char, but size 2, that matches type short. There's no integer
type that has alignment 1 and size 2, so the struct is returned in
memory. */
static int
sh_use_struct_convention (int renesas_abi, struct type *type)
{
int len = TYPE_LENGTH (type);
int nelem = type->num_fields ();
/* The Renesas ABI returns aggregate types always on stack. */
if (renesas_abi && (type->code () == TYPE_CODE_STRUCT
|| type->code () == TYPE_CODE_UNION))
return 1;
/* Non-power of 2 length types and types bigger than 8 bytes (which don't
fit in two registers anyway) use struct convention. */
if (len != 1 && len != 2 && len != 4 && len != 8)
return 1;
/* Scalar types and aggregate types with exactly one field are aligned
by definition. They are returned in registers. */
if (nelem <= 1)
return 0;
/* If the first field in the aggregate has the same length as the entire
aggregate type, the type is returned in registers. */
if (TYPE_LENGTH (TYPE_FIELD_TYPE (type, 0)) == len)
return 0;
/* If the size of the aggregate is 8 bytes and the first field is
of size 4 bytes its alignment is equal to long long's alignment,
so it's returned in registers. */
if (len == 8 && TYPE_LENGTH (TYPE_FIELD_TYPE (type, 0)) == 4)
return 0;
/* Otherwise use struct convention. */
return 1;
}
static int
sh_use_struct_convention_nofpu (int renesas_abi, struct type *type)
{
/* The Renesas ABI returns long longs/doubles etc. always on stack. */
if (renesas_abi && type->num_fields () == 0 && TYPE_LENGTH (type) >= 8)
return 1;
return sh_use_struct_convention (renesas_abi, type);
}
static CORE_ADDR
sh_frame_align (struct gdbarch *ignore, CORE_ADDR sp)
{
return sp & ~3;
}
/* Function: push_dummy_call (formerly push_arguments)
Setup the function arguments for calling a function in the inferior.
On the Renesas 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.
MVS: Except on SH variants that have floating point registers.
In that case, float and double arguments are passed in the same
manner, but using FP registers instead of GP registers.
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.
MVS: The above appears to be true for the SH variants that do not
have an FPU, however those that have an FPU appear to copy the
aggregate argument onto the stack (and not place it in registers)
if it is larger than 16 bytes (four GP registers).
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. */
/* Helper function to justify value in register according to endianness. */
static const gdb_byte *
sh_justify_value_in_reg (struct gdbarch *gdbarch, struct value *val, int len)
{
static gdb_byte valbuf[4];
memset (valbuf, 0, sizeof (valbuf));
if (len < 4)
{
/* value gets right-justified in the register or stack word. */
if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_BIG)
memcpy (valbuf + (4 - len), value_contents (val), len);
else
memcpy (valbuf, value_contents (val), len);
return valbuf;
}
return value_contents (val);
}
/* Helper function to eval number of bytes to allocate on stack. */
static CORE_ADDR
sh_stack_allocsize (int nargs, struct value **args)
{
int stack_alloc = 0;
while (nargs-- > 0)
stack_alloc += ((TYPE_LENGTH (value_type (args[nargs])) + 3) & ~3);
return stack_alloc;
}
/* Helper functions for getting the float arguments right. Registers usage
depends on the ABI and the endianness. The comments should enlighten how
it's intended to work. */
/* This array stores which of the float arg registers are already in use. */
static int flt_argreg_array[FLOAT_ARGLAST_REGNUM - FLOAT_ARG0_REGNUM + 1];
/* This function just resets the above array to "no reg used so far". */
static void
sh_init_flt_argreg (void)
{
memset (flt_argreg_array, 0, sizeof flt_argreg_array);
}
/* This function returns the next register to use for float arg passing.
It returns either a valid value between FLOAT_ARG0_REGNUM and
FLOAT_ARGLAST_REGNUM if a register is available, otherwise it returns
FLOAT_ARGLAST_REGNUM + 1 to indicate that no register is available.
Note that register number 0 in flt_argreg_array corresponds with the
real float register fr4. In contrast to FLOAT_ARG0_REGNUM (value is
29) the parity of the register number is preserved, which is important
for the double register passing test (see the "argreg & 1" test below). */
static int
sh_next_flt_argreg (struct gdbarch *gdbarch, int len, struct type *func_type)
{
int argreg;
/* First search for the next free register. */
for (argreg = 0; argreg <= FLOAT_ARGLAST_REGNUM - FLOAT_ARG0_REGNUM;
++argreg)
if (!flt_argreg_array[argreg])
break;
/* No register left? */
if (argreg > FLOAT_ARGLAST_REGNUM - FLOAT_ARG0_REGNUM)
return FLOAT_ARGLAST_REGNUM + 1;
if (len == 8)
{
/* Doubles are always starting in a even register number. */
if (argreg & 1)
{
/* In gcc ABI, the skipped register is lost for further argument
passing now. Not so in Renesas ABI. */
if (!sh_is_renesas_calling_convention (func_type))
flt_argreg_array[argreg] = 1;
++argreg;
/* No register left? */
if (argreg > FLOAT_ARGLAST_REGNUM - FLOAT_ARG0_REGNUM)
return FLOAT_ARGLAST_REGNUM + 1;
}
/* Also mark the next register as used. */
flt_argreg_array[argreg + 1] = 1;
}
else if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_LITTLE
&& !sh_is_renesas_calling_convention (func_type))
{
/* In little endian, gcc passes floats like this: f5, f4, f7, f6, ... */
if (!flt_argreg_array[argreg + 1])
++argreg;
}
flt_argreg_array[argreg] = 1;
return FLOAT_ARG0_REGNUM + argreg;
}
/* Helper function which figures out, if a type is treated like a float type.
The FPU ABIs have a special way how to treat types as float types.
Structures with exactly one member, which is of type float or double, are
treated exactly as the base types float or double:
struct sf {
float f;
};
struct sd {
double d;
};
are handled the same way as just
float f;
double d;
As a result, arguments of these struct types are pushed into floating point
registers exactly as floats or doubles, using the same decision algorithm.
The same is valid if these types are used as function return types. The
above structs are returned in fr0 resp. fr0,fr1 instead of in r0, r0,r1
or even using struct convention as it is for other structs. */
static int
sh_treat_as_flt_p (struct type *type)
{
/* Ordinary float types are obviously treated as float. */
if (type->code () == TYPE_CODE_FLT)
return 1;
/* Otherwise non-struct types are not treated as float. */
if (type->code () != TYPE_CODE_STRUCT)
return 0;
/* Otherwise structs with more than one member are not treated as float. */
if (type->num_fields () != 1)
return 0;
/* Otherwise if the type of that member is float, the whole type is
treated as float. */
if (TYPE_FIELD_TYPE (type, 0)->code () == TYPE_CODE_FLT)
return 1;
/* Otherwise it's not treated as float. */
return 0;
}
static CORE_ADDR
sh_push_dummy_call_fpu (struct gdbarch *gdbarch,
struct value *function,
struct regcache *regcache,
CORE_ADDR bp_addr, int nargs,
struct value **args,
CORE_ADDR sp, function_call_return_method return_method,
CORE_ADDR struct_addr)
{
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
int stack_offset = 0;
int argreg = ARG0_REGNUM;
int flt_argreg = 0;
int argnum;
struct type *func_type = value_type (function);
struct type *type;
CORE_ADDR regval;
const gdb_byte *val;
int len, reg_size = 0;
int pass_on_stack = 0;
int treat_as_flt;
int last_reg_arg = INT_MAX;
/* The Renesas ABI expects all varargs arguments, plus the last
non-vararg argument to be on the stack, no matter how many
registers have been used so far. */
if (sh_is_renesas_calling_convention (func_type)
&& TYPE_VARARGS (func_type))
last_reg_arg = func_type->num_fields () - 2;
/* First force sp to a 4-byte alignment. */
sp = sh_frame_align (gdbarch, sp);
/* Make room on stack for args. */
sp -= sh_stack_allocsize (nargs, args);
/* Initialize float argument mechanism. */
sh_init_flt_argreg ();
/* 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. */
for (argnum = 0; argnum < nargs; argnum++)
{
type = value_type (args[argnum]);
len = TYPE_LENGTH (type);
val = sh_justify_value_in_reg (gdbarch, args[argnum], len);
/* Some decisions have to be made how various types are handled.
This also differs in different ABIs. */
pass_on_stack = 0;
/* Find out the next register to use for a floating point value. */
treat_as_flt = sh_treat_as_flt_p (type);
if (treat_as_flt)
flt_argreg = sh_next_flt_argreg (gdbarch, len, func_type);
/* In Renesas ABI, long longs and aggregate types are always passed
on stack. */
else if (sh_is_renesas_calling_convention (func_type)
&& ((type->code () == TYPE_CODE_INT && len == 8)
|| type->code () == TYPE_CODE_STRUCT
|| type->code () == TYPE_CODE_UNION))
pass_on_stack = 1;
/* In contrast to non-FPU CPUs, arguments are never split between
registers and stack. If an argument doesn't fit in the remaining
registers it's always pushed entirely on the stack. */
else if (len > ((ARGLAST_REGNUM - argreg + 1) * 4))
pass_on_stack = 1;
while (len > 0)
{
if ((treat_as_flt && flt_argreg > FLOAT_ARGLAST_REGNUM)
|| (!treat_as_flt && (argreg > ARGLAST_REGNUM
|| pass_on_stack))
|| argnum > last_reg_arg)
{
/* The data goes entirely on the stack, 4-byte aligned. */
reg_size = (len + 3) & ~3;
write_memory (sp + stack_offset, val, reg_size);
stack_offset += reg_size;
}
else if (treat_as_flt && flt_argreg <= FLOAT_ARGLAST_REGNUM)
{
/* Argument goes in a float argument register. */
reg_size = register_size (gdbarch, flt_argreg);
regval = extract_unsigned_integer (val, reg_size, byte_order);
/* In little endian mode, float types taking two registers
(doubles on sh4, long doubles on sh2e, sh3e and sh4) must
be stored swapped in the argument registers. The below
code first writes the first 32 bits in the next but one
register, increments the val and len values accordingly
and then proceeds as normal by writing the second 32 bits
into the next register. */
if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_LITTLE
&& TYPE_LENGTH (type) == 2 * reg_size)
{
regcache_cooked_write_unsigned (regcache, flt_argreg + 1,
regval);
val += reg_size;
len -= reg_size;
regval = extract_unsigned_integer (val, reg_size,
byte_order);
}
regcache_cooked_write_unsigned (regcache, flt_argreg++, regval);
}
else if (!treat_as_flt && argreg <= ARGLAST_REGNUM)
{
/* there's room in a register */
reg_size = register_size (gdbarch, argreg);
regval = extract_unsigned_integer (val, reg_size, byte_order);
regcache_cooked_write_unsigned (regcache, argreg++, regval);
}
/* Store the value one register at a time or in one step on
stack. */
len -= reg_size;
val += reg_size;
}
}
if (return_method == return_method_struct)
{
if (sh_is_renesas_calling_convention (func_type))
/* If the function uses the Renesas ABI, subtract another 4 bytes from
the stack and store the struct return address there. */
write_memory_unsigned_integer (sp -= 4, 4, byte_order, struct_addr);
else
/* Using the gcc ABI, the "struct return pointer" pseudo-argument has
its own dedicated register. */
regcache_cooked_write_unsigned (regcache,
STRUCT_RETURN_REGNUM, struct_addr);
}
/* Store return address. */
regcache_cooked_write_unsigned (regcache, PR_REGNUM, bp_addr);
/* Update stack pointer. */
regcache_cooked_write_unsigned (regcache,
gdbarch_sp_regnum (gdbarch), sp);
return sp;
}
static CORE_ADDR
sh_push_dummy_call_nofpu (struct gdbarch *gdbarch,
struct value *function,
struct regcache *regcache,
CORE_ADDR bp_addr,
int nargs, struct value **args,
CORE_ADDR sp,
function_call_return_method return_method,
CORE_ADDR struct_addr)
{
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
int stack_offset = 0;
int argreg = ARG0_REGNUM;
int argnum;
struct type *func_type = value_type (function);
struct type *type;
CORE_ADDR regval;
const gdb_byte *val;
int len, reg_size = 0;
int pass_on_stack = 0;
int last_reg_arg = INT_MAX;
/* The Renesas ABI expects all varargs arguments, plus the last
non-vararg argument to be on the stack, no matter how many
registers have been used so far. */
if (sh_is_renesas_calling_convention (func_type)
&& TYPE_VARARGS (func_type))
last_reg_arg = func_type->num_fields () - 2;
/* First force sp to a 4-byte alignment. */
sp = sh_frame_align (gdbarch, sp);
/* Make room on stack for args. */
sp -= sh_stack_allocsize (nargs, 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. */
for (argnum = 0; argnum < nargs; argnum++)
{
type = value_type (args[argnum]);
len = TYPE_LENGTH (type);
val = sh_justify_value_in_reg (gdbarch, args[argnum], len);
/* Some decisions have to be made how various types are handled.
This also differs in different ABIs. */
pass_on_stack = 0;
/* Renesas ABI pushes doubles and long longs entirely on stack.
Same goes for aggregate types. */
if (sh_is_renesas_calling_convention (func_type)
&& ((type->code () == TYPE_CODE_INT && len >= 8)
|| (type->code () == TYPE_CODE_FLT && len >= 8)
|| type->code () == TYPE_CODE_STRUCT
|| type->code () == TYPE_CODE_UNION))
pass_on_stack = 1;
while (len > 0)
{
if (argreg > ARGLAST_REGNUM || pass_on_stack
|| argnum > last_reg_arg)
{
/* The remainder of the data goes entirely on the stack,
4-byte aligned. */
reg_size = (len + 3) & ~3;
write_memory (sp + stack_offset, val, reg_size);
stack_offset += reg_size;
}
else if (argreg <= ARGLAST_REGNUM)
{
/* There's room in a register. */
reg_size = register_size (gdbarch, argreg);
regval = extract_unsigned_integer (val, reg_size, byte_order);
regcache_cooked_write_unsigned (regcache, argreg++, regval);
}
/* Store the value reg_size bytes at a time. This means that things
larger than reg_size bytes may go partly in registers and partly
on the stack. */
len -= reg_size;
val += reg_size;
}
}
if (return_method == return_method_struct)
{
if (sh_is_renesas_calling_convention (func_type))
/* If the function uses the Renesas ABI, subtract another 4 bytes from
the stack and store the struct return address there. */
write_memory_unsigned_integer (sp -= 4, 4, byte_order, struct_addr);
else
/* Using the gcc ABI, the "struct return pointer" pseudo-argument has
its own dedicated register. */
regcache_cooked_write_unsigned (regcache,
STRUCT_RETURN_REGNUM, struct_addr);
}
/* Store return address. */
regcache_cooked_write_unsigned (regcache, PR_REGNUM, bp_addr);
/* Update stack pointer. */
regcache_cooked_write_unsigned (regcache,
gdbarch_sp_regnum (gdbarch), sp);
return sp;
}
/* Find a function's return value in the appropriate registers (in
regbuf), and copy it into valbuf. Extract from an array REGBUF
containing the (raw) register state a function return value of type
TYPE, and copy that, in virtual format, into VALBUF. */
static void
sh_extract_return_value_nofpu (struct type *type, struct regcache *regcache,
gdb_byte *valbuf)
{
struct gdbarch *gdbarch = regcache->arch ();
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
int len = TYPE_LENGTH (type);
if (len <= 4)
{
ULONGEST c;
regcache_cooked_read_unsigned (regcache, R0_REGNUM, &c);
store_unsigned_integer (valbuf, len, byte_order, c);
}
else if (len == 8)
{
int i, regnum = R0_REGNUM;
for (i = 0; i < len; i += 4)
regcache->raw_read (regnum++, valbuf + i);
}
else
error (_("bad size for return value"));
}
static void
sh_extract_return_value_fpu (struct type *type, struct regcache *regcache,
gdb_byte *valbuf)
{
struct gdbarch *gdbarch = regcache->arch ();
if (sh_treat_as_flt_p (type))
{
int len = TYPE_LENGTH (type);
int i, regnum = gdbarch_fp0_regnum (gdbarch);
for (i = 0; i < len; i += 4)
if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_LITTLE)
regcache->raw_read (regnum++,
valbuf + len - 4 - i);
else
regcache->raw_read (regnum++, valbuf + i);
}
else
sh_extract_return_value_nofpu (type, regcache, valbuf);
}
/* Write into appropriate registers a function return value
of type TYPE, given in virtual format.
If the architecture is sh4 or sh3e, store a function's return value
in the R0 general register or in the FP0 floating point register,
depending on the type of the return value. In all the other cases
the result is stored in r0, left-justified. */
static void
sh_store_return_value_nofpu (struct type *type, struct regcache *regcache,
const gdb_byte *valbuf)
{
struct gdbarch *gdbarch = regcache->arch ();
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
ULONGEST val;
int len = TYPE_LENGTH (type);
if (len <= 4)
{
val = extract_unsigned_integer (valbuf, len, byte_order);
regcache_cooked_write_unsigned (regcache, R0_REGNUM, val);
}
else
{
int i, regnum = R0_REGNUM;
for (i = 0; i < len; i += 4)
regcache->raw_write (regnum++, valbuf + i);
}
}
static void
sh_store_return_value_fpu (struct type *type, struct regcache *regcache,
const gdb_byte *valbuf)
{
struct gdbarch *gdbarch = regcache->arch ();
if (sh_treat_as_flt_p (type))
{
int len = TYPE_LENGTH (type);
int i, regnum = gdbarch_fp0_regnum (gdbarch);
for (i = 0; i < len; i += 4)
if (gdbarch_byte_order (gdbarch) == BFD_ENDIAN_LITTLE)
regcache->raw_write (regnum++,
valbuf + len - 4 - i);
else
regcache->raw_write (regnum++, valbuf + i);
}
else
sh_store_return_value_nofpu (type, regcache, valbuf);
}
static enum return_value_convention
sh_return_value_nofpu (struct gdbarch *gdbarch, struct value *function,
struct type *type, struct regcache *regcache,
gdb_byte *readbuf, const gdb_byte *writebuf)
{
struct type *func_type = function ? value_type (function) : NULL;
if (sh_use_struct_convention_nofpu (
sh_is_renesas_calling_convention (func_type), type))
return RETURN_VALUE_STRUCT_CONVENTION;
if (writebuf)
sh_store_return_value_nofpu (type, regcache, writebuf);
else if (readbuf)
sh_extract_return_value_nofpu (type, regcache, readbuf);
return RETURN_VALUE_REGISTER_CONVENTION;
}
static enum return_value_convention
sh_return_value_fpu (struct gdbarch *gdbarch, struct value *function,
struct type *type, struct regcache *regcache,
gdb_byte *readbuf, const gdb_byte *writebuf)
{
struct type *func_type = function ? value_type (function) : NULL;
if (sh_use_struct_convention (
sh_is_renesas_calling_convention (func_type), type))
return RETURN_VALUE_STRUCT_CONVENTION;
if (writebuf)
sh_store_return_value_fpu (type, regcache, writebuf);
else if (readbuf)
sh_extract_return_value_fpu (type, regcache, readbuf);
return RETURN_VALUE_REGISTER_CONVENTION;
}
static struct type *
sh_sh2a_register_type (struct gdbarch *gdbarch, int reg_nr)
{
if ((reg_nr >= gdbarch_fp0_regnum (gdbarch)
&& (reg_nr <= FP_LAST_REGNUM)) || (reg_nr == FPUL_REGNUM))
return builtin_type (gdbarch)->builtin_float;
else if (reg_nr >= DR0_REGNUM && reg_nr <= DR_LAST_REGNUM)
return builtin_type (gdbarch)->builtin_double;
else
return builtin_type (gdbarch)->builtin_int;
}
/* Return the GDB type object for the "standard" data type
of data in register N. */
static struct type *
sh_sh3e_register_type (struct gdbarch *gdbarch, int reg_nr)
{
if ((reg_nr >= gdbarch_fp0_regnum (gdbarch)
&& (reg_nr <= FP_LAST_REGNUM)) || (reg_nr == FPUL_REGNUM))
return builtin_type (gdbarch)->builtin_float;
else
return builtin_type (gdbarch)->builtin_int;
}
static struct type *
sh_sh4_build_float_register_type (struct gdbarch *gdbarch, int high)
{
return lookup_array_range_type (builtin_type (gdbarch)->builtin_float,
0, high);
}
static struct type *
sh_sh4_register_type (struct gdbarch *gdbarch, int reg_nr)
{
if ((reg_nr >= gdbarch_fp0_regnum (gdbarch)
&& (reg_nr <= FP_LAST_REGNUM)) || (reg_nr == FPUL_REGNUM))
return builtin_type (gdbarch)->builtin_float;
else if (reg_nr >= DR0_REGNUM && reg_nr <= DR_LAST_REGNUM)
return builtin_type (gdbarch)->builtin_double;
else if (reg_nr >= FV0_REGNUM && reg_nr <= FV_LAST_REGNUM)
return sh_sh4_build_float_register_type (gdbarch, 3);
else
return builtin_type (gdbarch)->builtin_int;
}
static struct type *
sh_default_register_type (struct gdbarch *gdbarch, int reg_nr)
{
return builtin_type (gdbarch)->builtin_int;
}
/* Is a register in a reggroup?
The default code in reggroup.c doesn't identify system registers, some
float registers or any of the vector registers.
TODO: sh2a and dsp registers. */
static int
sh_register_reggroup_p (struct gdbarch *gdbarch, int regnum,
struct reggroup *reggroup)
{
if (gdbarch_register_name (gdbarch, regnum) == NULL
|| *gdbarch_register_name (gdbarch, regnum) == '\0')
return 0;
if (reggroup == float_reggroup
&& (regnum == FPUL_REGNUM
|| regnum == FPSCR_REGNUM))
return 1;
if (regnum >= FV0_REGNUM && regnum <= FV_LAST_REGNUM)
{
if (reggroup == vector_reggroup || reggroup == float_reggroup)
return 1;
if (reggroup == general_reggroup)
return 0;
}
if (regnum == VBR_REGNUM
|| regnum == SR_REGNUM
|| regnum == FPSCR_REGNUM
|| regnum == SSR_REGNUM
|| regnum == SPC_REGNUM)
{
if (reggroup == system_reggroup)
return 1;
if (reggroup == general_reggroup)
return 0;
}
/* The default code can cope with any other registers. */
return default_register_reggroup_p (gdbarch, regnum, reggroup);
}
/* On the sh4, the DRi pseudo registers are problematic if the target
is little endian. When the user writes one of those registers, for
instance with 'set var $dr0=1', we want the double to be stored
like this:
fr0 = 0x00 0x00 0xf0 0x3f
fr1 = 0x00 0x00 0x00 0x00
This corresponds to little endian byte order & big endian word
order. However if we let gdb write the register w/o conversion, it
will write fr0 and fr1 this way:
fr0 = 0x00 0x00 0x00 0x00
fr1 = 0x00 0x00 0xf0 0x3f
because it will consider fr0 and fr1 as a single LE stretch of memory.
To achieve what we want we must force gdb to store things in
floatformat_ieee_double_littlebyte_bigword (which is defined in
include/floatformat.h and libiberty/floatformat.c.
In case the target is big endian, there is no problem, the
raw bytes will look like:
fr0 = 0x3f 0xf0 0x00 0x00
fr1 = 0x00 0x00 0x00 0x00
The other pseudo registers (the FVs) also don't pose a problem
because they are stored as 4 individual FP elements. */
static struct type *
sh_littlebyte_bigword_type (struct gdbarch *gdbarch)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
if (tdep->sh_littlebyte_bigword_type == NULL)
tdep->sh_littlebyte_bigword_type
= arch_float_type (gdbarch, -1, "builtin_type_sh_littlebyte_bigword",
floatformats_ieee_double_littlebyte_bigword);
return tdep->sh_littlebyte_bigword_type;
}
static void
sh_register_convert_to_virtual (struct gdbarch *gdbarch, int regnum,
struct type *type, gdb_byte *from, gdb_byte *to)
{
if (gdbarch_byte_order (gdbarch) != BFD_ENDIAN_LITTLE)
{
/* It is a no-op. */
memcpy (to, from, register_size (gdbarch, regnum));
return;
}
if (regnum >= DR0_REGNUM && regnum <= DR_LAST_REGNUM)
target_float_convert (from, sh_littlebyte_bigword_type (gdbarch),
to, type);
else
error
("sh_register_convert_to_virtual called with non DR register number");
}
static void
sh_register_convert_to_raw (struct gdbarch *gdbarch, struct type *type,
int regnum, const gdb_byte *from, gdb_byte *to)
{
if (gdbarch_byte_order (gdbarch) != BFD_ENDIAN_LITTLE)
{
/* It is a no-op. */
memcpy (to, from, register_size (gdbarch, regnum));
return;
}
if (regnum >= DR0_REGNUM && regnum <= DR_LAST_REGNUM)
target_float_convert (from, type,
to, sh_littlebyte_bigword_type (gdbarch));
else
error (_("sh_register_convert_to_raw called with non DR register number"));
}
/* For vectors of 4 floating point registers. */
static int
fv_reg_base_num (struct gdbarch *gdbarch, int fv_regnum)
{
int fp_regnum;
fp_regnum = gdbarch_fp0_regnum (gdbarch)
+ (fv_regnum - FV0_REGNUM) * 4;
return fp_regnum;
}
/* For double precision floating point registers, i.e 2 fp regs. */
static int
dr_reg_base_num (struct gdbarch *gdbarch, int dr_regnum)
{
int fp_regnum;
fp_regnum = gdbarch_fp0_regnum (gdbarch)
+ (dr_regnum - DR0_REGNUM) * 2;
return fp_regnum;
}
/* Concatenate PORTIONS contiguous raw registers starting at
BASE_REGNUM into BUFFER. */
static enum register_status
pseudo_register_read_portions (struct gdbarch *gdbarch,
readable_regcache *regcache,
int portions,
int base_regnum, gdb_byte *buffer)
{
int portion;
for (portion = 0; portion < portions; portion++)
{
enum register_status status;
gdb_byte *b;
b = buffer + register_size (gdbarch, base_regnum) * portion;
status = regcache->raw_read (base_regnum + portion, b);
if (status != REG_VALID)
return status;
}
return REG_VALID;
}
static enum register_status
sh_pseudo_register_read (struct gdbarch *gdbarch, readable_regcache *regcache,
int reg_nr, gdb_byte *buffer)
{
int base_regnum;
enum register_status status;
if (reg_nr == PSEUDO_BANK_REGNUM)
return regcache->raw_read (BANK_REGNUM, buffer);
else if (reg_nr >= DR0_REGNUM && reg_nr <= DR_LAST_REGNUM)
{
/* Enough space for two float registers. */
gdb_byte temp_buffer[4 * 2];
base_regnum = dr_reg_base_num (gdbarch, reg_nr);
/* Build the value in the provided buffer. */
/* Read the real regs for which this one is an alias. */
status = pseudo_register_read_portions (gdbarch, regcache,
2, base_regnum, temp_buffer);
if (status == REG_VALID)
{
/* We must pay attention to the endianness. */
sh_register_convert_to_virtual (gdbarch, reg_nr,
register_type (gdbarch, reg_nr),
temp_buffer, buffer);
}
return status;
}
else if (reg_nr >= FV0_REGNUM && reg_nr <= FV_LAST_REGNUM)
{
base_regnum = fv_reg_base_num (gdbarch, reg_nr);
/* Read the real regs for which this one is an alias. */
return pseudo_register_read_portions (gdbarch, regcache,
4, base_regnum, buffer);
}
else
gdb_assert_not_reached ("invalid pseudo register number");
}
static void
sh_pseudo_register_write (struct gdbarch *gdbarch, struct regcache *regcache,
int reg_nr, const gdb_byte *buffer)
{
int base_regnum, portion;
if (reg_nr == PSEUDO_BANK_REGNUM)
{
/* When the bank register is written to, the whole register bank
is switched and all values in the bank registers must be read
from the target/sim again. We're just invalidating the regcache
so that a re-read happens next time it's necessary. */
int bregnum;
regcache->raw_write (BANK_REGNUM, buffer);
for (bregnum = R0_BANK0_REGNUM; bregnum < MACLB_REGNUM; ++bregnum)
regcache->invalidate (bregnum);
}
else if (reg_nr >= DR0_REGNUM && reg_nr <= DR_LAST_REGNUM)
{
/* Enough space for two float registers. */
gdb_byte temp_buffer[4 * 2];
base_regnum = dr_reg_base_num (gdbarch, reg_nr);
/* We must pay attention to the endianness. */
sh_register_convert_to_raw (gdbarch, register_type (gdbarch, reg_nr),
reg_nr, buffer, temp_buffer);
/* Write the real regs for which this one is an alias. */
for (portion = 0; portion < 2; portion++)
regcache->raw_write (base_regnum + portion,
(temp_buffer
+ register_size (gdbarch,
base_regnum) * portion));
}
else if (reg_nr >= FV0_REGNUM && reg_nr <= FV_LAST_REGNUM)
{
base_regnum = fv_reg_base_num (gdbarch, reg_nr);
/* Write the real regs for which this one is an alias. */
for (portion = 0; portion < 4; portion++)
regcache->raw_write (base_regnum + portion,
(buffer
+ register_size (gdbarch,
base_regnum) * portion));
}
}
static int
sh_dsp_register_sim_regno (struct gdbarch *gdbarch, int nr)
{
if (legacy_register_sim_regno (gdbarch, nr) < 0)
return legacy_register_sim_regno (gdbarch, nr);
if (nr >= DSR_REGNUM && nr <= Y1_REGNUM)
return nr - DSR_REGNUM + SIM_SH_DSR_REGNUM;
if (nr == MOD_REGNUM)
return SIM_SH_MOD_REGNUM;
if (nr == RS_REGNUM)
return SIM_SH_RS_REGNUM;
if (nr == RE_REGNUM)
return SIM_SH_RE_REGNUM;
if (nr >= DSP_R0_BANK_REGNUM && nr <= DSP_R7_BANK_REGNUM)
return nr - DSP_R0_BANK_REGNUM + SIM_SH_R0_BANK_REGNUM;
return nr;
}
static int
sh_sh2a_register_sim_regno (struct gdbarch *gdbarch, int nr)
{
switch (nr)
{
case TBR_REGNUM:
return SIM_SH_TBR_REGNUM;
case IBNR_REGNUM:
return SIM_SH_IBNR_REGNUM;
case IBCR_REGNUM:
return SIM_SH_IBCR_REGNUM;
case BANK_REGNUM:
return SIM_SH_BANK_REGNUM;
case MACLB_REGNUM:
return SIM_SH_BANK_MACL_REGNUM;
case GBRB_REGNUM:
return SIM_SH_BANK_GBR_REGNUM;
case PRB_REGNUM:
return SIM_SH_BANK_PR_REGNUM;
case IVNB_REGNUM:
return SIM_SH_BANK_IVN_REGNUM;
case MACHB_REGNUM:
return SIM_SH_BANK_MACH_REGNUM;
default:
break;
}
return legacy_register_sim_regno (gdbarch, nr);
}
/* Set up the register unwinding such that call-clobbered registers are
not displayed in frames >0 because the true value is not certain.
The 'undefined' registers will show up as 'not available' unless the
CFI says otherwise.
This function is currently set up for SH4 and compatible only. */
static void
sh_dwarf2_frame_init_reg (struct gdbarch *gdbarch, int regnum,
struct dwarf2_frame_state_reg *reg,
struct frame_info *this_frame)
{
/* Mark the PC as the destination for the return address. */
if (regnum == gdbarch_pc_regnum (gdbarch))
reg->how = DWARF2_FRAME_REG_RA;
/* Mark the stack pointer as the call frame address. */
else if (regnum == gdbarch_sp_regnum (gdbarch))
reg->how = DWARF2_FRAME_REG_CFA;
/* The above was taken from the default init_reg in dwarf2-frame.c
while the below is SH specific. */
/* Caller save registers. */
else if ((regnum >= R0_REGNUM && regnum <= R0_REGNUM+7)
|| (regnum >= FR0_REGNUM && regnum <= FR0_REGNUM+11)
|| (regnum >= DR0_REGNUM && regnum <= DR0_REGNUM+5)
|| (regnum >= FV0_REGNUM && regnum <= FV0_REGNUM+2)
|| (regnum == MACH_REGNUM)
|| (regnum == MACL_REGNUM)
|| (regnum == FPUL_REGNUM)
|| (regnum == SR_REGNUM))
reg->how = DWARF2_FRAME_REG_UNDEFINED;
/* Callee save registers. */
else if ((regnum >= R0_REGNUM+8 && regnum <= R0_REGNUM+15)
|| (regnum >= FR0_REGNUM+12 && regnum <= FR0_REGNUM+15)
|| (regnum >= DR0_REGNUM+6 && regnum <= DR0_REGNUM+8)
|| (regnum == FV0_REGNUM+3))
reg->how = DWARF2_FRAME_REG_SAME_VALUE;
/* Other registers. These are not in the ABI and may or may not
mean anything in frames >0 so don't show them. */
else if ((regnum >= R0_BANK0_REGNUM && regnum <= R0_BANK0_REGNUM+15)
|| (regnum == GBR_REGNUM)
|| (regnum == VBR_REGNUM)
|| (regnum == FPSCR_REGNUM)
|| (regnum == SSR_REGNUM)
|| (regnum == SPC_REGNUM))
reg->how = DWARF2_FRAME_REG_UNDEFINED;
}
static struct sh_frame_cache *
sh_alloc_frame_cache (void)
{
struct sh_frame_cache *cache;
int i;
cache = FRAME_OBSTACK_ZALLOC (struct sh_frame_cache);
/* Base address. */
cache->base = 0;
cache->saved_sp = 0;
cache->sp_offset = 0;
cache->pc = 0;
/* Frameless until proven otherwise. */
cache->uses_fp = 0;
/* Saved registers. We initialize these to -1 since zero is a valid
offset (that's where fp is supposed to be stored). */
for (i = 0; i < SH_NUM_REGS; i++)
{
cache->saved_regs[i] = -1;
}
return cache;
}
static struct sh_frame_cache *
sh_frame_cache (struct frame_info *this_frame, void **this_cache)
{
struct gdbarch *gdbarch = get_frame_arch (this_frame);
struct sh_frame_cache *cache;
CORE_ADDR current_pc;
int i;
if (*this_cache)
return (struct sh_frame_cache *) *this_cache;
cache = sh_alloc_frame_cache ();
*this_cache = cache;
/* In principle, for normal frames, fp holds the frame pointer,
which holds the base address for the current stack frame.
However, for functions that don't need it, the frame pointer is
optional. For these "frameless" functions the frame pointer is
actually the frame pointer of the calling frame. */
cache->base = get_frame_register_unsigned (this_frame, FP_REGNUM);
if (cache->base == 0)
return cache;
cache->pc = get_frame_func (this_frame);
current_pc = get_frame_pc (this_frame);
if (cache->pc != 0)
{
ULONGEST fpscr;
/* Check for the existence of the FPSCR register. If it exists,
fetch its value for use in prologue analysis. Passing a zero
value is the best choice for architecture variants upon which
there's no FPSCR register. */
if (gdbarch_register_reggroup_p (gdbarch, FPSCR_REGNUM, all_reggroup))
fpscr = get_frame_register_unsigned (this_frame, FPSCR_REGNUM);
else
fpscr = 0;
sh_analyze_prologue (gdbarch, cache->pc, current_pc, cache, fpscr);
}
if (!cache->uses_fp)
{
/* We didn't find a valid frame, which means that CACHE->base
currently holds the frame pointer for our calling frame. If
we're at the start of a function, or somewhere half-way its
prologue, the function's frame probably hasn't been fully
setup yet. Try to reconstruct the base address for the stack
frame by looking at the stack pointer. For truly "frameless"
functions this might work too. */
cache->base = get_frame_register_unsigned
(this_frame, gdbarch_sp_regnum (gdbarch));
}
/* Now that we have the base address for the stack frame we can
calculate the value of sp in the calling frame. */
cache->saved_sp = cache->base + cache->sp_offset;
/* Adjust all the saved registers such that they contain addresses
instead of offsets. */
for (i = 0; i < SH_NUM_REGS; i++)
if (cache->saved_regs[i] != -1)
cache->saved_regs[i] = cache->saved_sp - cache->saved_regs[i] - 4;
return cache;
}
static struct value *
sh_frame_prev_register (struct frame_info *this_frame,
void **this_cache, int regnum)
{
struct gdbarch *gdbarch = get_frame_arch (this_frame);
struct sh_frame_cache *cache = sh_frame_cache (this_frame, this_cache);
gdb_assert (regnum >= 0);
if (regnum == gdbarch_sp_regnum (gdbarch) && cache->saved_sp)
return frame_unwind_got_constant (this_frame, regnum, cache->saved_sp);
/* The PC of the previous frame is stored in the PR register of
the current frame. Frob regnum so that we pull the value from
the correct place. */
if (regnum == gdbarch_pc_regnum (gdbarch))
regnum = PR_REGNUM;
if (regnum < SH_NUM_REGS && cache->saved_regs[regnum] != -1)
return frame_unwind_got_memory (this_frame, regnum,
cache->saved_regs[regnum]);
return frame_unwind_got_register (this_frame, regnum, regnum);
}
static void
sh_frame_this_id (struct frame_info *this_frame, void **this_cache,
struct frame_id *this_id)
{
struct sh_frame_cache *cache = sh_frame_cache (this_frame, this_cache);
/* This marks the outermost frame. */
if (cache->base == 0)
return;
*this_id = frame_id_build (cache->saved_sp, cache->pc);
}
static const struct frame_unwind sh_frame_unwind = {
NORMAL_FRAME,
default_frame_unwind_stop_reason,
sh_frame_this_id,
sh_frame_prev_register,
NULL,
default_frame_sniffer
};
static CORE_ADDR
sh_frame_base_address (struct frame_info *this_frame, void **this_cache)
{
struct sh_frame_cache *cache = sh_frame_cache (this_frame, this_cache);
return cache->base;
}
static const struct frame_base sh_frame_base = {
&sh_frame_unwind,
sh_frame_base_address,
sh_frame_base_address,
sh_frame_base_address
};
static struct sh_frame_cache *
sh_make_stub_cache (struct frame_info *this_frame)
{
struct gdbarch *gdbarch = get_frame_arch (this_frame);
struct sh_frame_cache *cache;
cache = sh_alloc_frame_cache ();
cache->saved_sp
= get_frame_register_unsigned (this_frame, gdbarch_sp_regnum (gdbarch));
return cache;
}
static void
sh_stub_this_id (struct frame_info *this_frame, void **this_cache,
struct frame_id *this_id)
{
struct sh_frame_cache *cache;
if (*this_cache == NULL)
*this_cache = sh_make_stub_cache (this_frame);
cache = (struct sh_frame_cache *) *this_cache;
*this_id = frame_id_build (cache->saved_sp, get_frame_pc (this_frame));
}
static int
sh_stub_unwind_sniffer (const struct frame_unwind *self,
struct frame_info *this_frame,
void **this_prologue_cache)
{
CORE_ADDR addr_in_block;
addr_in_block = get_frame_address_in_block (this_frame);
if (in_plt_section (addr_in_block))
return 1;
return 0;
}
static const struct frame_unwind sh_stub_unwind =
{
NORMAL_FRAME,
default_frame_unwind_stop_reason,
sh_stub_this_id,
sh_frame_prev_register,
NULL,
sh_stub_unwind_sniffer
};
/* Implement the stack_frame_destroyed_p gdbarch method.
The epilogue is defined here as the area at the end of a function,
either on the `ret' instruction itself or after an instruction which
destroys the function's stack frame. */
static int
sh_stack_frame_destroyed_p (struct gdbarch *gdbarch, CORE_ADDR pc)
{
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
CORE_ADDR func_addr = 0, func_end = 0;
if (find_pc_partial_function (pc, NULL, &func_addr, &func_end))
{
ULONGEST inst;
/* The sh epilogue is max. 14 bytes long. Give another 14 bytes
for a nop and some fixed data (e.g. big offsets) which are
unfortunately also treated as part of the function (which
means, they are below func_end. */
CORE_ADDR addr = func_end - 28;
if (addr < func_addr + 4)
addr = func_addr + 4;
if (pc < addr)
return 0;
/* First search forward until hitting an rts. */
while (addr < func_end
&& !IS_RTS (read_memory_unsigned_integer (addr, 2, byte_order)))
addr += 2;
if (addr >= func_end)
return 0;
/* At this point we should find a mov.l @r15+,r14 instruction,
either before or after the rts. If not, then the function has
probably no "normal" epilogue and we bail out here. */
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
if (IS_RESTORE_FP (read_memory_unsigned_integer (addr - 2, 2,
byte_order)))
addr -= 2;
else if (!IS_RESTORE_FP (read_memory_unsigned_integer (addr + 2, 2,
byte_order)))
return 0;
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
/* Step over possible lds.l @r15+,macl. */
if (IS_MACL_LDS (inst))
{
addr -= 2;
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
}
/* Step over possible lds.l @r15+,pr. */
if (IS_LDS (inst))
{
addr -= 2;
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
}
/* Step over possible mov r14,r15. */
if (IS_MOV_FP_SP (inst))
{
addr -= 2;
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
}
/* Now check for FP adjustments, using add #imm,r14 or add rX, r14
instructions. */
while (addr > func_addr + 4
&& (IS_ADD_REG_TO_FP (inst) || IS_ADD_IMM_FP (inst)))
{
addr -= 2;
inst = read_memory_unsigned_integer (addr - 2, 2, byte_order);
}
/* On SH2a check if the previous instruction was perhaps a MOVI20.
That's allowed for the epilogue. */
if ((gdbarch_bfd_arch_info (gdbarch)->mach == bfd_mach_sh2a
|| gdbarch_bfd_arch_info (gdbarch)->mach == bfd_mach_sh2a_nofpu)
&& addr > func_addr + 6
&& IS_MOVI20 (read_memory_unsigned_integer (addr - 4, 2,
byte_order)))
addr -= 4;
if (pc >= addr)
return 1;
}
return 0;
}
/* Supply register REGNUM from the buffer specified by REGS and LEN
in the register set REGSET to register cache REGCACHE.
REGTABLE specifies where each register can be found in REGS.
If REGNUM is -1, do this for all registers in REGSET. */
void
sh_corefile_supply_regset (const struct regset *regset,
struct regcache *regcache,
int regnum, const void *regs, size_t len)
{
struct gdbarch *gdbarch = regcache->arch ();
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
const struct sh_corefile_regmap *regmap = (regset == &sh_corefile_gregset
? tdep->core_gregmap
: tdep->core_fpregmap);
int i;
for (i = 0; regmap[i].regnum != -1; i++)
{
if ((regnum == -1 || regnum == regmap[i].regnum)
&& regmap[i].offset + 4 <= len)
regcache->raw_supply
(regmap[i].regnum, (char *) regs + regmap[i].offset);
}
}
/* Collect register REGNUM in the register set REGSET from register cache
REGCACHE into the buffer specified by REGS and LEN.
REGTABLE specifies where each register can be found in REGS.
If REGNUM is -1, do this for all registers in REGSET. */
void
sh_corefile_collect_regset (const struct regset *regset,
const struct regcache *regcache,
int regnum, void *regs, size_t len)
{
struct gdbarch *gdbarch = regcache->arch ();
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
const struct sh_corefile_regmap *regmap = (regset == &sh_corefile_gregset
? tdep->core_gregmap
: tdep->core_fpregmap);
int i;
for (i = 0; regmap[i].regnum != -1; i++)
{
if ((regnum == -1 || regnum == regmap[i].regnum)
&& regmap[i].offset + 4 <= len)
regcache->raw_collect (regmap[i].regnum,
(char *)regs + regmap[i].offset);
}
}
/* The following two regsets have the same contents, so it is tempting to
unify them, but they are distiguished by their address, so don't. */
const struct regset sh_corefile_gregset =
{
NULL,
sh_corefile_supply_regset,
sh_corefile_collect_regset
};
static const struct regset sh_corefile_fpregset =
{
NULL,
sh_corefile_supply_regset,
sh_corefile_collect_regset
};
static void
sh_iterate_over_regset_sections (struct gdbarch *gdbarch,
iterate_over_regset_sections_cb *cb,
void *cb_data,
const struct regcache *regcache)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
if (tdep->core_gregmap != NULL)
cb (".reg", tdep->sizeof_gregset, tdep->sizeof_gregset,
&sh_corefile_gregset, NULL, cb_data);
if (tdep->core_fpregmap != NULL)
cb (".reg2", tdep->sizeof_fpregset, tdep->sizeof_fpregset,
&sh_corefile_fpregset, NULL, cb_data);
}
/* This is the implementation of gdbarch method
return_in_first_hidden_param_p. */
static int
sh_return_in_first_hidden_param_p (struct gdbarch *gdbarch,
struct type *type)
{
return 0;
}
static struct gdbarch *
sh_gdbarch_init (struct gdbarch_info info, struct gdbarch_list *arches)
{
struct gdbarch *gdbarch;
struct gdbarch_tdep *tdep;
/* If there is already a candidate, use it. */
arches = gdbarch_list_lookup_by_info (arches, &info);
if (arches != NULL)
return arches->gdbarch;
/* None found, create a new architecture from the information
provided. */
tdep = XCNEW (struct gdbarch_tdep);
gdbarch = gdbarch_alloc (&info, tdep);
set_gdbarch_short_bit (gdbarch, 2 * TARGET_CHAR_BIT);
set_gdbarch_int_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_long_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_long_long_bit (gdbarch, 8 * TARGET_CHAR_BIT);
set_gdbarch_wchar_bit (gdbarch, 2 * TARGET_CHAR_BIT);
set_gdbarch_wchar_signed (gdbarch, 0);
set_gdbarch_float_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_double_bit (gdbarch, 8 * TARGET_CHAR_BIT);
set_gdbarch_long_double_bit (gdbarch, 8 * TARGET_CHAR_BIT);
set_gdbarch_ptr_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_num_regs (gdbarch, SH_NUM_REGS);
set_gdbarch_sp_regnum (gdbarch, 15);
set_gdbarch_pc_regnum (gdbarch, 16);
set_gdbarch_fp0_regnum (gdbarch, -1);
set_gdbarch_num_pseudo_regs (gdbarch, 0);
set_gdbarch_register_type (gdbarch, sh_default_register_type);
set_gdbarch_register_reggroup_p (gdbarch, sh_register_reggroup_p);
set_gdbarch_breakpoint_kind_from_pc (gdbarch, sh_breakpoint_kind_from_pc);
set_gdbarch_sw_breakpoint_from_kind (gdbarch, sh_sw_breakpoint_from_kind);
set_gdbarch_register_sim_regno (gdbarch, legacy_register_sim_regno);
set_gdbarch_return_value (gdbarch, sh_return_value_nofpu);
set_gdbarch_skip_prologue (gdbarch, sh_skip_prologue);
set_gdbarch_inner_than (gdbarch, core_addr_lessthan);
set_gdbarch_push_dummy_call (gdbarch, sh_push_dummy_call_nofpu);
set_gdbarch_return_in_first_hidden_param_p (gdbarch,
sh_return_in_first_hidden_param_p);
set_gdbarch_believe_pcc_promotion (gdbarch, 1);
set_gdbarch_frame_align (gdbarch, sh_frame_align);
frame_base_set_default (gdbarch, &sh_frame_base);
set_gdbarch_stack_frame_destroyed_p (gdbarch, sh_stack_frame_destroyed_p);
dwarf2_frame_set_init_reg (gdbarch, sh_dwarf2_frame_init_reg);
set_gdbarch_iterate_over_regset_sections
(gdbarch, sh_iterate_over_regset_sections);
switch (info.bfd_arch_info->mach)
{
case bfd_mach_sh:
set_gdbarch_register_name (gdbarch, sh_sh_register_name);
break;
case bfd_mach_sh2:
set_gdbarch_register_name (gdbarch, sh_sh_register_name);
break;
case bfd_mach_sh2e:
/* doubles on sh2e and sh3e are actually 4 byte. */
set_gdbarch_double_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_double_format (gdbarch, floatformats_ieee_single);
set_gdbarch_register_name (gdbarch, sh_sh2e_register_name);
set_gdbarch_register_type (gdbarch, sh_sh3e_register_type);
set_gdbarch_fp0_regnum (gdbarch, 25);
set_gdbarch_return_value (gdbarch, sh_return_value_fpu);
set_gdbarch_push_dummy_call (gdbarch, sh_push_dummy_call_fpu);
break;
case bfd_mach_sh2a:
set_gdbarch_register_name (gdbarch, sh_sh2a_register_name);
set_gdbarch_register_type (gdbarch, sh_sh2a_register_type);
set_gdbarch_register_sim_regno (gdbarch, sh_sh2a_register_sim_regno);
set_gdbarch_fp0_regnum (gdbarch, 25);
set_gdbarch_num_pseudo_regs (gdbarch, 9);
set_gdbarch_pseudo_register_read (gdbarch, sh_pseudo_register_read);
set_gdbarch_pseudo_register_write (gdbarch, sh_pseudo_register_write);
set_gdbarch_return_value (gdbarch, sh_return_value_fpu);
set_gdbarch_push_dummy_call (gdbarch, sh_push_dummy_call_fpu);
break;
case bfd_mach_sh2a_nofpu:
set_gdbarch_register_name (gdbarch, sh_sh2a_nofpu_register_name);
set_gdbarch_register_sim_regno (gdbarch, sh_sh2a_register_sim_regno);
set_gdbarch_num_pseudo_regs (gdbarch, 1);
set_gdbarch_pseudo_register_read (gdbarch, sh_pseudo_register_read);
set_gdbarch_pseudo_register_write (gdbarch, sh_pseudo_register_write);
break;
case bfd_mach_sh_dsp:
set_gdbarch_register_name (gdbarch, sh_sh_dsp_register_name);
set_gdbarch_register_sim_regno (gdbarch, sh_dsp_register_sim_regno);
break;
case bfd_mach_sh3:
case bfd_mach_sh3_nommu:
case bfd_mach_sh2a_nofpu_or_sh3_nommu:
set_gdbarch_register_name (gdbarch, sh_sh3_register_name);
break;
case bfd_mach_sh3e:
case bfd_mach_sh2a_or_sh3e:
/* doubles on sh2e and sh3e are actually 4 byte. */
set_gdbarch_double_bit (gdbarch, 4 * TARGET_CHAR_BIT);
set_gdbarch_double_format (gdbarch, floatformats_ieee_single);
set_gdbarch_register_name (gdbarch, sh_sh3e_register_name);
set_gdbarch_register_type (gdbarch, sh_sh3e_register_type);
set_gdbarch_fp0_regnum (gdbarch, 25);
set_gdbarch_return_value (gdbarch, sh_return_value_fpu);
set_gdbarch_push_dummy_call (gdbarch, sh_push_dummy_call_fpu);
break;
case bfd_mach_sh3_dsp:
set_gdbarch_register_name (gdbarch, sh_sh3_dsp_register_name);
set_gdbarch_register_sim_regno (gdbarch, sh_dsp_register_sim_regno);
break;
case bfd_mach_sh4:
case bfd_mach_sh4a:
case bfd_mach_sh2a_or_sh4:
set_gdbarch_register_name (gdbarch, sh_sh4_register_name);
set_gdbarch_register_type (gdbarch, sh_sh4_register_type);
set_gdbarch_fp0_regnum (gdbarch, 25);
set_gdbarch_num_pseudo_regs (gdbarch, 13);
set_gdbarch_pseudo_register_read (gdbarch, sh_pseudo_register_read);
set_gdbarch_pseudo_register_write (gdbarch, sh_pseudo_register_write);
set_gdbarch_return_value (gdbarch, sh_return_value_fpu);
set_gdbarch_push_dummy_call (gdbarch, sh_push_dummy_call_fpu);
break;
case bfd_mach_sh4_nofpu:
case bfd_mach_sh4a_nofpu:
case bfd_mach_sh4_nommu_nofpu:
case bfd_mach_sh2a_nofpu_or_sh4_nommu_nofpu:
set_gdbarch_register_name (gdbarch, sh_sh4_nofpu_register_name);
break;
case bfd_mach_sh4al_dsp:
set_gdbarch_register_name (gdbarch, sh_sh4al_dsp_register_name);
set_gdbarch_register_sim_regno (gdbarch, sh_dsp_register_sim_regno);
break;
default:
set_gdbarch_register_name (gdbarch, sh_sh_register_name);
break;
}
/* Hook in ABI-specific overrides, if they have been registered. */
gdbarch_init_osabi (info, gdbarch);
dwarf2_append_unwinders (gdbarch);
frame_unwind_append_unwinder (gdbarch, &sh_stub_unwind);
frame_unwind_append_unwinder (gdbarch, &sh_frame_unwind);
return gdbarch;
}
void _initialize_sh_tdep ();
void
_initialize_sh_tdep ()
{
gdbarch_register (bfd_arch_sh, sh_gdbarch_init, NULL);
add_basic_prefix_cmd ("sh", no_class, "SH specific commands.",
&setshcmdlist, "set sh ", 0, &setlist);
add_show_prefix_cmd ("sh", no_class, "SH specific commands.",
&showshcmdlist, "show sh ", 0, &showlist);
add_setshow_enum_cmd ("calling-convention", class_vars, sh_cc_enum,
&sh_active_calling_convention,
_("Set calling convention used when calling target "
"functions from GDB."),
_("Show calling convention used when calling target "
"functions from GDB."),
_("gcc - Use GCC calling convention (default).\n"
"renesas - Enforce Renesas calling convention."),
NULL, NULL,
&setshcmdlist, &showshcmdlist);
}