binutils-gdb/gdb/i387-tdep.c
Michael Sturm 01f9f808e2 Add AVX512 registers support to GDB and GDBserver.
This patch adds support for the Intel(R) Advanced Vector
Extensions 512 (Intel(R) AVX-512) registers.  Native and remote
debugging are covered by this patch.

Intel(R) AVX-512 is an extension to AVX to support 512-bit wide
SIMD registers in 64-bit mode (XMM0-XMM31, YMM0-YMM31, ZMM0-ZMM31).
The number of available registers in 32-bit mode is still 8
(XMM0-7, YMM0-7, ZMM0-7).  The lower 256-bits of the ZMM registers
are aliased to the respective 256-bit YMM registers.  The lower
128-bits are aliased to the respective 128-bit XMM registers.

There are also 8 new, dedicated mask registers (K0-K7) in both 32-bit
mode and 64-bit mode.

For more information please see
Intel(R) Developer Zone: Intel(R) AVX
http://software.intel.com/en-us/intel-isa-extensions#pid-16007-1495

Intel(R) Architecture Instruction Set Extensions Programming Reference:
http://software.intel.com/en-us/file/319433-017pdf

2014-04-24  Michael Sturm  <michael.sturm@mintel.com>
            Walfred Tedeschi  <walfred.tedeschi@intel.com>

     * amd64-linux-nat.c (amd64_linux_gregset32_reg_offset): Add
     AVX512 registers.
     (amd64_linux_read_description): Add code to handle AVX512 xstate
     mask and return respective tdesc.
     * amd64-linux-tdep.c: Include features/i386/amd64-avx512-linux.c
     and features/i386/x32-avx512-linux.c.
     (amd64_linux_gregset_reg_offset): Add AVX512 registers.
     (amd64_linux_core_read_description): Add code to handle AVX512
     xstate mask and return respective tdesc.
     (_initialize_amd64_linux_tdep): Initialize AVX512 tdesc.
     * amd64-linux-tdep.h (AMD64_LINUX_ORIG_RAX_REGNUM): Adjust regnum
     calculation.
     (AMD64_LINUX_NUM_REGS): Adjust to new number of registers.
     (tdesc_amd64_avx512_linux): New prototype.
     (tdesc_x32_avx512_linux): Likewise.
     * amd64-tdep.c: Include features/i386/amd64-avx512.c and
     features/i386/x32-avx512.c.
     (amd64_ymm_avx512_names): New register names for pseudo
     registers YMM16-31.
     (amd64_ymmh_avx512_names): New register names for raw registers
     YMMH16-31.
     (amd64_k_names): New register names for K registers.
     (amd64_zmmh_names): New register names for ZMM raw registers.
     (amd64_zmm_names): New registers names for ZMM pseudo registers.
     (amd64_xmm_avx512_names): New register names for XMM16-31
     registers.
     (amd64_pseudo_register_name): Add code to return AVX512 pseudo
     registers.
     (amd64_init_abi): Add code to intitialize AVX512 tdep variables
     if feature is present.
     (_initialize_amd64_tdep): Call AVX512 tdesc initializers.
     * amd64-tdep.h (enum amd64_regnum): Add AVX512 registers.
     (AMD64_NUM_REGS): Adjust to new number of registers.
     * i386-linux-nat.c (GETXSTATEREGS_SUPPLIES): Extend range of
     registers supplied via XSTATE by AVX512 registers.
     (i386_linux_read_description): Add case for AVX512.
     * i386-linux-tdep.c: Include i386-avx512-linux.c.
     (i386_linux_gregset_reg_offset): Add AVX512 registers.
     (i386_linux_core_read_description): Add case for AVX512.
     (i386_linux_init_abi): Install supported register note section
     for AVX512.
     (_initialize_i386_linux_tdep): Add call to tdesc init function for
     AVX512.
     * i386-linux-tdep.h (I386_LINUX_NUM_REGS): Set number of
     registers to be number of zmm7h + 1.
     (tdesc_i386_avx512_linux): Add tdesc for AVX512 registers.
     * i386-tdep.c: Include features/i386/i386-avx512.c.
     (i386_zmm_names): Add ZMM pseudo register names array.
     (i386_zmmh_names): Add ZMM raw register names array.
     (i386_k_names): Add K raw register names array.
     (num_lower_zmm_regs): Add constant for the number of lower ZMM
     registers. AVX512 has 16 more ZMM registers than there are YMM
     registers.
     (i386_zmmh_regnum_p): Add function to look up register number of
     ZMM raw registers.
     (i386_zmm_regnum_p): Likewise for ZMM pseudo registers.
     (i386_k_regnum_p): Likewise for K raw registers.
     (i386_ymmh_avx512_regnum_p): Likewise for additional YMM raw
     registers added by AVX512.
     (i386_ymm_avx512_regnum_p): Likewise for additional YMM pseudo
     registers added by AVX512.
     (i386_xmm_avx512_regnum_p): Likewise for additional XMM registers
     added by AVX512.
     (i386_register_name): Add code to hide YMMH16-31 and ZMMH0-31.
     (i386_pseudo_register_name): Add ZMM pseudo registers.
     (i386_zmm_type): Construct and return vector registers type for ZMM
     registers.
     (i386_pseudo_register_type): Return appropriate type for YMM16-31,
     ZMM0-31 pseudo registers and K registers.
     (i386_pseudo_register_read_into_value): Add code to read K, ZMM
     and YMM16-31 registers from register cache.
     (i386_pseudo_register_write): Add code to write  K, ZMM and
     YMM16-31 registers.
     (i386_register_reggroup_p): Add code to include/exclude AVX512
     registers in/from respective register groups.
     (i386_validate_tdesc_p): Handle AVX512 feature, add AVX512
     registers if feature is present in xcr0.
     (i386_gdbarch_init): Add code to initialize AVX512 feature
     variables in tdep structure, wire in pseudo registers and call
     initialize_tdesc_i386_avx512.
     * i386-tdep.h (struct gdbarch_tdep): Add AVX512 related
     variables.
     (i386_regnum): Add AVX512 registers.
     (I386_SSE_NUM_REGS): New define for number of SSE registers.
     (I386_AVX_NUM_REGS): Likewise for AVX registers.
     (I386_AVX512_NUM_REGS): Likewise for AVX512 registers.
     (I386_MAX_REGISTER_SIZE): Change to 64 bytes, ZMM registers are
     512 bits wide.
     (i386_xmm_avx512_regnum_p): New prototype for register look up.
     (i386_ymm_avx512_regnum_p): Likewise.
     (i386_k_regnum_p): Likewise.
     (i386_zmm_regnum_p): Likewise.
     (i386_zmmh_regnum_p): Likewise.
     * i387-tdep.c : Update year in copyright notice.
     (xsave_ymm_avx512_offset): New table for YMM16-31 offsets in
     XSAVE buffer.
     (XSAVE_YMM_AVX512_ADDR): New macro.
     (xsave_xmm_avx512_offset): New table for XMM16-31 offsets in
     XSAVE buffer.
     (XSAVE_XMM_AVX512_ADDR): New macro.
     (xsave_avx512_k_offset): New table for K register offsets in
     XSAVE buffer.
     (XSAVE_AVX512_K_ADDR): New macro.
     (xsave_avx512_zmm_h_offset): New table for ZMM register offsets
     in XSAVE buffer.
     (XSAVE_AVX512_ZMM_H_ADDR): New macro.
     (i387_supply_xsave): Add code to supply AVX512 registers to XSAVE
     buffer.
     (i387_collect_xsave): Add code to collect AVX512 registers from
     XSAVE buffer.
     * i387-tdep.h (I387_NUM_XMM_AVX512_REGS): New define for number
     of XMM16-31 registers.
     (I387_NUM_K_REGS): New define for number of K registers.
     (I387_K0_REGNUM): New define for K0 register number.
     (I387_NUM_ZMMH_REGS): New define for number of ZMMH registers.
     (I387_ZMM0H_REGNUM): New define for ZMM0H register number.
     (I387_NUM_YMM_AVX512_REGS): New define for number of YMM16-31
     registers.
     (I387_YMM16H_REGNUM): New define for YMM16H register number.
     (I387_XMM16_REGNUM): New define for XMM16 register number.
     (I387_YMM0_REGNUM): New define for YMM0 register number.
     (I387_KEND_REGNUM): New define for last K register number.
     (I387_ZMMENDH_REGNUM): New define for last ZMMH register number.
     (I387_YMMH_AVX512_END_REGNUM): New define for YMM31 register
     number.
     (I387_XMM_AVX512_END_REGNUM): New define for XMM31 register
     number.
     * common/i386-xstate.h: Add AVX 3.1 feature bits, mask and XSTATE
     size.
     * features/Makefile: Add AVX512 related files.
     * features/i386/32bit-avx512.xml: New file.
     * features/i386/64bit-avx512.xml: Likewise.
     * features/i386/amd64-avx512-linux.c: Likewise.
     * features/i386/amd64-avx512-linux.xml: Likewise.
     * features/i386/amd64-avx512.c: Likewise.
     * features/i386/amd64-avx512.xml: Likewise.
     * features/i386/i386-avx512-linux.c: Likewise.
     * features/i386/i386-avx512-linux.xml: Likewise.
     * features/i386/i386-avx512.c: Likewise.
     * features/i386/i386-avx512.xml: Likewise.
     * features/i386/x32-avx512-linux.c: Likewise.
     * features/i386/x32-avx512-linux.xml: Likewise.
     * features/i386/x32-avx512.c: Likewise.
     * features/i386/x32-avx512.xml: Likewise.
     * regformats/i386/amd64-avx512-linux.dat: New file.
     * regformats/i386/amd64-avx512.dat: Likewise.
     * regformats/i386/i386-avx512-linux.dat: Likewise.
     * regformats/i386/i386-avx512.dat: Likewise.
     * regformats/i386/x32-avx512-linux.dat: Likewise.
     * regformats/i386/x32-avx512.dat: Likewise.
     * NEWS: Add note about new support for AVX512.

testsuite/
     * Makefile.in (EXECUTABLES): Added i386-avx512.
     * gdb.arch/i386-avx512.c: New file.
     * gdb.arch/i386-avx512.exp: Likewise.

gdbserver/
     * Makefile.in: Added rules to handle new files
     i386-avx512.c i386-avx512-linux.c amd64-avx512.c
     amd64-avx512-linux.c x32-avx512.c x32-avx512-linux.c.
     * configure.srv (srv_i386_regobj): Add i386-avx512.o.
     (srv_i386_linux_regobj): Add i386-avx512-linux.o.
     (srv_amd64_regobj): Add amd64-avx512.o and x32-avx512.o.
     (srv_amd64_linux_regobj): Add amd64-avx512-linux.o and
     x32-avx512-linux.o.
     (srv_i386_32bit_xmlfiles): Add i386/32bit-avx512.xml.
     (srv_i386_64bit_xmlfiles): Add i386/64bit-avx512.xml.
     (srv_amd64_xmlfiles): Add i386/amd64-avx512.xml and
     i386/x32-avx512.xml.
     (srv_i386_linux_xmlfiles): Add i386/i386-avx512-linux.xml.
     (srv_amd64_linux_xmlfiles): Add i386/amd64-avx512-linux.xml and
     i386/x32-avx512-linux.xml.
     * i387-fp.c (num_avx512_k_registers): New constant for number
     of K registers.
     (num_avx512_zmmh_low_registers): New constant for number of
     lower ZMM registers (0-15).
     (num_avx512_zmmh_high_registers): New constant for number of
     higher ZMM registers (16-31).
     (num_avx512_ymmh_registers): New contant for number of higher
     YMM registers (ymm16-31 added by avx521 on x86_64).
     (num_avx512_xmm_registers): New constant for number of higher
     XMM registers (xmm16-31 added by AVX512 on x86_64).
     (struct i387_xsave): Add space for AVX512 registers.
     (i387_cache_to_xsave): Change raw buffer size to 64 characters.
     Add code to handle AVX512 registers.
     (i387_xsave_to_cache): Add code to handle AVX512 registers.
     * linux-x86-low.c (init_registers_amd64_avx512_linux): New
     prototypei from generated file.
     (tdesc_amd64_avx512_linux): Likewise.
     (init_registers_x32_avx512_linux): Likewise.
     (tdesc_x32_avx512_linux): Likewise.
     (init_registers_i386_avx512_linux): Likewise.
     (tdesc_i386_avx512_linux): Likewise.
     (x86_64_regmap): Add AVX512 registers.
     (x86_linux_read_description): Add code to handle AVX512 XSTATE
     mask.
     (initialize_low_arch): Add code to initialize AVX512 registers.

doc/
     * gdb.texinfo (i386 Features): Add description of AVX512
     registers.

Change-Id: Ifc4c08c76b85dbec18d02efdbe6182e851584438
Signed-off-by: Michael Sturm <michael.sturm@intel.com>
2014-04-24 16:30:03 +02:00

1778 lines
48 KiB
C
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/* Intel 387 floating point stuff.
Copyright (C) 1988-2014 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 <http://www.gnu.org/licenses/>. */
#include "defs.h"
#include "doublest.h"
#include "floatformat.h"
#include "frame.h"
#include "gdbcore.h"
#include "inferior.h"
#include "language.h"
#include "regcache.h"
#include "value.h"
#include "gdb_assert.h"
#include <string.h>
#include "i386-tdep.h"
#include "i387-tdep.h"
#include "i386-xstate.h"
/* Print the floating point number specified by RAW. */
static void
print_i387_value (struct gdbarch *gdbarch,
const gdb_byte *raw, struct ui_file *file)
{
DOUBLEST value;
/* Using extract_typed_floating here might affect the representation
of certain numbers such as NaNs, even if GDB is running natively.
This is fine since our caller already detects such special
numbers and we print the hexadecimal representation anyway. */
value = extract_typed_floating (raw, i387_ext_type (gdbarch));
/* We try to print 19 digits. The last digit may or may not contain
garbage, but we'd better print one too many. We need enough room
to print the value, 1 position for the sign, 1 for the decimal
point, 19 for the digits and 6 for the exponent adds up to 27. */
#ifdef PRINTF_HAS_LONG_DOUBLE
fprintf_filtered (file, " %-+27.19Lg", (long double) value);
#else
fprintf_filtered (file, " %-+27.19g", (double) value);
#endif
}
/* Print the classification for the register contents RAW. */
static void
print_i387_ext (struct gdbarch *gdbarch,
const gdb_byte *raw, struct ui_file *file)
{
int sign;
int integer;
unsigned int exponent;
unsigned long fraction[2];
sign = raw[9] & 0x80;
integer = raw[7] & 0x80;
exponent = (((raw[9] & 0x7f) << 8) | raw[8]);
fraction[0] = ((raw[3] << 24) | (raw[2] << 16) | (raw[1] << 8) | raw[0]);
fraction[1] = (((raw[7] & 0x7f) << 24) | (raw[6] << 16)
| (raw[5] << 8) | raw[4]);
if (exponent == 0x7fff && integer)
{
if (fraction[0] == 0x00000000 && fraction[1] == 0x00000000)
/* Infinity. */
fprintf_filtered (file, " %cInf", (sign ? '-' : '+'));
else if (sign && fraction[0] == 0x00000000 && fraction[1] == 0x40000000)
/* Real Indefinite (QNaN). */
fputs_unfiltered (" Real Indefinite (QNaN)", file);
else if (fraction[1] & 0x40000000)
/* QNaN. */
fputs_filtered (" QNaN", file);
else
/* SNaN. */
fputs_filtered (" SNaN", file);
}
else if (exponent < 0x7fff && exponent > 0x0000 && integer)
/* Normal. */
print_i387_value (gdbarch, raw, file);
else if (exponent == 0x0000)
{
/* Denormal or zero. */
print_i387_value (gdbarch, raw, file);
if (integer)
/* Pseudo-denormal. */
fputs_filtered (" Pseudo-denormal", file);
else if (fraction[0] || fraction[1])
/* Denormal. */
fputs_filtered (" Denormal", file);
}
else
/* Unsupported. */
fputs_filtered (" Unsupported", file);
}
/* Print the status word STATUS. If STATUS_P is false, then STATUS
was unavailable. */
static void
print_i387_status_word (int status_p,
unsigned int status, struct ui_file *file)
{
fprintf_filtered (file, "Status Word: ");
if (!status_p)
{
fprintf_filtered (file, "%s\n", _("<unavailable>"));
return;
}
fprintf_filtered (file, "%s", hex_string_custom (status, 4));
fputs_filtered (" ", file);
fprintf_filtered (file, " %s", (status & 0x0001) ? "IE" : " ");
fprintf_filtered (file, " %s", (status & 0x0002) ? "DE" : " ");
fprintf_filtered (file, " %s", (status & 0x0004) ? "ZE" : " ");
fprintf_filtered (file, " %s", (status & 0x0008) ? "OE" : " ");
fprintf_filtered (file, " %s", (status & 0x0010) ? "UE" : " ");
fprintf_filtered (file, " %s", (status & 0x0020) ? "PE" : " ");
fputs_filtered (" ", file);
fprintf_filtered (file, " %s", (status & 0x0080) ? "ES" : " ");
fputs_filtered (" ", file);
fprintf_filtered (file, " %s", (status & 0x0040) ? "SF" : " ");
fputs_filtered (" ", file);
fprintf_filtered (file, " %s", (status & 0x0100) ? "C0" : " ");
fprintf_filtered (file, " %s", (status & 0x0200) ? "C1" : " ");
fprintf_filtered (file, " %s", (status & 0x0400) ? "C2" : " ");
fprintf_filtered (file, " %s", (status & 0x4000) ? "C3" : " ");
fputs_filtered ("\n", file);
fprintf_filtered (file,
" TOP: %d\n", ((status >> 11) & 7));
}
/* Print the control word CONTROL. If CONTROL_P is false, then
CONTROL was unavailable. */
static void
print_i387_control_word (int control_p,
unsigned int control, struct ui_file *file)
{
fprintf_filtered (file, "Control Word: ");
if (!control_p)
{
fprintf_filtered (file, "%s\n", _("<unavailable>"));
return;
}
fprintf_filtered (file, "%s", hex_string_custom (control, 4));
fputs_filtered (" ", file);
fprintf_filtered (file, " %s", (control & 0x0001) ? "IM" : " ");
fprintf_filtered (file, " %s", (control & 0x0002) ? "DM" : " ");
fprintf_filtered (file, " %s", (control & 0x0004) ? "ZM" : " ");
fprintf_filtered (file, " %s", (control & 0x0008) ? "OM" : " ");
fprintf_filtered (file, " %s", (control & 0x0010) ? "UM" : " ");
fprintf_filtered (file, " %s", (control & 0x0020) ? "PM" : " ");
fputs_filtered ("\n", file);
fputs_filtered (" PC: ", file);
switch ((control >> 8) & 3)
{
case 0:
fputs_filtered ("Single Precision (24-bits)\n", file);
break;
case 1:
fputs_filtered ("Reserved\n", file);
break;
case 2:
fputs_filtered ("Double Precision (53-bits)\n", file);
break;
case 3:
fputs_filtered ("Extended Precision (64-bits)\n", file);
break;
}
fputs_filtered (" RC: ", file);
switch ((control >> 10) & 3)
{
case 0:
fputs_filtered ("Round to nearest\n", file);
break;
case 1:
fputs_filtered ("Round down\n", file);
break;
case 2:
fputs_filtered ("Round up\n", file);
break;
case 3:
fputs_filtered ("Round toward zero\n", file);
break;
}
}
/* Print out the i387 floating point state. Note that we ignore FRAME
in the code below. That's OK since floating-point registers are
never saved on the stack. */
void
i387_print_float_info (struct gdbarch *gdbarch, struct ui_file *file,
struct frame_info *frame, const char *args)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (get_frame_arch (frame));
ULONGEST fctrl;
int fctrl_p;
ULONGEST fstat;
int fstat_p;
ULONGEST ftag;
int ftag_p;
ULONGEST fiseg;
int fiseg_p;
ULONGEST fioff;
int fioff_p;
ULONGEST foseg;
int foseg_p;
ULONGEST fooff;
int fooff_p;
ULONGEST fop;
int fop_p;
int fpreg;
int top;
gdb_assert (gdbarch == get_frame_arch (frame));
fctrl_p = read_frame_register_unsigned (frame,
I387_FCTRL_REGNUM (tdep), &fctrl);
fstat_p = read_frame_register_unsigned (frame,
I387_FSTAT_REGNUM (tdep), &fstat);
ftag_p = read_frame_register_unsigned (frame,
I387_FTAG_REGNUM (tdep), &ftag);
fiseg_p = read_frame_register_unsigned (frame,
I387_FISEG_REGNUM (tdep), &fiseg);
fioff_p = read_frame_register_unsigned (frame,
I387_FIOFF_REGNUM (tdep), &fioff);
foseg_p = read_frame_register_unsigned (frame,
I387_FOSEG_REGNUM (tdep), &foseg);
fooff_p = read_frame_register_unsigned (frame,
I387_FOOFF_REGNUM (tdep), &fooff);
fop_p = read_frame_register_unsigned (frame,
I387_FOP_REGNUM (tdep), &fop);
if (fstat_p)
{
top = ((fstat >> 11) & 7);
for (fpreg = 7; fpreg >= 0; fpreg--)
{
struct value *regval;
int regnum;
int i;
int tag = -1;
fprintf_filtered (file, "%sR%d: ", fpreg == top ? "=>" : " ", fpreg);
if (ftag_p)
{
tag = (ftag >> (fpreg * 2)) & 3;
switch (tag)
{
case 0:
fputs_filtered ("Valid ", file);
break;
case 1:
fputs_filtered ("Zero ", file);
break;
case 2:
fputs_filtered ("Special ", file);
break;
case 3:
fputs_filtered ("Empty ", file);
break;
}
}
else
fputs_filtered ("Unknown ", file);
regnum = (fpreg + 8 - top) % 8 + I387_ST0_REGNUM (tdep);
regval = get_frame_register_value (frame, regnum);
if (value_entirely_available (regval))
{
const gdb_byte *raw = value_contents (regval);
fputs_filtered ("0x", file);
for (i = 9; i >= 0; i--)
fprintf_filtered (file, "%02x", raw[i]);
if (tag != -1 && tag != 3)
print_i387_ext (gdbarch, raw, file);
}
else
fprintf_filtered (file, "%s", _("<unavailable>"));
fputs_filtered ("\n", file);
}
}
fputs_filtered ("\n", file);
print_i387_status_word (fstat_p, fstat, file);
print_i387_control_word (fctrl_p, fctrl, file);
fprintf_filtered (file, "Tag Word: %s\n",
ftag_p ? hex_string_custom (ftag, 4) : _("<unavailable>"));
fprintf_filtered (file, "Instruction Pointer: %s:",
fiseg_p ? hex_string_custom (fiseg, 2) : _("<unavailable>"));
fprintf_filtered (file, "%s\n",
fioff_p ? hex_string_custom (fioff, 8) : _("<unavailable>"));
fprintf_filtered (file, "Operand Pointer: %s:",
foseg_p ? hex_string_custom (foseg, 2) : _("<unavailable>"));
fprintf_filtered (file, "%s\n",
fooff_p ? hex_string_custom (fooff, 8) : _("<unavailable>"));
fprintf_filtered (file, "Opcode: %s\n",
fop_p
? (hex_string_custom (fop ? (fop | 0xd800) : 0, 4))
: _("<unavailable>"));
}
/* Return nonzero if a value of type TYPE stored in register REGNUM
needs any special handling. */
int
i387_convert_register_p (struct gdbarch *gdbarch, int regnum,
struct type *type)
{
if (i386_fp_regnum_p (gdbarch, regnum))
{
/* Floating point registers must be converted unless we are
accessing them in their hardware type. */
if (type == i387_ext_type (gdbarch))
return 0;
else
return 1;
}
return 0;
}
/* Read a value of type TYPE from register REGNUM in frame FRAME, and
return its contents in TO. */
int
i387_register_to_value (struct frame_info *frame, int regnum,
struct type *type, gdb_byte *to,
int *optimizedp, int *unavailablep)
{
struct gdbarch *gdbarch = get_frame_arch (frame);
gdb_byte from[I386_MAX_REGISTER_SIZE];
gdb_assert (i386_fp_regnum_p (gdbarch, regnum));
/* We only support floating-point values. */
if (TYPE_CODE (type) != TYPE_CODE_FLT)
{
warning (_("Cannot convert floating-point register value "
"to non-floating-point type."));
*optimizedp = *unavailablep = 0;
return 0;
}
/* Convert to TYPE. */
if (!get_frame_register_bytes (frame, regnum, 0, TYPE_LENGTH (type),
from, optimizedp, unavailablep))
return 0;
convert_typed_floating (from, i387_ext_type (gdbarch), to, type);
*optimizedp = *unavailablep = 0;
return 1;
}
/* Write the contents FROM of a value of type TYPE into register
REGNUM in frame FRAME. */
void
i387_value_to_register (struct frame_info *frame, int regnum,
struct type *type, const gdb_byte *from)
{
struct gdbarch *gdbarch = get_frame_arch (frame);
gdb_byte to[I386_MAX_REGISTER_SIZE];
gdb_assert (i386_fp_regnum_p (gdbarch, regnum));
/* We only support floating-point values. */
if (TYPE_CODE (type) != TYPE_CODE_FLT)
{
warning (_("Cannot convert non-floating-point type "
"to floating-point register value."));
return;
}
/* Convert from TYPE. */
convert_typed_floating (from, type, to, i387_ext_type (gdbarch));
put_frame_register (frame, regnum, to);
}
/* Handle FSAVE and FXSAVE formats. */
/* At fsave_offset[REGNUM] you'll find the offset to the location in
the data structure used by the "fsave" instruction where GDB
register REGNUM is stored. */
static int fsave_offset[] =
{
28 + 0 * 10, /* %st(0) ... */
28 + 1 * 10,
28 + 2 * 10,
28 + 3 * 10,
28 + 4 * 10,
28 + 5 * 10,
28 + 6 * 10,
28 + 7 * 10, /* ... %st(7). */
0, /* `fctrl' (16 bits). */
4, /* `fstat' (16 bits). */
8, /* `ftag' (16 bits). */
16, /* `fiseg' (16 bits). */
12, /* `fioff'. */
24, /* `foseg' (16 bits). */
20, /* `fooff'. */
18 /* `fop' (bottom 11 bits). */
};
#define FSAVE_ADDR(tdep, fsave, regnum) \
(fsave + fsave_offset[regnum - I387_ST0_REGNUM (tdep)])
/* Fill register REGNUM in REGCACHE with the appropriate value from
*FSAVE. This function masks off any of the reserved bits in
*FSAVE. */
void
i387_supply_fsave (struct regcache *regcache, int regnum, const void *fsave)
{
struct gdbarch *gdbarch = get_regcache_arch (regcache);
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
const gdb_byte *regs = fsave;
int i;
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
for (i = I387_ST0_REGNUM (tdep); i < I387_XMM0_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
if (fsave == NULL)
{
regcache_raw_supply (regcache, i, NULL);
continue;
}
/* Most of the FPU control registers occupy only 16 bits in the
fsave area. Give those a special treatment. */
if (i >= I387_FCTRL_REGNUM (tdep)
&& i != I387_FIOFF_REGNUM (tdep) && i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte val[4];
memcpy (val, FSAVE_ADDR (tdep, regs, i), 2);
val[2] = val[3] = 0;
if (i == I387_FOP_REGNUM (tdep))
val[1] &= ((1 << 3) - 1);
regcache_raw_supply (regcache, i, val);
}
else
regcache_raw_supply (regcache, i, FSAVE_ADDR (tdep, regs, i));
}
/* Provide dummy values for the SSE registers. */
for (i = I387_XMM0_REGNUM (tdep); i < I387_MXCSR_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
regcache_raw_supply (regcache, i, NULL);
if (regnum == -1 || regnum == I387_MXCSR_REGNUM (tdep))
{
gdb_byte buf[4];
store_unsigned_integer (buf, 4, byte_order, 0x1f80);
regcache_raw_supply (regcache, I387_MXCSR_REGNUM (tdep), buf);
}
}
/* Fill register REGNUM (if it is a floating-point register) in *FSAVE
with the value from REGCACHE. If REGNUM is -1, do this for all
registers. This function doesn't touch any of the reserved bits in
*FSAVE. */
void
i387_collect_fsave (const struct regcache *regcache, int regnum, void *fsave)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (get_regcache_arch (regcache));
gdb_byte *regs = fsave;
int i;
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
for (i = I387_ST0_REGNUM (tdep); i < I387_XMM0_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
/* Most of the FPU control registers occupy only 16 bits in
the fsave area. Give those a special treatment. */
if (i >= I387_FCTRL_REGNUM (tdep)
&& i != I387_FIOFF_REGNUM (tdep) && i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte buf[4];
regcache_raw_collect (regcache, i, buf);
if (i == I387_FOP_REGNUM (tdep))
{
/* The opcode occupies only 11 bits. Make sure we
don't touch the other bits. */
buf[1] &= ((1 << 3) - 1);
buf[1] |= ((FSAVE_ADDR (tdep, regs, i))[1] & ~((1 << 3) - 1));
}
memcpy (FSAVE_ADDR (tdep, regs, i), buf, 2);
}
else
regcache_raw_collect (regcache, i, FSAVE_ADDR (tdep, regs, i));
}
}
/* At fxsave_offset[REGNUM] you'll find the offset to the location in
the data structure used by the "fxsave" instruction where GDB
register REGNUM is stored. */
static int fxsave_offset[] =
{
32, /* %st(0) through ... */
48,
64,
80,
96,
112,
128,
144, /* ... %st(7) (80 bits each). */
0, /* `fctrl' (16 bits). */
2, /* `fstat' (16 bits). */
4, /* `ftag' (16 bits). */
12, /* `fiseg' (16 bits). */
8, /* `fioff'. */
20, /* `foseg' (16 bits). */
16, /* `fooff'. */
6, /* `fop' (bottom 11 bits). */
160 + 0 * 16, /* %xmm0 through ... */
160 + 1 * 16,
160 + 2 * 16,
160 + 3 * 16,
160 + 4 * 16,
160 + 5 * 16,
160 + 6 * 16,
160 + 7 * 16,
160 + 8 * 16,
160 + 9 * 16,
160 + 10 * 16,
160 + 11 * 16,
160 + 12 * 16,
160 + 13 * 16,
160 + 14 * 16,
160 + 15 * 16, /* ... %xmm15 (128 bits each). */
};
#define FXSAVE_ADDR(tdep, fxsave, regnum) \
(fxsave + fxsave_offset[regnum - I387_ST0_REGNUM (tdep)])
/* We made an unfortunate choice in putting %mxcsr after the SSE
registers %xmm0-%xmm7 instead of before, since it makes supporting
the registers %xmm8-%xmm15 on AMD64 a bit involved. Therefore we
don't include the offset for %mxcsr here above. */
#define FXSAVE_MXCSR_ADDR(fxsave) (fxsave + 24)
static int i387_tag (const gdb_byte *raw);
/* Fill register REGNUM in REGCACHE with the appropriate
floating-point or SSE register value from *FXSAVE. This function
masks off any of the reserved bits in *FXSAVE. */
void
i387_supply_fxsave (struct regcache *regcache, int regnum, const void *fxsave)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (get_regcache_arch (regcache));
const gdb_byte *regs = fxsave;
int i;
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
gdb_assert (tdep->num_xmm_regs > 0);
for (i = I387_ST0_REGNUM (tdep); i < I387_MXCSR_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
if (regs == NULL)
{
regcache_raw_supply (regcache, i, NULL);
continue;
}
/* Most of the FPU control registers occupy only 16 bits in
the fxsave area. Give those a special treatment. */
if (i >= I387_FCTRL_REGNUM (tdep) && i < I387_XMM0_REGNUM (tdep)
&& i != I387_FIOFF_REGNUM (tdep) && i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte val[4];
memcpy (val, FXSAVE_ADDR (tdep, regs, i), 2);
val[2] = val[3] = 0;
if (i == I387_FOP_REGNUM (tdep))
val[1] &= ((1 << 3) - 1);
else if (i== I387_FTAG_REGNUM (tdep))
{
/* The fxsave area contains a simplified version of
the tag word. We have to look at the actual 80-bit
FP data to recreate the traditional i387 tag word. */
unsigned long ftag = 0;
int fpreg;
int top;
top = ((FXSAVE_ADDR (tdep, regs,
I387_FSTAT_REGNUM (tdep)))[1] >> 3);
top &= 0x7;
for (fpreg = 7; fpreg >= 0; fpreg--)
{
int tag;
if (val[0] & (1 << fpreg))
{
int thisreg = (fpreg + 8 - top) % 8
+ I387_ST0_REGNUM (tdep);
tag = i387_tag (FXSAVE_ADDR (tdep, regs, thisreg));
}
else
tag = 3; /* Empty */
ftag |= tag << (2 * fpreg);
}
val[0] = ftag & 0xff;
val[1] = (ftag >> 8) & 0xff;
}
regcache_raw_supply (regcache, i, val);
}
else
regcache_raw_supply (regcache, i, FXSAVE_ADDR (tdep, regs, i));
}
if (regnum == I387_MXCSR_REGNUM (tdep) || regnum == -1)
{
if (regs == NULL)
regcache_raw_supply (regcache, I387_MXCSR_REGNUM (tdep), NULL);
else
regcache_raw_supply (regcache, I387_MXCSR_REGNUM (tdep),
FXSAVE_MXCSR_ADDR (regs));
}
}
/* Fill register REGNUM (if it is a floating-point or SSE register) in
*FXSAVE with the value from REGCACHE. If REGNUM is -1, do this for
all registers. This function doesn't touch any of the reserved
bits in *FXSAVE. */
void
i387_collect_fxsave (const struct regcache *regcache, int regnum, void *fxsave)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (get_regcache_arch (regcache));
gdb_byte *regs = fxsave;
int i;
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
gdb_assert (tdep->num_xmm_regs > 0);
for (i = I387_ST0_REGNUM (tdep); i < I387_MXCSR_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
/* Most of the FPU control registers occupy only 16 bits in
the fxsave area. Give those a special treatment. */
if (i >= I387_FCTRL_REGNUM (tdep) && i < I387_XMM0_REGNUM (tdep)
&& i != I387_FIOFF_REGNUM (tdep) && i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte buf[4];
regcache_raw_collect (regcache, i, buf);
if (i == I387_FOP_REGNUM (tdep))
{
/* The opcode occupies only 11 bits. Make sure we
don't touch the other bits. */
buf[1] &= ((1 << 3) - 1);
buf[1] |= ((FXSAVE_ADDR (tdep, regs, i))[1] & ~((1 << 3) - 1));
}
else if (i == I387_FTAG_REGNUM (tdep))
{
/* Converting back is much easier. */
unsigned short ftag;
int fpreg;
ftag = (buf[1] << 8) | buf[0];
buf[0] = 0;
buf[1] = 0;
for (fpreg = 7; fpreg >= 0; fpreg--)
{
int tag = (ftag >> (fpreg * 2)) & 3;
if (tag != 3)
buf[0] |= (1 << fpreg);
}
}
memcpy (FXSAVE_ADDR (tdep, regs, i), buf, 2);
}
else
regcache_raw_collect (regcache, i, FXSAVE_ADDR (tdep, regs, i));
}
if (regnum == I387_MXCSR_REGNUM (tdep) || regnum == -1)
regcache_raw_collect (regcache, I387_MXCSR_REGNUM (tdep),
FXSAVE_MXCSR_ADDR (regs));
}
/* `xstate_bv' is at byte offset 512. */
#define XSAVE_XSTATE_BV_ADDR(xsave) (xsave + 512)
/* At xsave_avxh_offset[REGNUM] you'll find the offset to the location in
the upper 128bit of AVX register data structure used by the "xsave"
instruction where GDB register REGNUM is stored. */
static int xsave_avxh_offset[] =
{
576 + 0 * 16, /* Upper 128bit of %ymm0 through ... */
576 + 1 * 16,
576 + 2 * 16,
576 + 3 * 16,
576 + 4 * 16,
576 + 5 * 16,
576 + 6 * 16,
576 + 7 * 16,
576 + 8 * 16,
576 + 9 * 16,
576 + 10 * 16,
576 + 11 * 16,
576 + 12 * 16,
576 + 13 * 16,
576 + 14 * 16,
576 + 15 * 16 /* Upper 128bit of ... %ymm15 (128 bits each). */
};
#define XSAVE_AVXH_ADDR(tdep, xsave, regnum) \
(xsave + xsave_avxh_offset[regnum - I387_YMM0H_REGNUM (tdep)])
/* At xsave_ymm_avx512_offset[REGNUM] you'll find the offset to the location in
the upper 128bit of ZMM register data structure used by the "xsave"
instruction where GDB register REGNUM is stored. */
static int xsave_ymm_avx512_offset[] =
{
/* HI16_ZMM_area + 16 bytes + regnum* 64 bytes. */
1664 + 16 + 0 * 64, /* %ymm16 through... */
1664 + 16 + 1 * 64,
1664 + 16 + 2 * 64,
1664 + 16 + 3 * 64,
1664 + 16 + 4 * 64,
1664 + 16 + 5 * 64,
1664 + 16 + 6 * 64,
1664 + 16 + 7 * 64,
1664 + 16 + 8 * 64,
1664 + 16 + 9 * 64,
1664 + 16 + 10 * 64,
1664 + 16 + 11 * 64,
1664 + 16 + 12 * 64,
1664 + 16 + 13 * 64,
1664 + 16 + 14 * 64,
1664 + 16 + 15 * 64 /* ... %ymm31 (128 bits each). */
};
#define XSAVE_YMM_AVX512_ADDR(tdep, xsave, regnum) \
(xsave + xsave_ymm_avx512_offset[regnum - I387_YMM16H_REGNUM (tdep)])
static int xsave_xmm_avx512_offset[] =
{
1664 + 0 * 64, /* %ymm16 through... */
1664 + 1 * 64,
1664 + 2 * 64,
1664 + 3 * 64,
1664 + 4 * 64,
1664 + 5 * 64,
1664 + 6 * 64,
1664 + 7 * 64,
1664 + 8 * 64,
1664 + 9 * 64,
1664 + 10 * 64,
1664 + 11 * 64,
1664 + 12 * 64,
1664 + 13 * 64,
1664 + 14 * 64,
1664 + 15 * 64 /* ... %ymm31 (128 bits each). */
};
#define XSAVE_XMM_AVX512_ADDR(tdep, xsave, regnum) \
(xsave + xsave_xmm_avx512_offset[regnum - I387_XMM16_REGNUM (tdep)])
static int xsave_mpx_offset[] = {
960 + 0 * 16, /* bnd0r...bnd3r registers. */
960 + 1 * 16,
960 + 2 * 16,
960 + 3 * 16,
1024 + 0 * 8, /* bndcfg ... bndstatus. */
1024 + 1 * 8,
};
#define XSAVE_MPX_ADDR(tdep, xsave, regnum) \
(xsave + xsave_mpx_offset[regnum - I387_BND0R_REGNUM (tdep)])
/* At xsave_avx512__h_offset[REGNUM] you find the offset to the location
of the AVX512 opmask register data structure used by the "xsave"
instruction where GDB register REGNUM is stored. */
static int xsave_avx512_k_offset[] =
{
1088 + 0 * 8, /* %k0 through... */
1088 + 1 * 8,
1088 + 2 * 8,
1088 + 3 * 8,
1088 + 4 * 8,
1088 + 5 * 8,
1088 + 6 * 8,
1088 + 7 * 8 /* %k7 (64 bits each). */
};
#define XSAVE_AVX512_K_ADDR(tdep, xsave, regnum) \
(xsave + xsave_avx512_k_offset[regnum - I387_K0_REGNUM (tdep)])
/* At xsave_avx512_zmm_h_offset[REGNUM] you find the offset to the location in
the upper 256bit of AVX512 ZMMH register data structure used by the "xsave"
instruction where GDB register REGNUM is stored. */
static int xsave_avx512_zmm_h_offset[] =
{
1152 + 0 * 32,
1152 + 1 * 32, /* Upper 256bit of %zmmh0 through... */
1152 + 2 * 32,
1152 + 3 * 32,
1152 + 4 * 32,
1152 + 5 * 32,
1152 + 6 * 32,
1152 + 7 * 32,
1152 + 8 * 32,
1152 + 9 * 32,
1152 + 10 * 32,
1152 + 11 * 32,
1152 + 12 * 32,
1152 + 13 * 32,
1152 + 14 * 32,
1152 + 15 * 32, /* Upper 256bit of... %zmmh15 (256 bits each). */
1664 + 32 + 0 * 64, /* Upper 256bit of... %zmmh16 (256 bits each). */
1664 + 32 + 1 * 64,
1664 + 32 + 2 * 64,
1664 + 32 + 3 * 64,
1664 + 32 + 4 * 64,
1664 + 32 + 5 * 64,
1664 + 32 + 6 * 64,
1664 + 32 + 7 * 64,
1664 + 32 + 8 * 64,
1664 + 32 + 9 * 64,
1664 + 32 + 10 * 64,
1664 + 32 + 11 * 64,
1664 + 32 + 12 * 64,
1664 + 32 + 13 * 64,
1664 + 32 + 14 * 64,
1664 + 32 + 15 * 64 /* Upper 256bit of... %zmmh31 (256 bits each). */
};
#define XSAVE_AVX512_ZMM_H_ADDR(tdep, xsave, regnum) \
(xsave + xsave_avx512_zmm_h_offset[regnum - I387_ZMM0H_REGNUM (tdep)])
/* Similar to i387_supply_fxsave, but use XSAVE extended state. */
void
i387_supply_xsave (struct regcache *regcache, int regnum,
const void *xsave)
{
struct gdbarch *gdbarch = get_regcache_arch (regcache);
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
const gdb_byte *regs = xsave;
int i;
unsigned int clear_bv;
static const gdb_byte zero[MAX_REGISTER_SIZE] = { 0 };
enum
{
none = 0x0,
x87 = 0x1,
sse = 0x2,
avxh = 0x4,
mpx = 0x8,
avx512_k = 0x10,
avx512_zmm_h = 0x20,
avx512_ymmh_avx512 = 0x40,
avx512_xmm_avx512 = 0x80,
all = x87 | sse | avxh | mpx | avx512_k | avx512_zmm_h
| avx512_ymmh_avx512 | avx512_xmm_avx512
} regclass;
gdb_assert (regs != NULL);
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
gdb_assert (tdep->num_xmm_regs > 0);
if (regnum == -1)
regclass = all;
else if (regnum >= I387_ZMM0H_REGNUM (tdep)
&& regnum < I387_ZMMENDH_REGNUM (tdep))
regclass = avx512_zmm_h;
else if (regnum >= I387_K0_REGNUM (tdep)
&& regnum < I387_KEND_REGNUM (tdep))
regclass = avx512_k;
else if (regnum >= I387_YMM16H_REGNUM (tdep)
&& regnum < I387_YMMH_AVX512_END_REGNUM (tdep))
regclass = avx512_ymmh_avx512;
else if (regnum >= I387_XMM16_REGNUM (tdep)
&& regnum < I387_XMM_AVX512_END_REGNUM (tdep))
regclass = avx512_xmm_avx512;
else if (regnum >= I387_YMM0H_REGNUM (tdep)
&& regnum < I387_YMMENDH_REGNUM (tdep))
regclass = avxh;
else if (regnum >= I387_BND0R_REGNUM (tdep)
&& regnum < I387_MPXEND_REGNUM (tdep))
regclass = mpx;
else if (regnum >= I387_XMM0_REGNUM (tdep)
&& regnum < I387_MXCSR_REGNUM (tdep))
regclass = sse;
else if (regnum >= I387_ST0_REGNUM (tdep)
&& regnum < I387_FCTRL_REGNUM (tdep))
regclass = x87;
else
regclass = none;
if (regclass != none)
{
/* Get `xstat_bv'. */
const gdb_byte *xstate_bv_p = XSAVE_XSTATE_BV_ADDR (regs);
/* The supported bits in `xstat_bv' are 1 byte. Clear part in
vector registers if its bit in xstat_bv is zero. */
clear_bv = (~(*xstate_bv_p)) & tdep->xcr0;
}
else
clear_bv = I386_XSTATE_ALL_MASK;
/* With the delayed xsave mechanism, in between the program
starting, and the program accessing the vector registers for the
first time, the register's values are invalid. The kernel
initializes register states to zero when they are set the first
time in a program. This means that from the user-space programs'
perspective, it's the same as if the registers have always been
zero from the start of the program. Therefore, the debugger
should provide the same illusion to the user. */
switch (regclass)
{
case none:
break;
case avx512_zmm_h:
if ((clear_bv & (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM)))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_AVX512_ZMM_H_ADDR (tdep, regs, regnum));
return;
case avx512_k:
if ((clear_bv & I386_XSTATE_K))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_AVX512_K_ADDR (tdep, regs, regnum));
return;
case avx512_ymmh_avx512:
if ((clear_bv & I386_XSTATE_ZMM))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_YMM_AVX512_ADDR (tdep, regs, regnum));
return;
case avx512_xmm_avx512:
if ((clear_bv & I386_XSTATE_ZMM))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_XMM_AVX512_ADDR (tdep, regs, regnum));
return;
case avxh:
if ((clear_bv & I386_XSTATE_AVX))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_AVXH_ADDR (tdep, regs, regnum));
return;
case mpx:
if ((clear_bv & I386_XSTATE_BNDREGS))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
XSAVE_MPX_ADDR (tdep, regs, regnum));
return;
case sse:
if ((clear_bv & I386_XSTATE_SSE))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
FXSAVE_ADDR (tdep, regs, regnum));
return;
case x87:
if ((clear_bv & I386_XSTATE_X87))
regcache_raw_supply (regcache, regnum, zero);
else
regcache_raw_supply (regcache, regnum,
FXSAVE_ADDR (tdep, regs, regnum));
return;
case all:
/* Handle the upper ZMM registers. */
if ((tdep->xcr0 & (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM)))
{
if ((clear_bv & (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM)))
{
for (i = I387_ZMM0H_REGNUM (tdep);
i < I387_ZMMENDH_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_ZMM0H_REGNUM (tdep);
i < I387_ZMMENDH_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i,
XSAVE_AVX512_ZMM_H_ADDR (tdep, regs, i));
}
}
/* Handle AVX512 OpMask registers. */
if ((tdep->xcr0 & I386_XSTATE_K))
{
if ((clear_bv & I386_XSTATE_K))
{
for (i = I387_K0_REGNUM (tdep);
i < I387_KEND_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_K0_REGNUM (tdep);
i < I387_KEND_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i,
XSAVE_AVX512_K_ADDR (tdep, regs, i));
}
}
/* Handle the YMM_AVX512 registers. */
if ((tdep->xcr0 & I386_XSTATE_ZMM))
{
if ((clear_bv & I386_XSTATE_ZMM))
{
for (i = I387_YMM16H_REGNUM (tdep);
i < I387_YMMH_AVX512_END_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
for (i = I387_XMM16_REGNUM (tdep);
i < I387_XMM_AVX512_END_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_YMM16H_REGNUM (tdep);
i < I387_YMMH_AVX512_END_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i,
XSAVE_YMM_AVX512_ADDR (tdep, regs, i));
for (i = I387_XMM16_REGNUM (tdep);
i < I387_XMM_AVX512_END_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i,
XSAVE_XMM_AVX512_ADDR (tdep, regs, i));
}
}
/* Handle the upper YMM registers. */
if ((tdep->xcr0 & I386_XSTATE_AVX))
{
if ((clear_bv & I386_XSTATE_AVX))
{
for (i = I387_YMM0H_REGNUM (tdep);
i < I387_YMMENDH_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_YMM0H_REGNUM (tdep);
i < I387_YMMENDH_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i,
XSAVE_AVXH_ADDR (tdep, regs, i));
}
}
/* Handle the MPX registers. */
if ((tdep->xcr0 & I386_XSTATE_BNDREGS))
{
if (clear_bv & I386_XSTATE_BNDREGS)
{
for (i = I387_BND0R_REGNUM (tdep);
i < I387_BNDCFGU_REGNUM (tdep); i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_BND0R_REGNUM (tdep);
i < I387_BNDCFGU_REGNUM (tdep); i++)
regcache_raw_supply (regcache, i,
XSAVE_MPX_ADDR (tdep, regs, i));
}
}
/* Handle the MPX registers. */
if ((tdep->xcr0 & I386_XSTATE_BNDCFG))
{
if (clear_bv & I386_XSTATE_BNDCFG)
{
for (i = I387_BNDCFGU_REGNUM (tdep);
i < I387_MPXEND_REGNUM (tdep); i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_BNDCFGU_REGNUM (tdep);
i < I387_MPXEND_REGNUM (tdep); i++)
regcache_raw_supply (regcache, i,
XSAVE_MPX_ADDR (tdep, regs, i));
}
}
/* Handle the XMM registers. */
if ((tdep->xcr0 & I386_XSTATE_SSE))
{
if ((clear_bv & I386_XSTATE_SSE))
{
for (i = I387_XMM0_REGNUM (tdep);
i < I387_MXCSR_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_XMM0_REGNUM (tdep);
i < I387_MXCSR_REGNUM (tdep); i++)
regcache_raw_supply (regcache, i,
FXSAVE_ADDR (tdep, regs, i));
}
}
/* Handle the x87 registers. */
if ((tdep->xcr0 & I386_XSTATE_X87))
{
if ((clear_bv & I386_XSTATE_X87))
{
for (i = I387_ST0_REGNUM (tdep);
i < I387_FCTRL_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, zero);
}
else
{
for (i = I387_ST0_REGNUM (tdep);
i < I387_FCTRL_REGNUM (tdep);
i++)
regcache_raw_supply (regcache, i, FXSAVE_ADDR (tdep, regs, i));
}
}
break;
}
/* Only handle x87 control registers. */
for (i = I387_FCTRL_REGNUM (tdep); i < I387_XMM0_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
/* Most of the FPU control registers occupy only 16 bits in
the xsave extended state. Give those a special treatment. */
if (i != I387_FIOFF_REGNUM (tdep)
&& i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte val[4];
memcpy (val, FXSAVE_ADDR (tdep, regs, i), 2);
val[2] = val[3] = 0;
if (i == I387_FOP_REGNUM (tdep))
val[1] &= ((1 << 3) - 1);
else if (i== I387_FTAG_REGNUM (tdep))
{
/* The fxsave area contains a simplified version of
the tag word. We have to look at the actual 80-bit
FP data to recreate the traditional i387 tag word. */
unsigned long ftag = 0;
int fpreg;
int top;
top = ((FXSAVE_ADDR (tdep, regs,
I387_FSTAT_REGNUM (tdep)))[1] >> 3);
top &= 0x7;
for (fpreg = 7; fpreg >= 0; fpreg--)
{
int tag;
if (val[0] & (1 << fpreg))
{
int thisreg = (fpreg + 8 - top) % 8
+ I387_ST0_REGNUM (tdep);
tag = i387_tag (FXSAVE_ADDR (tdep, regs, thisreg));
}
else
tag = 3; /* Empty */
ftag |= tag << (2 * fpreg);
}
val[0] = ftag & 0xff;
val[1] = (ftag >> 8) & 0xff;
}
regcache_raw_supply (regcache, i, val);
}
else
regcache_raw_supply (regcache, i, FXSAVE_ADDR (tdep, regs, i));
}
if (regnum == I387_MXCSR_REGNUM (tdep) || regnum == -1)
regcache_raw_supply (regcache, I387_MXCSR_REGNUM (tdep),
FXSAVE_MXCSR_ADDR (regs));
}
/* Similar to i387_collect_fxsave, but use XSAVE extended state. */
void
i387_collect_xsave (const struct regcache *regcache, int regnum,
void *xsave, int gcore)
{
struct gdbarch *gdbarch = get_regcache_arch (regcache);
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
gdb_byte *regs = xsave;
int i;
enum
{
none = 0x0,
check = 0x1,
x87 = 0x2 | check,
sse = 0x4 | check,
avxh = 0x8 | check,
mpx = 0x10 | check,
avx512_k = 0x20 | check,
avx512_zmm_h = 0x40 | check,
avx512_ymmh_avx512 = 0x80 | check,
avx512_xmm_avx512 = 0x100 | check,
all = x87 | sse | avxh | mpx | avx512_k | avx512_zmm_h
| avx512_ymmh_avx512 | avx512_xmm_avx512
} regclass;
gdb_assert (tdep->st0_regnum >= I386_ST0_REGNUM);
gdb_assert (tdep->num_xmm_regs > 0);
if (regnum == -1)
regclass = all;
else if (regnum >= I387_ZMM0H_REGNUM (tdep)
&& regnum < I387_ZMMENDH_REGNUM (tdep))
regclass = avx512_zmm_h;
else if (regnum >= I387_K0_REGNUM (tdep)
&& regnum < I387_KEND_REGNUM (tdep))
regclass = avx512_k;
else if (regnum >= I387_YMM16H_REGNUM (tdep)
&& regnum < I387_YMMH_AVX512_END_REGNUM (tdep))
regclass = avx512_ymmh_avx512;
else if (regnum >= I387_XMM16_REGNUM (tdep)
&& regnum < I387_XMM_AVX512_END_REGNUM (tdep))
regclass = avx512_xmm_avx512;
else if (regnum >= I387_YMM0H_REGNUM (tdep)
&& regnum < I387_YMMENDH_REGNUM (tdep))
regclass = avxh;
else if (regnum >= I387_BND0R_REGNUM (tdep)
&& regnum < I387_MPXEND_REGNUM (tdep))
regclass = mpx;
else if (regnum >= I387_XMM0_REGNUM (tdep)
&& regnum < I387_MXCSR_REGNUM (tdep))
regclass = sse;
else if (regnum >= I387_ST0_REGNUM (tdep)
&& regnum < I387_FCTRL_REGNUM (tdep))
regclass = x87;
else
regclass = none;
if (gcore)
{
/* Clear XSAVE extended state. */
memset (regs, 0, I386_XSTATE_SIZE (tdep->xcr0));
/* Update XCR0 and `xstate_bv' with XCR0 for gcore. */
if (tdep->xsave_xcr0_offset != -1)
memcpy (regs + tdep->xsave_xcr0_offset, &tdep->xcr0, 8);
memcpy (XSAVE_XSTATE_BV_ADDR (regs), &tdep->xcr0, 8);
}
if ((regclass & check))
{
gdb_byte raw[I386_MAX_REGISTER_SIZE];
gdb_byte *xstate_bv_p = XSAVE_XSTATE_BV_ADDR (regs);
unsigned int xstate_bv = 0;
/* The supported bits in `xstat_bv' are 1 byte. */
unsigned int clear_bv = (~(*xstate_bv_p)) & tdep->xcr0;
gdb_byte *p;
/* Clear register set if its bit in xstat_bv is zero. */
if (clear_bv)
{
if ((clear_bv & I386_XSTATE_BNDREGS))
for (i = I387_BND0R_REGNUM (tdep);
i < I387_BNDCFGU_REGNUM (tdep); i++)
memset (XSAVE_MPX_ADDR (tdep, regs, i), 0, 16);
if ((clear_bv & I386_XSTATE_BNDCFG))
for (i = I387_BNDCFGU_REGNUM (tdep);
i < I387_MPXEND_REGNUM (tdep); i++)
memset (XSAVE_MPX_ADDR (tdep, regs, i), 0, 8);
if ((clear_bv & (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM)))
for (i = I387_ZMM0H_REGNUM (tdep);
i < I387_ZMMENDH_REGNUM (tdep); i++)
memset (XSAVE_AVX512_ZMM_H_ADDR (tdep, regs, i), 0, 32);
if ((clear_bv & I386_XSTATE_K))
for (i = I387_K0_REGNUM (tdep);
i < I387_KEND_REGNUM (tdep); i++)
memset (XSAVE_AVX512_K_ADDR (tdep, regs, i), 0, 8);
if ((clear_bv & I386_XSTATE_ZMM))
{
for (i = I387_YMM16H_REGNUM (tdep);
i < I387_YMMH_AVX512_END_REGNUM (tdep); i++)
memset (XSAVE_YMM_AVX512_ADDR (tdep, regs, i), 0, 16);
for (i = I387_XMM16_REGNUM (tdep);
i < I387_XMM_AVX512_END_REGNUM (tdep); i++)
memset (XSAVE_XMM_AVX512_ADDR (tdep, regs, i), 0, 16);
}
if ((clear_bv & I386_XSTATE_AVX))
for (i = I387_YMM0H_REGNUM (tdep);
i < I387_YMMENDH_REGNUM (tdep); i++)
memset (XSAVE_AVXH_ADDR (tdep, regs, i), 0, 16);
if ((clear_bv & I386_XSTATE_SSE))
for (i = I387_XMM0_REGNUM (tdep);
i < I387_MXCSR_REGNUM (tdep); i++)
memset (FXSAVE_ADDR (tdep, regs, i), 0, 16);
if ((clear_bv & I386_XSTATE_X87))
for (i = I387_ST0_REGNUM (tdep);
i < I387_FCTRL_REGNUM (tdep); i++)
memset (FXSAVE_ADDR (tdep, regs, i), 0, 10);
}
if (regclass == all)
{
/* Check if any ZMMH registers are changed. */
if ((tdep->xcr0 & (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM)))
for (i = I387_ZMM0H_REGNUM (tdep);
i < I387_ZMMENDH_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_AVX512_ZMM_H_ADDR (tdep, regs, i);
if (memcmp (raw, p, 32) != 0)
{
xstate_bv |= (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM);
memcpy (p, raw, 32);
}
}
/* Check if any K registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_K))
for (i = I387_K0_REGNUM (tdep);
i < I387_KEND_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_AVX512_K_ADDR (tdep, regs, i);
if (memcmp (raw, p, 8) != 0)
{
xstate_bv |= I386_XSTATE_K;
memcpy (p, raw, 8);
}
}
/* Check if any XMM or upper YMM registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_ZMM))
{
for (i = I387_YMM16H_REGNUM (tdep);
i < I387_YMMH_AVX512_END_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_YMM_AVX512_ADDR (tdep, regs, i);
if (memcmp (raw, p, 16) != 0)
{
xstate_bv |= I386_XSTATE_ZMM;
memcpy (p, raw, 16);
}
}
for (i = I387_XMM16_REGNUM (tdep);
i < I387_XMM_AVX512_END_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_XMM_AVX512_ADDR (tdep, regs, i);
if (memcmp (raw, p, 16) != 0)
{
xstate_bv |= I386_XSTATE_ZMM;
memcpy (p, raw, 16);
}
}
}
/* Check if any upper YMM registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_AVX))
for (i = I387_YMM0H_REGNUM (tdep);
i < I387_YMMENDH_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_AVXH_ADDR (tdep, regs, i);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_AVX;
memcpy (p, raw, 16);
}
}
/* Check if any upper MPX registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_BNDREGS))
for (i = I387_BND0R_REGNUM (tdep);
i < I387_BNDCFGU_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_MPX_ADDR (tdep, regs, i);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_BNDREGS;
memcpy (p, raw, 16);
}
}
/* Check if any upper MPX registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_BNDCFG))
for (i = I387_BNDCFGU_REGNUM (tdep);
i < I387_MPXEND_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = XSAVE_MPX_ADDR (tdep, regs, i);
if (memcmp (raw, p, 8))
{
xstate_bv |= I386_XSTATE_BNDCFG;
memcpy (p, raw, 8);
}
}
/* Check if any SSE registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_SSE))
for (i = I387_XMM0_REGNUM (tdep);
i < I387_MXCSR_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = FXSAVE_ADDR (tdep, regs, i);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_SSE;
memcpy (p, raw, 16);
}
}
/* Check if any X87 registers are changed. */
if ((tdep->xcr0 & I386_XSTATE_X87))
for (i = I387_ST0_REGNUM (tdep);
i < I387_FCTRL_REGNUM (tdep); i++)
{
regcache_raw_collect (regcache, i, raw);
p = FXSAVE_ADDR (tdep, regs, i);
if (memcmp (raw, p, 10))
{
xstate_bv |= I386_XSTATE_X87;
memcpy (p, raw, 10);
}
}
}
else
{
/* Check if REGNUM is changed. */
regcache_raw_collect (regcache, regnum, raw);
switch (regclass)
{
default:
internal_error (__FILE__, __LINE__,
_("invalid i387 regclass"));
case avx512_zmm_h:
/* This is a ZMM register. */
p = XSAVE_AVX512_ZMM_H_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 32) != 0)
{
xstate_bv |= (I386_XSTATE_ZMM_H | I386_XSTATE_ZMM);
memcpy (p, raw, 32);
}
break;
case avx512_k:
/* This is a AVX512 mask register. */
p = XSAVE_AVX512_K_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 8) != 0)
{
xstate_bv |= I386_XSTATE_K;
memcpy (p, raw, 8);
}
break;
case avx512_ymmh_avx512:
/* This is an upper YMM16-31 register. */
p = XSAVE_YMM_AVX512_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 16) != 0)
{
xstate_bv |= I386_XSTATE_ZMM;
memcpy (p, raw, 16);
}
break;
case avx512_xmm_avx512:
/* This is an upper XMM16-31 register. */
p = XSAVE_XMM_AVX512_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 16) != 0)
{
xstate_bv |= I386_XSTATE_ZMM;
memcpy (p, raw, 16);
}
break;
case avxh:
/* This is an upper YMM register. */
p = XSAVE_AVXH_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_AVX;
memcpy (p, raw, 16);
}
break;
case mpx:
if (regnum < I387_BNDCFGU_REGNUM (tdep))
{
regcache_raw_collect (regcache, regnum, raw);
p = XSAVE_MPX_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_BNDREGS;
memcpy (p, raw, 16);
}
}
else
{
p = XSAVE_MPX_ADDR (tdep, regs, regnum);
xstate_bv |= I386_XSTATE_BNDCFG;
memcpy (p, raw, 8);
}
break;
case sse:
/* This is an SSE register. */
p = FXSAVE_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 16))
{
xstate_bv |= I386_XSTATE_SSE;
memcpy (p, raw, 16);
}
break;
case x87:
/* This is an x87 register. */
p = FXSAVE_ADDR (tdep, regs, regnum);
if (memcmp (raw, p, 10))
{
xstate_bv |= I386_XSTATE_X87;
memcpy (p, raw, 10);
}
break;
}
}
/* Update the corresponding bits in `xstate_bv' if any SSE/AVX
registers are changed. */
if (xstate_bv)
{
/* The supported bits in `xstat_bv' are 1 byte. */
*xstate_bv_p |= (gdb_byte) xstate_bv;
switch (regclass)
{
default:
internal_error (__FILE__, __LINE__,
_("invalid i387 regclass"));
case all:
break;
case x87:
case sse:
case avxh:
case mpx:
case avx512_k:
case avx512_zmm_h:
case avx512_ymmh_avx512:
case avx512_xmm_avx512:
/* Register REGNUM has been updated. Return. */
return;
}
}
else
{
/* Return if REGNUM isn't changed. */
if (regclass != all)
return;
}
}
/* Only handle x87 control registers. */
for (i = I387_FCTRL_REGNUM (tdep); i < I387_XMM0_REGNUM (tdep); i++)
if (regnum == -1 || regnum == i)
{
/* Most of the FPU control registers occupy only 16 bits in
the xsave extended state. Give those a special treatment. */
if (i != I387_FIOFF_REGNUM (tdep)
&& i != I387_FOOFF_REGNUM (tdep))
{
gdb_byte buf[4];
regcache_raw_collect (regcache, i, buf);
if (i == I387_FOP_REGNUM (tdep))
{
/* The opcode occupies only 11 bits. Make sure we
don't touch the other bits. */
buf[1] &= ((1 << 3) - 1);
buf[1] |= ((FXSAVE_ADDR (tdep, regs, i))[1] & ~((1 << 3) - 1));
}
else if (i == I387_FTAG_REGNUM (tdep))
{
/* Converting back is much easier. */
unsigned short ftag;
int fpreg;
ftag = (buf[1] << 8) | buf[0];
buf[0] = 0;
buf[1] = 0;
for (fpreg = 7; fpreg >= 0; fpreg--)
{
int tag = (ftag >> (fpreg * 2)) & 3;
if (tag != 3)
buf[0] |= (1 << fpreg);
}
}
memcpy (FXSAVE_ADDR (tdep, regs, i), buf, 2);
}
else
regcache_raw_collect (regcache, i, FXSAVE_ADDR (tdep, regs, i));
}
if (regnum == I387_MXCSR_REGNUM (tdep) || regnum == -1)
regcache_raw_collect (regcache, I387_MXCSR_REGNUM (tdep),
FXSAVE_MXCSR_ADDR (regs));
}
/* Recreate the FTW (tag word) valid bits from the 80-bit FP data in
*RAW. */
static int
i387_tag (const gdb_byte *raw)
{
int integer;
unsigned int exponent;
unsigned long fraction[2];
integer = raw[7] & 0x80;
exponent = (((raw[9] & 0x7f) << 8) | raw[8]);
fraction[0] = ((raw[3] << 24) | (raw[2] << 16) | (raw[1] << 8) | raw[0]);
fraction[1] = (((raw[7] & 0x7f) << 24) | (raw[6] << 16)
| (raw[5] << 8) | raw[4]);
if (exponent == 0x7fff)
{
/* Special. */
return (2);
}
else if (exponent == 0x0000)
{
if (fraction[0] == 0x0000 && fraction[1] == 0x0000 && !integer)
{
/* Zero. */
return (1);
}
else
{
/* Special. */
return (2);
}
}
else
{
if (integer)
{
/* Valid. */
return (0);
}
else
{
/* Special. */
return (2);
}
}
}
/* Prepare the FPU stack in REGCACHE for a function return. */
void
i387_return_value (struct gdbarch *gdbarch, struct regcache *regcache)
{
struct gdbarch_tdep *tdep = gdbarch_tdep (gdbarch);
ULONGEST fstat;
/* Set the top of the floating-point register stack to 7. The
actual value doesn't really matter, but 7 is what a normal
function return would end up with if the program started out with
a freshly initialized FPU. */
regcache_raw_read_unsigned (regcache, I387_FSTAT_REGNUM (tdep), &fstat);
fstat |= (7 << 11);
regcache_raw_write_unsigned (regcache, I387_FSTAT_REGNUM (tdep), fstat);
/* Mark %st(1) through %st(7) as empty. Since we set the top of the
floating-point register stack to 7, the appropriate value for the
tag word is 0x3fff. */
regcache_raw_write_unsigned (regcache, I387_FTAG_REGNUM (tdep), 0x3fff);
}