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NetBSD/sys/arch/m68k/fpe/fpu_calcea.c

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/* $NetBSD: fpu_calcea.c,v 1.24 2011/05/25 15:47:19 tsutsui Exp $ */
/*
* Copyright (c) 1995 Gordon W. Ross
* portion Copyright (c) 1995 Ken Nakata
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
* 4. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by Gordon Ross
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "opt_m68k_arch.h"
#include <sys/cdefs.h>
__KERNEL_RCSID(0, "$NetBSD: fpu_calcea.c,v 1.24 2011/05/25 15:47:19 tsutsui Exp $");
#include <sys/param.h>
#include <sys/signal.h>
#include <sys/systm.h>
#include <machine/frame.h>
#include <m68k/m68k.h>
#include "fpu_emulate.h"
#ifdef DEBUG_FPE
#define DPRINTF(x) printf x
#else
#define DPRINTF(x) do {} while (/* CONSTCOND */ 0)
#endif
/*
* Prototypes of static functions
*/
static int decode_ea6(struct frame *, struct instruction *,
struct insn_ea *, int);
static int fetch_immed(struct frame *, struct instruction *, int *);
static int fetch_disp(struct frame *, struct instruction *, int, int *);
static int calc_ea(struct insn_ea *, char *, char **);
/*
* Helper routines for dealing with "effective address" values.
*/
/*
* Decode an effective address into internal form.
* Returns zero on success, else signal number.
*/
int
fpu_decode_ea(struct frame *frame, struct instruction *insn,
struct insn_ea *ea, int modreg)
{
int sig;
#ifdef DIAGNOSTIC
if (insn->is_datasize < 0)
panic("%s: called with uninitialized datasize", __func__);
#endif
sig = 0;
/* Set the most common value here. */
ea->ea_regnum = 8 + (modreg & 7);
if ((modreg & 060) == 0) {
/* register direct */
ea->ea_regnum = modreg & 0xf;
ea->ea_flags = EA_DIRECT;
DPRINTF(("%s: register direct reg=%d\n",
__func__, ea->ea_regnum));
} else if ((modreg & 077) == 074) {
/* immediate */
ea->ea_flags = EA_IMMED;
sig = fetch_immed(frame, insn, &ea->ea_immed[0]);
DPRINTF(("%s: immediate size=%d\n",
__func__, insn->is_datasize));
}
/*
* rest of the address modes need to be separately
* handled for the LC040 and the others.
*/
#if 0 /* XXX */
else if (frame->f_format == 4 && frame->f_fmt4.f_fa) {
/* LC040 */
ea->ea_flags = EA_FRAME_EA;
ea->ea_fea = frame->f_fmt4.f_fa;
DPRINTF(("%s: 68LC040 - in-frame EA (%p) size %d\n",
__func__, (void *)ea->ea_fea, insn->is_datasize));
if ((modreg & 070) == 030) {
/* postincrement mode */
ea->ea_flags |= EA_POSTINCR;
} else if ((modreg & 070) == 040) {
/* predecrement mode */
ea->ea_flags |= EA_PREDECR;
#ifdef M68060
#if defined(M68020) || defined(M68030) || defined(M68040)
if (cputype == CPU_68060)
#endif
if (insn->is_datasize == 12)
ea->ea_fea -= 8;
#endif
}
}
#endif /* XXX */
else {
/* 020/030 */
switch (modreg & 070) {
case 020: /* (An) */
ea->ea_flags = 0;
DPRINTF(("%s: register indirect reg=%d\n",
__func__, ea->ea_regnum));
break;
case 030: /* (An)+ */
ea->ea_flags = EA_POSTINCR;
DPRINTF(("%s: reg indirect postincrement reg=%d\n",
__func__, ea->ea_regnum));
break;
case 040: /* -(An) */
ea->ea_flags = EA_PREDECR;
DPRINTF(("%s: reg indirect predecrement reg=%d\n",
__func__, ea->ea_regnum));
break;
case 050: /* (d16,An) */
ea->ea_flags = EA_OFFSET;
sig = fetch_disp(frame, insn, 1, &ea->ea_offset);
DPRINTF(("%s: reg indirect with displacement reg=%d\n",
__func__, ea->ea_regnum));
break;
case 060: /* (d8,An,Xn) */
ea->ea_flags = EA_INDEXED;
sig = decode_ea6(frame, insn, ea, modreg);
break;
case 070: /* misc. */
ea->ea_regnum = (modreg & 7);
switch (modreg & 7) {
case 0: /* (xxxx).W */
ea->ea_flags = EA_ABS;
sig = fetch_disp(frame, insn, 1,
&ea->ea_absaddr);
DPRINTF(("%s: absolute address (word)\n",
__func__));
break;
case 1: /* (xxxxxxxx).L */
ea->ea_flags = EA_ABS;
sig = fetch_disp(frame, insn, 2,
&ea->ea_absaddr);
DPRINTF(("%s: absolute address (long)\n",
__func__));
break;
case 2: /* (d16,PC) */
ea->ea_flags = EA_PC_REL | EA_OFFSET;
sig = fetch_disp(frame, insn, 1,
&ea->ea_absaddr);
DPRINTF(("%s: pc relative word displacement\n",
__func__));
break;
case 3: /* (d8,PC,Xn) */
ea->ea_flags = EA_PC_REL | EA_INDEXED;
sig = decode_ea6(frame, insn, ea, modreg);
break;
case 4: /* #data */
/* it should have been taken care of earlier */
default:
DPRINTF(("%s: invalid addr mode (7,%d)\n",
__func__, modreg & 7));
return SIGILL;
}
break;
}
}
ea->ea_moffs = 0;
return sig;
}
/*
* Decode Mode=6 address modes
*/
static int
decode_ea6(struct frame *frame, struct instruction *insn, struct insn_ea *ea,
int modreg)
{
int extword, idx;
int basedisp, outerdisp;
int bd_size, od_size;
int sig;
extword = fusword((void *)(insn->is_pc + insn->is_advance));
if (extword < 0) {
return SIGSEGV;
}
insn->is_advance += 2;
/* get register index */
ea->ea_idxreg = (extword >> 12) & 0xf;
idx = frame->f_regs[ea->ea_idxreg];
if ((extword & 0x0800) == 0) {
/* if word sized index, sign-extend */
idx &= 0xffff;
if (idx & 0x8000) {
idx |= 0xffff0000;
}
}
/* scale register index */
idx <<= ((extword >> 9) & 3);
if ((extword & 0x100) == 0) {
/* brief extension word - sign-extend the displacement */
basedisp = (extword & 0xff);
if (basedisp & 0x80) {
basedisp |= 0xffffff00;
}
ea->ea_basedisp = idx + basedisp;
ea->ea_outerdisp = 0;
DPRINTF(("%s: brief ext word idxreg=%d, basedisp=%08x\n",
__func__, ea->ea_idxreg, ea->ea_basedisp));
} else {
/* full extension word */
if (extword & 0x80) {
ea->ea_flags |= EA_BASE_SUPPRSS;
}
bd_size = ((extword >> 4) & 3) - 1;
od_size = (extword & 3) - 1;
sig = fetch_disp(frame, insn, bd_size, &basedisp);
if (sig)
return sig;
if (od_size >= 0)
ea->ea_flags |= EA_MEM_INDIR;
sig = fetch_disp(frame, insn, od_size, &outerdisp);
if (sig)
return sig;
switch (extword & 0x44) {
case 0: /* preindexed */
ea->ea_basedisp = basedisp + idx;
ea->ea_outerdisp = outerdisp;
break;
case 4: /* postindexed */
ea->ea_basedisp = basedisp;
ea->ea_outerdisp = outerdisp + idx;
break;
case 0x40: /* no index */
ea->ea_basedisp = basedisp;
ea->ea_outerdisp = outerdisp;
break;
default:
DPRINTF(("%s: invalid indirect mode: ext word %04x\n",
__func__, extword));
return SIGILL;
break;
}
DPRINTF(("%s: full ext idxreg=%d, basedisp=%x, outerdisp=%x\n",
__func__,
ea->ea_idxreg, ea->ea_basedisp, ea->ea_outerdisp));
}
DPRINTF(("%s: regnum=%d, flags=%x\n",
__func__, ea->ea_regnum, ea->ea_flags));
return 0;
}
/*
* Load a value from an effective address.
* Returns zero on success, else signal number.
*/
int
fpu_load_ea(struct frame *frame, struct instruction *insn, struct insn_ea *ea,
char *dst)
{
int *reg;
char *src;
int len, step;
int sig;
#ifdef DIAGNOSTIC
if (ea->ea_regnum & ~0xF)
panic("%s: bad regnum", __func__);
#endif
DPRINTF(("%s: frame at %p\n", __func__, frame));
/* dst is always int or larger. */
len = insn->is_datasize;
if (len < 4)
dst += (4 - len);
step = (len == 1 && ea->ea_regnum == 15 /* sp */) ? 2 : len;
#if 0
if (ea->ea_flags & EA_FRAME_EA) {
/* Using LC040 frame EA */
#ifdef DEBUG_FPE
if (ea->ea_flags & (EA_PREDECR|EA_POSTINCR)) {
printf("%s: frame ea %08x w/r%d\n",
__func__, ea->ea_fea, ea->ea_regnum);
} else {
printf("%s: frame ea %08x\n", __func__, ea->ea_fea);
}
#endif
src = (char *)ea->ea_fea;
copyin(src + ea->ea_moffs, dst, len);
if (ea->ea_flags & EA_PREDECR) {
frame->f_regs[ea->ea_regnum] = ea->ea_fea;
ea->ea_fea -= step;
ea->ea_moffs = 0;
} else if (ea->ea_flags & EA_POSTINCR) {
ea->ea_fea += step;
frame->f_regs[ea->ea_regnum] = ea->ea_fea;
ea->ea_moffs = 0;
} else {
ea->ea_moffs += step;
}
/* That's it, folks */
} else
#endif
if (ea->ea_flags & EA_DIRECT) {
if (len > 4) {
DPRINTF(("%s: operand doesn't fit CPU reg\n",
__func__));
return SIGILL;
}
if (ea->ea_moffs > 0) {
DPRINTF(("%s: more than one move from CPU reg\n",
__func__));
return SIGILL;
}
src = (char *)&frame->f_regs[ea->ea_regnum];
/* The source is an int. */
if (len < 4) {
src += (4 - len);
DPRINTF(("%s: short/byte opr - addr adjusted\n",
__func__));
}
DPRINTF(("%s: src %p\n", __func__, src));
memcpy(dst, src, len);
} else if (ea->ea_flags & EA_IMMED) {
DPRINTF(("%s: immed %08x%08x%08x size %d\n", __func__,
ea->ea_immed[0], ea->ea_immed[1], ea->ea_immed[2], len));
src = (char *)&ea->ea_immed[0];
if (len < 4) {
src += (4 - len);
DPRINTF(("%s: short/byte immed opr - "
"addr adjusted\n", __func__));
}
memcpy(dst, src, len);
} else if (ea->ea_flags & EA_ABS) {
DPRINTF(("%s: abs addr %08x\n", __func__, ea->ea_absaddr));
src = (char *)ea->ea_absaddr;
copyin(src, dst, len);
} else /* register indirect */ {
if (ea->ea_flags & EA_PC_REL) {
DPRINTF(("%s: using PC\n", __func__));
reg = NULL;
/*
* Grab the register contents. 4 is offset to the first
* extension word from the opcode
*/
src = (char *)insn->is_pc + 4;
DPRINTF(("%s: pc relative pc+4 = %p\n", __func__, src));
} else /* not PC relative */ {
DPRINTF(("%s: using register %c%d\n",
__func__,
(ea->ea_regnum >= 8) ? 'a' : 'd',
ea->ea_regnum & 7));
/* point to the register */
reg = &frame->f_regs[ea->ea_regnum];
if (ea->ea_flags & EA_PREDECR) {
DPRINTF(("%s: predecr mode - "
"reg decremented\n", __func__));
*reg -= step;
ea->ea_moffs = 0;
}
/* Grab the register contents. */
src = (char *)*reg;
DPRINTF(("%s: reg indirect reg = %p\n", __func__, src));
}
sig = calc_ea(ea, src, &src);
if (sig)
return sig;
copyin(src + ea->ea_moffs, dst, len);
/* do post-increment */
if (ea->ea_flags & EA_POSTINCR) {
if (ea->ea_flags & EA_PC_REL) {
DPRINTF(("%s: tried to postincrement PC\n",
__func__));
return SIGILL;
}
*reg += step;
ea->ea_moffs = 0;
DPRINTF(("%s: postinc mode - reg incremented\n",
__func__));
} else {
ea->ea_moffs += len;
}
}
return 0;
}
/*
* Store a value at the effective address.
* Returns zero on success, else signal number.
*/
int
fpu_store_ea(struct frame *frame, struct instruction *insn, struct insn_ea *ea,
char *src)
{
int *reg;
char *dst;
int len, step;
int sig;
#ifdef DIAGNOSTIC
if (ea->ea_regnum & ~0xf)
panic("%s: bad regnum", __func__);
#endif
if (ea->ea_flags & (EA_IMMED|EA_PC_REL)) {
/* not alterable address mode */
DPRINTF(("%s: not alterable address mode\n", __func__));
return SIGILL;
}
/* src is always int or larger. */
len = insn->is_datasize;
if (len < 4)
src += (4 - len);
step = (len == 1 && ea->ea_regnum == 15 /* sp */) ? 2 : len;
if (ea->ea_flags & EA_FRAME_EA) {
/* Using LC040 frame EA */
#ifdef DEBUG_FPE
if (ea->ea_flags & (EA_PREDECR|EA_POSTINCR)) {
printf("%s: frame ea %08x w/r%d\n",
__func__, ea->ea_fea, ea->ea_regnum);
} else {
printf("%s: frame ea %08x\n", __func__, ea->ea_fea);
}
#endif
dst = (char *)ea->ea_fea;
copyout(src, dst + ea->ea_moffs, len);
if (ea->ea_flags & EA_PREDECR) {
frame->f_regs[ea->ea_regnum] = ea->ea_fea;
ea->ea_fea -= step;
ea->ea_moffs = 0;
} else if (ea->ea_flags & EA_POSTINCR) {
ea->ea_fea += step;
frame->f_regs[ea->ea_regnum] = ea->ea_fea;
ea->ea_moffs = 0;
} else {
ea->ea_moffs += step;
}
/* That's it, folks */
} else if (ea->ea_flags & EA_ABS) {
DPRINTF(("%s: abs addr %08x\n", __func__, ea->ea_absaddr));
dst = (char *)ea->ea_absaddr;
copyout(src, dst + ea->ea_moffs, len);
ea->ea_moffs += len;
} else if (ea->ea_flags & EA_DIRECT) {
if (len > 4) {
DPRINTF(("%s: operand doesn't fit CPU reg\n",
__func__));
return SIGILL;
}
if (ea->ea_moffs > 0) {
DPRINTF(("%s: more than one move to CPU reg\n",
__func__));
return SIGILL;
}
dst = (char *)&frame->f_regs[ea->ea_regnum];
/* The destination is an int. */
if (len < 4) {
dst += (4 - len);
DPRINTF(("%s: short/byte opr - dst addr adjusted\n",
__func__));
}
DPRINTF(("%s: dst %p\n", __func__, dst));
memcpy(dst, src, len);
} else /* One of MANY indirect forms... */ {
DPRINTF(("%s: using register %c%d\n", __func__,
(ea->ea_regnum >= 8) ? 'a' : 'd', ea->ea_regnum & 7));
/* point to the register */
reg = &(frame->f_regs[ea->ea_regnum]);
/* do pre-decrement */
if (ea->ea_flags & EA_PREDECR) {
DPRINTF(("%s: predecr mode - reg decremented\n",
__func__));
*reg -= step;
ea->ea_moffs = 0;
}
/* calculate the effective address */
sig = calc_ea(ea, (char *)*reg, &dst);
if (sig)
return sig;
DPRINTF(("%s: dst addr=%p+%d\n", __func__, dst, ea->ea_moffs));
copyout(src, dst + ea->ea_moffs, len);
/* do post-increment */
if (ea->ea_flags & EA_POSTINCR) {
*reg += step;
ea->ea_moffs = 0;
DPRINTF(("%s: postinc mode - reg incremented\n",
__func__));
} else {
ea->ea_moffs += len;
}
}
return 0;
}
/*
* fetch_immed: fetch immediate operand
*/
static int
fetch_immed(struct frame *frame, struct instruction *insn, int *dst)
{
int data, ext_bytes;
ext_bytes = insn->is_datasize;
if (0 < ext_bytes) {
data = fusword((void *)(insn->is_pc + insn->is_advance));
if (data < 0)
return SIGSEGV;
if (ext_bytes == 1) {
/* sign-extend byte to long */
data &= 0xff;
if (data & 0x80)
data |= 0xffffff00;
} else if (ext_bytes == 2) {
/* sign-extend word to long */
data &= 0xffff;
if (data & 0x8000)
data |= 0xffff0000;
}
insn->is_advance += 2;
dst[0] = data;
}
if (2 < ext_bytes) {
data = fusword((void *)(insn->is_pc + insn->is_advance));
if (data < 0)
return SIGSEGV;
insn->is_advance += 2;
dst[0] <<= 16;
dst[0] |= data;
}
if (4 < ext_bytes) {
data = fusword((void *)(insn->is_pc + insn->is_advance));
if (data < 0)
return SIGSEGV;
dst[1] = data << 16;
data = fusword((void *)(insn->is_pc + insn->is_advance + 2));
if (data < 0)
return SIGSEGV;
insn->is_advance += 4;
dst[1] |= data;
}
if (8 < ext_bytes) {
data = fusword((void *)(insn->is_pc + insn->is_advance));
if (data < 0)
return SIGSEGV;
dst[2] = data << 16;
data = fusword((void *)(insn->is_pc + insn->is_advance + 2));
if (data < 0)
return SIGSEGV;
insn->is_advance += 4;
dst[2] |= data;
}
return 0;
}
/*
* fetch_disp: fetch displacement in full extension words
*/
static int
fetch_disp(struct frame *frame, struct instruction *insn, int size, int *res)
{
int disp, word;
if (size == 1) {
word = fusword((void *)(insn->is_pc + insn->is_advance));
if (word < 0)
return SIGSEGV;
disp = word & 0xffff;
if (disp & 0x8000) {
/* sign-extend */
disp |= 0xffff0000;
}
insn->is_advance += 2;
} else if (size == 2) {
word = fusword((void *)(insn->is_pc + insn->is_advance));
if (word < 0)
return SIGSEGV;
disp = word << 16;
word = fusword((void *)(insn->is_pc + insn->is_advance + 2));
if (word < 0)
return SIGSEGV;
disp |= (word & 0xffff);
insn->is_advance += 4;
} else {
disp = 0;
}
*res = disp;
return 0;
}
/*
* Calculates an effective address for all address modes except for
* register direct, absolute, and immediate modes. However, it does
* not take care of predecrement/postincrement of register content.
* Returns a signal value (0 == no error).
*/
static int
calc_ea(struct insn_ea *ea, char *ptr, char **eaddr)
/* ptr: base address (usually a register content) */
/* eaddr: pointer to result pointer */
{
int data, word;
DPRINTF(("%s: reg indirect (reg) = %p\n", __func__, ptr));
if (ea->ea_flags & EA_OFFSET) {
/* apply the signed offset */
DPRINTF(("%s: offset %d\n", __func__, ea->ea_offset));
ptr += ea->ea_offset;
} else if (ea->ea_flags & EA_INDEXED) {
DPRINTF(("%s: indexed mode\n", __func__));
if (ea->ea_flags & EA_BASE_SUPPRSS) {
/* base register is suppressed */
ptr = (char *)ea->ea_basedisp;
} else {
ptr += ea->ea_basedisp;
}
if (ea->ea_flags & EA_MEM_INDIR) {
DPRINTF(("%s: mem indir mode: basedisp=%08x, "
"outerdisp=%08x\n",
__func__, ea->ea_basedisp, ea->ea_outerdisp));
DPRINTF(("%s: addr fetched from %p\n", __func__, ptr));
/* memory indirect modes */
word = fusword(ptr);
if (word < 0)
return SIGSEGV;
word <<= 16;
data = fusword(ptr + 2);
if (data < 0)
return SIGSEGV;
word |= data;
DPRINTF(("%s: fetched ptr 0x%08x\n", __func__, word));
ptr = (char *)word + ea->ea_outerdisp;
}
}
*eaddr = ptr;
return 0;
}
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